SYLLABI - tsipil.ugm.ac.idtsipil.ugm.ac.id/wp-content/uploads/2019/04/Tsipil-UGM-Syllabi.pdf · Bibliography : 1) Ditjen Dikti Depdiknas, 2001, Kapita Selekta Pendidikan Pancasila

UNIVERSITAS GADJAH MADACIVIL AND ENVIRONMENTAL ENGINEERING DEPARTMENT

SYLLABICivil and Environmental Engineering

UNIVERSITAS GADJAH MADAPhone & Fax : +62-274-545676

Email: [email protected]://tsipil.ugm.ac.id

UNDER GRADUATE IN CIVIL ENGINEERINGSYLLABI

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Table of Contents

1. Course name : Pancasila ................................................................................................ 1

2. Course name : Civic ...................................................................................................... 1

3. Course name : Basic Physics ......................................................................................... 2

4. Course name : Chemistry for Civil Engineering ........................................................... 3

5. Course name : Calculus I ............................................................................................... 3

6. Course name : Algorythm and Programming ................................................................ 4

7. Course name : Engineering Drawing............................................................................. 4

8. Course name : Statistic and Probability ......................................................................... 5

9. Course name : Religion ................................................................................................. 6

10. Course name : Calculus II ............................................................................................. 7

11. Course name : Engineering Concept for Civilization .................................................... 7

12. Course name : Building Structure ................................................................................. 8

13. Course name : Physics for Civil Engineering ................................................................ 9

14. Course name : Fluid Mechanics .................................................................................. 10

15. Course name : Introduction to Environmental Engineering ........................................ 10

16. Course name : Introduction to Transportation Engineering ........................................ 11

17. Course name : Introduction to Geology ...................................................................... 12

18. Course name : Differential Equation ........................................................................... 13

19. Course name : Traffic Engineering ............................................................................. 13

20. Course name : Hydrology ............................................................................................ 14

21. Course name : Geomatics and SIG .............................................................................. 15

22. Course name : Statics I ................................................................................................ 16

23. Course name : Introduction to Transportation Planning ............................................ 16

24. Course name : Entrepreneurship and Life Skill........................................................... 17

25. Course name : Building Materials and Fundamentals of Concrete Engineering ........ 18

26. Course name : Soil Mechanicis I ................................................................................. 19

27. Course name : Shallow Foundation Engineering ........................................................ 20

28. Course name : Material Mechanics ............................................................................. 20

29. Course name : Earth Moving ....................................................................................... 21

30. Course name : Open Channel Hydraulics.................................................................... 22

31. Course name : Geometric Design of Roads................................................................. 23

32. Course name : Water Resources Management ............................................................ 24

33. Course name : Numerical Method I ............................................................................ 25

34. Course name : Soil Mechanics II ................................................................................. 25

35. Course name : Drainage and Sanitation ...................................................................... 26

36. Course name : Railway Engineering ........................................................................... 27

37. Course name : Pavement Design ................................................................................. 28

38. Course name : Statics II ............................................................................................... 29

39. Course name : Civil Engineering Softwares I (Hydraulic, Environmental,

Transportation) .................................................................................. 30

40. Course name : Water and Waste Water Management Engineering ............................ 31

41. Course name : Irrigation Engineering ......................................................................... 32

42. Course name : Reinforced Concrete Structure I .......................................................... 32

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43. Course name : Steel Structure I ................................................................................... 34

44. Course name : Deep Foundation Engineering ............................................................. 35

45. Course name : Timber and Bamboo Structure ............................................................ 35

46. Course name : Numerical Method II ........................................................................... 36

47. Course name : Dynamic Structural Analysis and Earthquake Engineering ................ 37

48. Course name : Introduction to Construction Management .......................................... 38

49. Course name : Port Engineering .................................................................................. 38

50. Course name : Research Method, Academic Writing, and Presentation ..................... 39

51. Course name : Software in Civil Engineering II (Building Structure and Material,

Geotechnics and Construction Management) .................................... 40

52. Course name : Engineering Economics ....................................................................... 40

53. Course name : Reinforced Concrete Structure II......................................................... 41

54. Course name : Steel Structure II .................................................................................. 42

55. Course name : Drinking Water Supply Engineering ................................................... 43

56. Course name : Traffic Management ............................................................................ 43

57. Course name : Site Investigation ................................................................................. 44

58. Course name : River Engineering ................................................................................ 45

59. Course name : Ground Water Flow ............................................................................. 46

60. Course name : Construction Health and Safety ........................................................... 47

61. Course name : Community Development (KKN) ....................................................... 47

62. Course name : Practice Work ...................................................................................... 48

63. Course name : Final Assignment ................................................................................. 48

64. Course name : Building Bridge Structure Design ....................................................... 49

65. Course name : Project Planning and Scheduling ......................................................... 50

66. Course name : Water/Waste Water Treatment Installation Design ............................. 51

67. Course name : Transportation Infrastructure Design .................................................. 52

68. Course name : Geotechnics for Civil Engineering Structure Design .......................... 52

69. Course name : Hydraulic Structure Design ................................................................. 53

70. Course name : Concrete Technology .......................................................................... 54

71. Course name : Prestressed and Precast Concrete Structure ......................................... 55

72. Course name : Bridge Structure .................................................................................. 56

73. Course name : Monitoring and Control of Water Pollution ........................................ 56

74. Course name : Pavement Construction ........................................................................ 57

75. Course name : Rock Mechanics .................................................................................. 58

76. Course name : Water Power Structure ........................................................................ 59

77. Course name : Fundamentals of Coastal Engineering ................................................. 60

78. Course name : Natural Disaster Mitigation ................................................................. 60

79. Course name : Foreign Language (English) ................................................................ 61

80. Course name : Foreign Language (Japan) ................................................................... 61

81. Course name : Infrastructure Maintenance and Repair ............................................... 62

82. Course name : Offshore Structure ............................................................................... 62

83. Course name : Finite Element Method ........................................................................ 63

84. Course name : Waste Water Management and Treatment .......................................... 64

85. Course name : Airport Engineering ............................................................................. 65

86. Course name : Soil Improvement ................................................................................ 65

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87. Course name : Sediment Transport ............................................................................. 66

88. Course name : Hydrology and Applied Hydraulics..................................................... 67

89. Course name : Construction Method ........................................................................... 68

90. Course name : Courses Outside Department ............................................................... 69

1

1. Course name : Pancasila

Course code/UCU : UN1101/2.0

Semester : I

Prerequisite Courses : None

Objectives : Students will be able to comprehend the fundamentals and aims of

course in Pancasila, and to expand the insight on the values of

Pancasila.

Learning outcomes : a) Coordination capability in multidisciplinary team

b) Comprehension in leadership, responsibility and professional

ethics in Civil Engineering

c) Good communication skill

Syllabus : Fundamentals and purposes of Pancasila education, history of

Indonesian struggle (growth of Indonesian national ideology), 1945

Constitution (basic definition, 1945 Constitution preambule,

government system, state institution, state-citizens relationship,

1945 Constitution dynamics); Pancasila as philosophy system, ethic,

ideology, paradigm of society, nation and state life; actualization of

Pancasila in campus life.

Studio practice : N/A

Practice : N/A

Bibliography : 1) Ditjen Dikti Depdiknas, 2001, Kapita Selekta Pendidikan

Pancasila Bagian II, Dirjen Dikti Depdiknas, Jakarta

2) Sinar Grafika, 2002, UUD 1945 Hasil Amandemen Agustus

2002, Jakarta

3) Ditjen Dikti Depdiknas, 2001, Kapita Selekta Pendidikan

Pancasila Bag.II, Diten Dikti Depdiknas, Jakarta

4) Ditjen Dikti Depdiknas, 2002, Materi Ajar Pendidikan

Pancasila, Diten Dikti Depdiknas, Jakarta

2. Course name : Civic


Semester : I


Objectives : Students will be able to become knowledgeable human being and

perceptive to the issues encountered particularly in Indonesia and

world wide. Students will possess the personality characterized by

the spirit of sacrifice for others and territorial integrity of the

Republic of Indonesia. Students will also acquire visionary

personality, Memiliki kepribadian yang visioner, prepared for hard

work, discipline, and productive.

Learning outcomes a) Coordination capability in multidisciplinary team




Syllabus : Discussion in the definition of rights and obligations of the citizens,

knowledge in Indonesian archipelagi as Indonesian living space

(Indonesian geopolitics) and Indonesian geostrategy in the form of

national defense and the implementation of national policy in the

form of national politics and strategy.

2

Knowledge of Indonesia: geographical position and natural

resources potentials. Economic, political, legal, social, and

educational condition in Indonesia. Knowing Indonesian geopolitics

in relation to the global condition. Knowing the concept of

HANKAMRATA system. The obligation of citizens in defending

the Republic of Indonesia from disintegration by domestic and

foreign threats. Becoming visionary, hard working, discipline, and

productive citizens and concern with the issues within the society

and Indonesia. Vision of a better future for Indonesia.


Practice : N/A

Bibliography : 1) Wahyu Widodo, Budi Anwari, Maryanto, 2015, Pendidikan

Kewarganegaraan, CV ANDI OFFSET, Yogyakarta

2) A.Ubaidillah, Abdul Rozak, 2005, Demokrasi Hak Azasi

Manusia dan Masyarakat Madani, Kencana Perdana Media

Grup, Jakarta

3) Mardiasmo, 2004, Otonomi dan Manajemen Keuangan Daerah,

CV ANDI OFFSET, Yogyakarta

3. Course name : Basic Physics

Course code/UCU : TKS1103/3.0

Semester : I


Objectives : Understanding natural phenomena (mechanics) and electrical

(statics and dynamics) and electromagnet.

Learning Outcomes : To be able to apply mathematics, science, and technology in Civil

Engineering

Syllabus : Kinematics: vector, force and displacement, energy and enthalpy,

potential energy, the law of energy conservation, equilibrium;

dynamics (momentum, Newton law I, II, III, force, conservative

force, power); rigid body mechanics (center of mass, moment of

inertia); static electricity (electric field strength and potential,

capacitor); dynamic electricity (resistance, Ohm law, unidirectional

electricity, magnetism, and alternating current).

Vibration: introduction in Fourier series and transformation,

introduction in white noise, introduction in periodic and non-

periodic signal.

Fluids


Practice : N/A

Bibliography : 1) David Halliday, Robert Resnick, Jearl Walker, 2014, Principle

of Physics, 10th Edition, Wiley, International Student Version

2) Miller, F.J.R., 1999, College Physics, 5th edition, Uniersity of

Arkansas

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4. Course name : Chemistry for Civil Engineering

Course code/UCU : TKS1104/2.5 + 0.5 (Practice)

Semester : I


Objectives : To understand the basic general concept of chemistry especially

with relevance to Civil Engineering

Learning Outcomes : a) Able to apply mathematics, science, and technology in Civil

Engineering

b) Knowledge in the development of current issues in Civil

Engineering

Syllabus : Chemistry science, the basic theory of atom, chemical reaction and

calculation and molecule concept (electron configuration in the

properties of element), electron structure from atom, periodic table

and element properties, chemical bonds, energy, energy conversion

and thermochemistry, liquid solution and acid reaction, chemical

kinetics, chemical reaction in solution and acid-base reaction,

calculation of solution concentration, pH value in acid-base

solution, chemical balance, buffer solution and hydrolysis,

electrochemistry.

Chemical aspect in building materials and pollution: atom bond,

chrystal, chemical reaction of Portland cement and adhesive

substance and additive, chemical process of corrosion in metal/steel

and concrete, protection of metal/steel and concrete materials.

Chemical aspect in Environmental Engineering: corrosion in metal,

application of chemistry in water treatment and waste water

treatment also environmental pollution control (water and air).


Practice : Practice in building material analysis and water quality

Bibliography : 1) Ames F. Brady, 1990, General Chemistry, Principles and

Structures, John Wiley & Sons, New York

2) The Fu Yen, 2007, Chemical Processes for Environmental

Engineering, Imperial College Press, London

3) Hyman D. Gesser, 2002, Applied Chemistry, A Textbook for

Engineering and Technologies, Kluwer Academic/Plenum

Publisher

5. Course name : Calculus I

Course code/UCU : TKS1105/3.0+1.0 (Studio practice)

Semester : I


Objectives : To understand the definition, types, and properties of single

variable function, to master derivation technique and integral

function, also the application in Civil Engineering.

Learning Outcomes : Able to apply mathematics, science, and technology in Civil

Engineering.

Syllabus : Real number system, number value, mean, absolute value,

coordinat system, single variable function, function graph,

function limit, function continuity, derivative fuction, extreme

value, integral, definite integral, indefinite integral; area, volume,

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momen inertia, and center of gravity of geometry, vector and

tensor.

Studio practice : Derivation and application example of simple equations for

calculation in structural, hydraulic, geotechnical, transportation,

and environmental engineering.

Practice : N/A

Bibliography : 1) Ayres, J.R.F., 1964, Theory and Problems of Calculus,

McGraw Hill International

2) E. Purcell, 1984, Kalkulus dan Geometri Analitik, Edisi ke 3

6. Course name : Algorythm and Programming

Course code/UCU : TKS1106/1.5+0.5 Studio practice)

Semester : I

Prerequisite Courses : Tidak ada

Objectives : To obtain comprehension and apply hardware and software also the

creation of simple software in Civil Engineering and supporting

science.

Learning Outcomes a) Able to apply mathematics, science, and technology in Civil

Engineering.

b) Able to apply the latest technology and software in Civil

Engineering.

Syllabus : Introduction to main hardware of a computer, introduction to OS;

definition of OS and the way of work, iteration process of software

creation: problems, algorythm, coding, compiling, running;

debugging, the application of FORTRAN/VISUAL BASIC: general

rules, input-output, matrix strcuture, completion of differential

equation; programming with spresdsheet and its application in Civil

Engineering, introduction to OOP, programming with VISUAL

BASIC, GUI, Graphical programming, creation of simple software.

Studio practice : Creation of simple program with FORTRAN or VISUAL BASIC

and Spreadsheet

Practice : N/A

Bibliography : 1) Larry Nyhoff, Sanford Leestm, 1995, FORTRAN 77 and

Numerical Methods for Engineers and Scientists, Prentice Hall

2) Richard H. McCuen, 1975, FORTRAN Programming for Civil

Engineers

3) Radianta Triatmadja, 2010, Bahasa Pemrograman

Menggunakan Visual Basic, Untuk Bidang Sains dan

Teknologi, Draft Buku Ajar

4) Jubilee Enterprise, 2015, VBA Macro MS Excel Manual Book,

PT Elex Media Computindo, Jakarta

7. Course name : Engineering Drawing

Course code/UCU : TKS1107/1.5 + 0.5 (Studio practice)

Semester : I


Tujuan : Students will be able to interpret and create drawings (manually),

also to master the drafting technique using drafting application

program (AutoCAD).

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Engineering.

b) Able to apply the latest technology and software in Civil

Engineering.

Syllabus : Drawing function, drawing component, drawing scale, types of

drawing, drawing tools (for manual drafting and drafting with

drafting application program), drawing standard; projection

drawing(orthogonal, isometry, dimetry, trimetry), view drawings,

cross section drawings, introduction to drafting application program

AutoCAD; drafting technique with AutoCAD; drawing scale

setting, drawings layout, drawing title; printing/plotting techniques.

Creating drawings manually and using drafting application program

AutoCAD.

Studio practice : Drawing civil engineering building components and its accessories

using AutoCAD.

Practice : N/A

Bibliography : 1) Gurcharan, S., Chander, S., 1979, Civil Engineering Drawing,

New Chand Jain, Nai Sarak, Delhi

2) Mott, L.C., 1979, Engineering Drawing and Construction,

Oxford University Press, Oxford

3) AutoDesk, 2015: AutoCAD Version 2015

8. Course name : Statistic and Probability


Semester : I


Objectives : To understand the application of statistics in engineering, especially

descriprive and inference statistics.


Engineering.

b) Able to conduct design and research, also analyzing and

interpreting data.

k) Able to apply the latest technology and software in Civil

Engineering.

Syllabus : Statistic scale (central tendency, variability, measure of individual

in a population); data, sample, population; data presentation in table

or chart; basic concept of probability (opportunity), probability

interpretation, return period; conditional probability, total

probability, Bayes theorem; random variable, pdf, cdf; probability

distribution; discrete distribution (binomial, Poisson, geometric,

multinomial, and hypergeometric distribution); continuous

distribution (uniform, exponential, gamma, beta, Weibull, normal,

and lognormal distribution); estimation and testing; estimation of

confidence intervals; hypothesis test; regression; frequency analysis

of extreme events.


Practice : N/A

Bibliography : 1) Kottegoda, N.T., Rosso, R., 1998, Statistics, Probability, and

Reliability for Civil and Environmental Engineers, McGraw-

Hill Co., Inc., New York

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2) Kottegoda, Nathabandu T., Rosso, Renzo, 2008, Applied

Statistics for Civil and Environmental Engineers, 2nd Edition,

Blackwell Publishing Ltd., United Kingdom

9. Course name : Religion


Semester : II


Objective : To strengthen the students’ faith and piety to the Almighty God

according to their beliefs, noble character, rational and dynamic

attitude, open minded, able to cooperate among other religion

believers in the development and utilization of science, technology,

and art for the benefit of mankind and nation.

Learning Outcomes : a) Coordination capability in multidisciplinary team




d) Willingness and ability for self development and continuous

learning

Syllabus : ISLAM: human and religion, Islam, the origin of Islam, the

fundamentals of Islam, aqidah, syari’ah, worship and mu’amalah,

akhlaq, piety, science in Islam, knowledge discipline in Islam.

CATHOLIC: Catholic graduate aspired by the society and church,

religion study method in public universities, basic relationship of

human (philosophical description), thoughts in seeking for truth,

faithful human who will follow Jesus and believe in Him, the nature

of Jesus Christ and His role in the life of faith, church as a

community of the faithful, fundamentals and measures in the

consideration of good and bad decision making, motivation,

Catholic family, Catholic religion acknowledges the autonomy of

science including its methodology, responsibility of the Catholics in

world development, apostolate of the laity as the duty of the faithful

among the world.

CHRISTIAN: human, Christian, church, Christian Faith Science and

Technology (Faith, Compassion and Hope), human and

development, problems in ethics in social life, Capita Selecta (Capita

Selecta Themes).

HINDU: philosophy of science and religion, the history of Hindu,

universe, weda as scripture and source of law in Hindu pricipals of

Srada in Hindu, Catur Purusartha and Catur Asrama, Catur Harga

Yoga, Hindu sociology, Sad Darsana, percepts and ethics of Hindu,

Adnya, Pandita and Pinandita, sanctuary, sacred days of Hindu.

BUDHA: human and religion, Budha, the origin of Budha, the

fundamentals of Budha, Dharma, percepts, meditations, Buddhist

and Science.

KHONGHUCU: Essence and values of Khonghucu for the mankind,

values of Khonghucu history, religion and virtue, foundations of

Konghucu, commandment of Khonghucu, the principal faith (Chen

Xin Zhi Zhi)

Studio Studio practice : N/A

7

Practice : N/A

Bibliography : Following university

10. Course name : Calculus II

Course code/UCU : TKS1202/3.0+1.0 (Studio practice)

Semester : II

Prerequisite Courses : Calculus I (Semester I)

Objectives : Students will be able to comprehend the definition of function o

of several variables, derivative, double integral and its application,

elementer differential equation

Learning Outcomes : Able to apply mathematics, science, and technology in Civil

Engineering.

Syllabus : Function of several variables, function derivative limit of several

variables, derivative application to define extreme value of 2

variables, double integral and its application in several geometry,

elementer differential equation and its completion techniques,

Laplace transformation and the definition of elementer differential

equation completion with initial condition, several special

functions (Unique Function) and its properties, Fourier series.

Studio practice : Derivative and the application example of several formulas for

analysis and calculation of design value in structural, hydraulic,

geotechnical, transportation, and environmental engineering.

Practice : N/A

Bibliography : 1) Bacon, H.M., 1955, Differential and Integral Calculus,

McGraw Hill

2) Murray Spiegel, 2008, Schaum's Outlines: Kalkulus Lanjut

(Edisi 2), Erlangga

3) Sever Engel Popescu, 2013, Differential Calculus for

Engineers and Begining Mathematicians, LAMBERT

Academic Publishing

11. Course name : Engineering Concept for Civilization

Course code/UCU : TK1203/2.0

Semester : II


Objectives : To establish the comprehension in the rules of engineering

principles and its application in improving the quality of human life

with comprehensive insights.

Learning Outcomes : a) Comprehension in leadership, responsibility and professional

ethics in Engineering

b) Willingness and ability for self development and continuous

learning

Syllabus : Following the syllabus from UGM Engineering Faculty:

Contribution and importance of engineering science, attitude of an

engineer, professional ethics of an engineer, introduction in system

thinking, socio-cultural insight in engineering, political and

economic insights in engineering, environmental insight in

engineering, design principles, industrial technology cases,

geological technology cases, civil and planning technology cases,

8

energy technology cases, vision and mission of engineering

graduates as civilized human being.


Practice : N/A

Bibliography : Following UGM Engineering Faculty

12. Course name : Building Structure


Semester : II

Prerequisite Courses : Engineering Drawing (Semester I)

Objectives : Students will be able to comprehend the definition of civil

engineering structures, including water structures, transportation

structures, building and bridge structures, and able to conduct

simple design of civil engineering aspect in residential area.

Learning Outcomes : a) Able to design system and infrastructure in civil engineering as

part of requirements taking into account several obstacles such

as economic, environmental, health and security obstacles.

b) Able to identify, formulate, and solve the problems in civil

engineering by considering the potential use of local resources.

c) Possess comprehensive knowledge in the impact of

infrastructure development implementation to social, economic,

and environmental aspects.

d) Able to apply the latest technology and software in civil

engineering.

Syllabus : Transportation: Introduction in main structure and supporting

facilities of transportation activities and the role and function in:

road and terminal infrastructure; port and harbor infrastructure;

airport and terminal infrastructure; railway and station

infrastructure; intermodal/multimodal transportation control

structure; and several transportation structure animation.

Building and Bridge: regulation and standard of buildings; types

of buildings and bridges; introduction in building structure elements

(foundation, building frame, floor, roof, stair, wall, door andn

window; and bridge structure (superstructure and substructure);

introduction of loads in buildings and bridges; earthquake resistant

buildings and residentials; sanitation and drainage in buildings.

Hydraulic: river structure, hydraulic loads, general characteristics

of rain, rain intensity, dewatering problem in construction, river

flow (open channel flow: rectangular, trapezoidal, and circular

channel section), simple design of flow load, simple design of

channel section dimension in communal drainage utility,

environmental aspects in Building Structure.

Studio practice : Providing the students with design skill for residential area

(house/building design, residential area road network, and

communal drainage utility) both in simple design

analysis/calculation and its interpretation into engineering drawings

(plan and detail).

Practice : N/A

Bibliography : 1) Freick, H., 1980, Ilmu Konstruksi Bangunan, Kanisius,

Yogyakarta

9

2) Hutington, et.al., 1987, Building Construction, John Wiley,

New York

3) Subarkah, I, 1980, Konstruksi Bangunan Gedung, Idea Darma,

Bandung

4) Djojowirono, S., 1988, Konstruksi Bangunan Gedung, Biro

Penerbit KMTS FT UGM, Yogyakarta

5) NAASRA, 1979, Interim Guide for the Design of Intersection at

Grade

6) Road and Transportation Association of Canada, 1976,

Geometric Design Standards for Canadian Roads on Streets

13. Course name : Physics for Civil Engineering

Course code/UCU : TKS1205/2.5+0.5 (Practice)

Semester : II

Prerequisite Courses : Basic Physics (Semester I)

Objectives : To be able to apply science and technology, and physics in civil

engineering.

Learning Outcomes : a) Able to apply mathematics, science, and technology in civil

engineering.

b) Able to apply the latest technology and software in civil

engineering.

Syllabus : Fundamentals of Statics I:

Definition of force and moment; parallelogram, paralelogram/ force

disintegration, concurrent and non-concurrent forces resultant;

definition of moment from a force, couple moment and torsional

moment; parallel forces resultant, forces equilibrium; principle of

force equilibrium; Newton Law I and III; Definition of intenal

forces due to loading: normal force, shear force, bending and

torsional moment; definition and types of loads/external force and

load combinations, and load and structure idealization in the field;

definition, types, and characteristics of supports, calculation of

support reaction.

Fundamentals of Stress, Strain, and Deformation Analysis:

Rigid body stability, definition of stress and strain, stress-strain

relationship, E-G- relationship, section properties: area, center of

gravity, moment of inertia, axis transformation (axis displacement

and rotation). Introduction of single and multiple degree system,

resonance, and damping.

Fundamentals of Fluid Mechanics:

Hydrostatic pressure, Bernouli law, balance principle and force

momentum also the fundamentals of liquid flow through pipe, shear

stress, velocity distribution in vertical section, energy loss in fluid

flow, specific energy, specific force, hydraulic jump.

Fundamentals of Transportation Engineering:

Fundamentals of dynamics mechanics, single vehicle movement,

single vehicle movement statistics (velocity, acceleration), multiple

vehicle movement (following theory).


Practice : Practice of building structure (tensile force, compression force,

moment, shear force)

Bibliography : 1) Megson, 2014, Structural and Stress Analysis

10

2) N.B. Weber, 1971, Fluid Mechanics for Civil Engineers,

Chapman & Hall

3) Albert T. Fromhold Jr., 2011, Quantum Mechanics for Applied

Physics and Engineering, Dover Books on Physics

14. Course name : Fluid Mechanics


Semester : II

Prerequisite Courses : 1) Calculus I (Semester I)

2) Basic Physics (Semester I)

Objectives : Students will be able to understand (i) fluid properties and

hydrostatics, (ii) principle of stability of floating bodies and relative

movement, also (iii) momentum and basic flow of fluid through

pipe


engineering.

b) Able to conduct design and research, and to analyze and

interpret data.

Syllabus : Definition and properties of fluids, hydrostatics, stability of floating

bodies, relative stability, fluid kinematics, momentum equation,

fluid flow through pipe and steady though piping system


Practice : Bourdon manometer, hydrostatic pressure, Reynolds aparatus,

venturimeter, energy loss of flow in pipe, momentum

Bibliography : 1) Bambang Triatmodjo, Hidraulika I dan II, Beta Offset,

Yogyakarta

2) Evett, Jacd B, Cheng Liu, 1987, Fundamental of Fluid

Mechanics, Mc. Graw Hill International Edition, Civil

Engineering Series

3) Dougherty, Robert L., Joseph B. Franzini, 1977, Fluid

Mechanics with Engineering applications, Mc. Graw Hill

International Book Company, International Student Edition

4) White, Frank M., 1986, Fluid Mechanics, Mc. Graw Hill

International Book Company, Second Edition

5) Munson, B. R., Young, D.F., Okiishi, T. H., 2002,

Fundamentals of Fluid Mechanics, 4th. Ed., John Wiley &

Sons, Inc. New York

15. Course name : Introduction to Environmental Engineering


Semester : II

Prerequisite Courses : Chemistry for Civil Engineering (Semester I)

Objectives : Students will acquire environmental awareness (able to develop

perceptive attitude and awareness towards the environment, and

understand the benchmark of environmental condition and the

importance of sustainable development) to ensure that the

development will not deviate far away from the environmental

moral ‘vitalism’, understand the fundamentals (identification,

prediction and impact evaluation) in the environmental impact

analysis to analyze the environmental impact from a civil

engineering activity, understand environmental audit and scientific

benchmark and the regulations for audit review.

11

Studio practice : Field assignment (conducting environmental audit of river in biotic

and abiotic aspects, review the problems against existing scientific

rule or regulation).

Learning Outcomes : a) Able to condcut design and research, and to analyze and

interpret data.

b) Able to identify, formulate, and solve problems in civil

engineering by taking into account the potential use of local

resources.


infrastructure development implementation to social,

economic, and environmental aspects.

Practice : N/A

Syllabus : Philosophy of environmental science in civil engineering activities;

Fundamentals of environmental science; Understanding

environmental issues world wide. Regulations and policies

regarding management of environment. Introduction in the term of

environmental review method. Several cases in the impact of civil

engineering structures to the environment; Introduction in the

analysis of environmental impact (AMDAL), RKL and RPL, UKL

and UPL in civil engineering construction; environmental audit;

introduction in means and technology in civil engineering structure

for conservation and management of environmental impact from

civil engineering activities or others, for example fishway,

infiltration well, garbage/liquid waste treatment building.

Bibliography : 1) Institution of Highway and Transportion, 1996, Road Transport,

the Environment and Sustainable Development, Institution of

Highway and Transportation

2) Davis, L.D. and Cornwell, D.A., 2008, Introduction to

Environmental Engineering, 5th edition, Mc.Graw-Hill, Inc.

3) Otto Soemarwoto, Analisis Mengenai Dampak Lingkungan,

1998, Penerbit: Gadjah Mada University Press

16. Course name : Introduction to Transportation Engineering


Semester : II


Objectives : Students will be able to understand the meaning of transportation

and acquire knowledge in transportation which is environmental

friendly, efficient, and sustainable.

Learning Outcomes : a) Able to design system and infrastructure in civil engineering

as required by taking into account several obstacles such as

economic, environmental, health, and security obstacles.

b) Able to identify, formulate, and solve the problems in civil


resources.

c) Possess comorehensive knowledge in the impact of

infrastructure development implementation to social,

economic, and environmental aspects.

Syllabus : Relationship between transportation and other disciplines;

Importance and definition of transportation system, transportation

network, transportation facilities and infrastructures (land, river,

crossing, sea, and air); Relationship between transportation and

environment; Relationship between transportation and

12

technology; Comprehension in public transportation;

Comprehension in freight transportation; Example of the

implementation of urban transportation; Comprehension in

multimodal transportation; Comprehension in sustainable

transportation.


Practice : N/A

Bibliography : 1) Vuchic, V.R., 1999, Transportation for Livable Cities, Center

for Urban Policy Research

2) Hamberger (Editor), 1982, Transportation and Traffic

Engineering Handbook, Institute of Transportation

Engineering

3) Paquatte, et al., 1982, Transportation Engineering Planning

and Design, John Wiley and Sons

4) Munawar, A., 2004, Dasar-Dasar Teknik Transportasi, Beta

Offset, Yogyakarta

17. Course name : Introduction to Geology


Semester : II


Objectives : To understand soil, rock as construction materials in civil

engineering, geological structure of soil, fault, joint and origin of

soil and rock.

Learning Outcomes : Able to apply mathematics, science, and technology in civil

engineering.

Syllabus : Geology for Civil Engineering, geological cycle, igneous rock,

surface process, sediment rock, metamorph rock; geological

structure, geological map and section, interpretation of geological

map, tectonic plate, disaster (earthquake, volcano), rock in

Indonesia, weathering and soil, flood plain and alluvium, glacial

deposit, regional climate and local geological characteristics,

coastal process, ground water, rock strength and rock mass, land

land subsidence (soil, limestone, mining area), rock excavation,

tunnel in rocks, stone and aggregate.


Practice : N/A

Bibliography : 1) Van Bemmelem, R.W. (1949), The Geology of Indonesia, Vol.

IA, General Geology of Indonesia and Adjacent Archipelagoes,

Government Printing Office, The Hague

2) Waltham, A.C. (1994), Foundations of Engineering Geology,

Blackie Academic & Professional

3) Das, B.M. (2002), Principle of Geotechnical Engineering, 5th

edition, Brooks/Cole, Thomson learning

4) Craig R.F. (1992), Soil Mechanics, 5th Edition, Chapman &

Hall

5) Hardiyatmo, H.C. (2004), Mekanika Tanah I, UGM Press,

Yogyakarta

13

18. Course name : Differential Equation


Semester : III

Prerequisite Courses : 1) Calculus I (Semester I)

2) Calculus II (Semester II)

Objectives : To understand and able to apply differential equation theory in civil

engineering analysis


engineering.

Syllabus : Ordinary differential equation order 1, ordinary differential equation

order 2, numerical solution of ordinary differential equation,

ordinary differential equation system, partial differential equation,

ordinary differential equation solution (Euler, Heun, Runge-Kutta),

partial differential equation (finite differential, explicit, implicit, and

Crank-Nicholson schemes).


Practice : N/A

Bibliography : 1) Bronson, R., Costa G., 2008, Schaum’s Outline: Persamaan

Diferensial, Edisi 3, Erlangga

2) Djoko Luknanto, 2003, Model Matematik, Jurusan Teknik Sipil

FT UGM

3) Nakamura, Soichiro, 1977, Computational Methods in

Engineering and Science, John Wiley & Sons

4) Robert, Charles E., 1979, Ordinary Differential Equations,

Prentice-Hall

19. Course name : Traffic Engineering


Semester : III


Objectives : Students will be able to understand the characteristics of traffic and

road user, vehicle; relationship between volume, velocity and

density; to understand road hierarchy; to analyze road capacity and

level of service; to understand the method of traffic data collection,

able to analyze and calculate cycle time, lots time and green time of

signal-controlled intersection; able to analyze and calculate the

capacity of uncontrolled intersection and knowing the role of traffic

engineering in the environmental management.


engineering.


interpret data.

c) Able to design system and infrastructure in civil engineering as

required by taking into account several obstacles such as

economic, environmental, health and security obstacles.

j) Possess knowledge in the development of latest issues in civil

engineering.

k) Able to apply the latest technology and software in civil

engineering.

Syllabus : Characteristics of road user and traffic; Characteristics of vehicles

and traffic; Characteristics pf traffic velocity; Relationship between

14

volume, velocity and density (fundamental diagram); Macroscopic

and microscopic theory; Calculation of capacity and velocity

according to Manual Kapasitas Jalan Indonesia (MKJI). Road

division based on status and function; Road capacity and level of

service; Method of traffic data collection: volume, headway,

velocity, density; Choosing types of intersection. The application of

MKJI for intersection analysis. Introduction to signal-controlled

intersection; Calculation method of green time, lost time and cycle

time in signal; Phase and stage setting diagram in signal-controlled

intersection; Saturation flow and capacity of signal-controlled

intersection; Introduction to uncontrolled intersection; Gap, lag and

capacity of uncontrolled intersection; The role of traffic engineering

in the environmental management (air quality, noise and vibration).

Introduction to computer programs for traffic analysis.


Practice : N/A

Bibliography : 1) Curin, T. R., 2001, Introduction to Traffic Engineering: A

Manual for Data Collection and Analysis. Brooks/Cole

2) Direktorat Jenderal Bina Marga, 1997, Manual Kapasitas Jalan

Indonesia, Departemen Jenderal Bina Marga.

3) Munawar, A., 2004, Program Komputer untuk Analisis Lalu

Lintas, Beta Offset, Yogyakarta

4) O’Flaherty, C.A. (ed)., 1997, Transport Planning and Traffic

Engineering. Arnold.

5) Salter, R.J. and Hounsell, N. B., 1996. Highway Traffic

Analysis and Design (3rd ed.), Macmillan.

6) Salter, R.J., 1989, Traffic Engineering Worked Examples

(2nd.ed). Macmillan.

7) Slinn, M., et al., 1998, Traffic Engineering Design: Principles

and Studio practice. Arnold.

20. Course name : Hydrology


Semester : III


Objectives : To understand the role of hydrology, process, and measurement of

hydrological elements in design and planning of water resources.


engineering.


interpret data.

c) Able tp design system and infrastructure in civil engineering as



e) Able to identify, formulate and solve the problems in civil


resources.

Syllabus : Definition and history of hydrology, the role of hydrology in water

resources design, comprehension in the process, measurement, and

analysis of all hydrological elements, scale of hydrological design,

unit hydrpgraph, frequency analysis, design flood, environmental

aspect in hydrology.

15


Practice : N/A

Bibliography : 1) Bras, R.L., 1990, Hydrology: An Introduction to Hydrology

Science, Adison-Wesley Publishing Co., Canada

2) Chow, V.T., Maidment, D.R. and Mays, L.W., 1988, Applied

Hydrology, MC-Graw-Hill Book Company, New York

3) Sri Harto Br., 2000, Hidrologi Teori-Masalah Penyelesaian,

Nafiri, Yogyakarta

4) Saeid Eslamean, 2014, Handbook of Engineering Hydrology,

CRC Press, Taylor and Francis Group

21. Course name : Geomatics and SIG


Semester : III


Objectives : To be able to understand surveying and the use of map including

reading, analysis and interpretation for planning and civil

engineering work. Students will be able to understand the

Geographical Information System (GIS) and its application in civil

engineering.


engineering.

k) Able to apply the latest technology and software in civil

engineering.

Syllabus : - Definition for geodetical basics in mapping and its application in

civil engineering, basic and method of surveying: distance

measurement, altitude and angle, 3D coordinate system, Global

Positioning System (GPS), topography in civil engineering, map

reading: calculation of area, distance, volume, and profile

(longitudinal and cross sections), map interpretation.

- Definition of Geographical Information System, spatial concept,

information system concept, spatial information system, data

input (analog to digital), storing, process and manipulation

(graphic dan atribute). Output data in graphic form, table and the

combination of both. Remote sensing data integration to

geographical information system. Application of geographical

information system for mapping, monitoring, and modeling

(evaluation, prediction).


Practice : N/A

Bibliography : 1) Davis, R., 1990, Surveying: Theory and Studio practice, 6th

edition, Mc Graw Hill, USA

2) Kisam, P., 1981, Surveying for Civil Engineering, Mc Graw Hill

3) Indarto, Arif Faisol, 2013, Konsep Dasar Analisis Spasial,

Galerigis

4) Projo Danoedoro, 2012, Pengantar Penginderaan Jauh Digital,

Andi Offset

5) Michael Kennedy, 2013, Introducing Geographic Information

Systems with ArcGIS, Third Edition, Wiley

16

22. Course name : Statics I


Semester : III

Prerequisite Courses : Physics for Civil Engineering (Semester II)

Objectives : To be able to understand the basic concept of the role of

determinate static structural analysis in design of civil engineering

structure, idealization of actual structure and load into

mathematical model, to understand the stability concept to

calculate support reactions and internal forces in a determinate

static structure (beam and truss structure).


engineering.

Syllabus : - Internal forces in determinate static beam structure and drawing

of SFD, NFD, BMD, and TMD diagrams; due to various

types/shapes of load (including indirect loads).

- Determinate static truss structure: definition, assumption,

structural analysis with method: Joint, graphic/Cremona,

Section, deformation analysis with graphical and analytical

methods.

- Analysis and drawing of influence line for determinate static

structure (beam, frame and truss), including indirect loads.

- Scope of indeterminate static structure including: hinge-roller

beam (simple beam), cantilever beam, cantilever beam in 3D

space, simple beam with cantilever, Gerber bema (compound

beam), simple frame/arch (hinge-roller support), truss structure;

3-hinged frame and arch; simple cable structure.


Practice : Students to conduct test and demo of determinate static structure

model based on stability concept (simple beam, cantilever, gerber,

including influence line).

Strudents to create truss analysis and maximum forces occur using

influence line.

Bibliography : 1) Megson, T.H.G., 2014, Structural and Stress Analysis Third

Edition, Butterwort & Heinemann

2) Hibbeler, R.C., 2012, Structural Analysis 8thEdition., Prentice

Hall Int., Inc.

23. Course name : Introduction to Transportation Planning


Semester : III


Objectives : Students will be able to comprehend the transportation planning

process through a modeling stage, especially for highway

transportation.

Learning Outcomes : a) Able to design system and infrastructure in civil engineering

as required by taking into account several obstacles such as


b) Able to identify, formulate and solve problems in civil


resources.

c) Possess knowledge in the development of the latest issues in

civil engineering

17


engineering.

Syllabus : Basic definition and introduction to transportation planning (why

transportation planning shall be understood, the role of

transportation, transportation development, movement and

transportation, land usage cycle and transportation, introduction in

urban transportation planning, rasional approach in transportation

planning, concept of transportation planning). Planning process and

decision making in transportation planning; transportation zoning

analysis, data collection and survey planning; Introduction to four

step model: trip generation, trip distribution, modal split, trip

assignment. Definition of trip generation and influence factor of trip

generation; Definition of trip distribution, origin-destination matrix

and trip distribution analysis method (growth factor method,

synthetic method) Definition and determining factor of trip mode

choosing; Definition and determining factor of traffic loading,

traffic loading analysis method; Planning principles and service

quality of public transportation; Route planning; Planning of

armada capacity and number; Evaluation to public transportation;

Policy aspet in public transportation and road network planning;

Case demo of network planning and or public transportation.


Practice : N/A

Bibliography : 1) Blunden, W.R. dan Black, J.A., 1971, The Land Use Transport

System, 2nd Edition, Pergamon Press, Sydney, Australia

2) Salter, R. J. and Hounsell, N.B, 1996, Highway Traffic Analysis

and Design, Palgrave Macmillan

3) Ortuzar, J.D. and Wilumsen, L.G., 1994, Modelling Transport

2nd Edition, Wiley, England

4) Banister, D., 1995, Transport and Urban Development, Spon,

London

5) Pushkarev, B.S. and Jeffrey M.Z., 1977, Public Transportation

and Land Use Policy, Indiana University Press, Bloomington

24. Course name : Entrepreneurship and Life Skill


Semester : III


Objectives : To develop understanding and awareness in the spirit of

entrepreneurship, especially in relation to business opportunities in

construction sector, in order for the students to be able to develop

talent and skills in entrepreneurship in construction sector.

Learning Outcomes : a) Comprehension in leadership, responsibility and professional

ethics in civil engineering

b) Good communication skill

c) Willingness and ability for self development and continuous

learning

Syllabus : Introduction to entrepreneurship and its urgency, characters of an

entrepreneur, motivation, team work, business opportunity in

construction (design consultant, supervising consultant,

18

construction management consultant, general contractor, specialist

contractor, construction industry, property), entrepreneurship risk,

business moral and ethics and social responsibility, personality

development, ability to convey ideas and academic inovation, time

management, quality control, communication and leadership, also

team building.


Practice : N/A

Bibliography : 1) Buchari Alma, 2006, Kewirausahaan. Edisi kesepuluh.

Bandung: Alfabeta

2) Geoffrey G. Meredith, Robert E. Nelson, Philip A. Neck, 1996,

Kewirausahaan, Teori dan Praktek. Edisi kelima. Jakarta: PT

Bibliography Binaman Pressindo

3) Justin G. Longenecker dkk., 2001, Kewirausahaan Manajemen

Usaha Kecil. Jakarta: PT. Salemba Emban Patria

4) Rusman Hakim,1998, Kiat Sukses Berwiraswasta.Edisi

Kedua.Jakarta: PT Elex Media Media Komputindo

5) David C. McClelland, 1961, The Achieving Society. New

York: D. Van Nostrand Company, Inc.

6) Abdullah Gymnastiar, 2006, Melipatgandakan Kekayaan

dengan Kecerdasan Spiritual. Bandung. Solusi Qalbu

7) Covey, S., 2008, The 8thHabit; Menggapai Keagungan, Jakarta:

PT. Gramedia Bibliography

8) Hisrich, R. D., Peters, M. P., & Shepherd, D. A., 2008,

Entrepreneurship, Singapore: McGraw-Hill International

25. Course name : Building Materials and Fundamentals of Concrete Engineering


Semester : III

Prerequisite Courses : Chemistry for Civil Engineering (Semester I)

Objectives : Students will be able to understand the physical, mechanical, and

chemical properties of materials used in civil engineering structures.

Students will be able to understand the creation of concrete.


engineering.

e) Able to identify, formulate, andn solve the problems in civil


resources.

h) Possess comprehensive knowledge in the impact of

infrastructure development implementation to social, economic


Syllabus : Physical, mechanical, and chemical properties of various materials

used in civil engineering originated from organic materials (wood),

non-organic materials (bitumen, polymer, glass, metal, ceramic,

limestone), and materials used for concrete creation (water, Portland

cement, sand, gravel, and additive).

Design and creation of mortar and normal concrete including

Perancangan serta pembuatan mortar dan beton normal yang

meliputi measurement, mixing, handling, casting, compacting, and

treatment of concrete. Evaluation of concrete quality in project

construction.

19

Studio practice : None

Practice : Students to conduct test of physical and mechanical properties of

building materials (wood, steel).

Students to be able to conduct test for sand and gravel, design of

concrete mix, concrete mixing, testing of fresh concrete and curred

concrete.

Bibliography : 1) Jackson, N., 1978,”Civil Engineering Materials”, The

Macmillan Press Ltd., London

2) Singh, G., 1979, ”Materials of Construction”, Standard Book

Service, Delhi

3) Somayaji, S., 1995, ”Civil Engineering Materials”, Prentice

Hall, New Jersey

4) Gambhir, M.L., 1986, Concrete Technology, Tata McGraw-Hill

Publishing Company Limited, New Delhi

5) Shetty, M.S., 1997, Concrete Technology, S.Chand & Company

Ltd., New Delhi

26. Course name : Soil Mechanicis I


Semester : II


Objectives : Students will be able to understand the soil index properties, soil

classifications, compacting classifications, effective stress, soil

permeability, and introduction to soil shear strength.


engineering.


interpret data.




Syllabus : General introduction (problems and application of soil mechanics),

soil and its formation process, index properties (water content,

specific gravity, unit weight, void ratio, degree of saturation, grain

size analysis, Atterberg’s limit) and classification (BS, ASTM,

AASHTO), compacting (laboratory & field, density control in the

field), soil stress, seepage (permeability, laboratory and field

permeability test; layered soil/ anisotropic, flownet, seepage

pressure, seepage at soil embankment, filter), introduction to soil

shear stress.


Practice : Students to conduct soil index properties test, soil compaction,

permeability.

Bibliography : 1) Das, B.M., 2002, Principle of Geotechnical Engineering, 5th

edition, Brooks/Cole, Thomson Learning

2) Craig R.F., 1992, Soil Mechanics, 5th Edition, Chapman & Hall

3) Hardiyatmo, H.C., 2004, Mekanika Tanah I, UGM Press,

Yogyakarta

4) Karl Terzaghi, 2016, Soil Mechanics in Engineering Studio

practice, Amazon Warehouse Deals

5) William Powrie, 2013, Soil Mechanics, Concepts and

Applications, CRC Press, Taylor and Francis Group

20

27. Course name : Shallow Foundation Engineering


Semester : IV

Prerequisite Courses : Soil Mechanics I (Semester III)

Objectives : Students will be able to design and plan shallow foundation and

retaining wall construction.


engineering.


interpret data.




Syllabus : Definition of shallow foundation, soil bearing capacity theory

(Terzaghi, Meyerhof, Vesic), foundation width effect and ground

water level position, individual footing foundation, combined

footing foundation, mat foundation. Retaining wall, lateral soil

pressure theory, drawing of active and passive soil pressure

diagram, drainage in retaining wall structure, retaining wall by

reinforced earth.


Practice : N/A

Bibliography : 1) Bowles, J.E., 1994, Foundation Analysis and Design, Mc.

Graw-Hill, Inc, New York

2) Coduto, D. P. 1994, Foundation Design: Principe and Studio

practices, Prentice Hall, Englewood Cliffs, New Jersey, USA

3) Hardiyatmo, H.C. 2010, Analisis dan Perancangan Fondasi I,

UGM Press, Yogyakarta

4) Suryolelono, K. B., 1993, Teknik Fondasi I, Nafiri, Jogjakarta

28. Course name : Material Mechanics


Semester : IV

Prerequisite Courses : 1) Differential Equation (Semester III)

2) Statics I (Semester III)

Objectives : To be able to analyze stress and strain due to internal and external

forces, also to design simple structures using concrete, steel, wood,

composite, and other materials.


engineering.

Syllabus : Axially loaded members, pure flexure, axial-flexure combination,

shear and torsion, deformation and displacement (beam deflection:

deflection curve differential equation, beam deflection analysis

using double integral method and moment area method), stability of

compression member, body stress strain analysis by analytic and

graphic method.


Practice : N/A

Bibliography : 1) Gere, J.M. and Timoshenko, S.P., 2004, Mechanics of

Materials, Sixth Edition, Wordsworth Inc.

21

2) Timothy A. Philpot, 2013, Mechanics of Materials, Wiley

3) Popov, P.E., 1978, Mechanics of Materials, Prentice Hall Inc.

4) Hiyndon Ohlsen, Mechanics of Materials, John Wiley and Sons

29. Course name : Earth Moving


Semester : IV


Tujuan : Students will be able yo understand the appropriate management

and choice of heavy equipment on site adjusted based on soil and

rock properties, environmental condition, and anticipation of

construction and civil engineering structure failure.


engineering.


required by taking into account the obstacles such as economic,

environmental, health, and security obstacles.

e) Able to identify, formulate, and solve civil engineering

problems by taking into account the potential use of local

resources.

Syllabus : - Main issues of heavy equipment on site from technical, economy,

social-cultural, health and safery, and environment.

- Definition and technical classification and fuction of heavy

equipments on site or field earth moving.

- Management and selection of heavy equipment on site.

- Technical factors affecting the performance of heavy equipment

on various soil characteristics.

- Technical analysis of heavy equipment productivity in

earthworks: land clearing (bulldozer, ripper, and scrapper);

material excavation and loading (excavator, power shovel,

backhoe, dragline, loader, clamshell); material mobilization

(dump truck); material laying (motor grader); initial compaction

of material backfilling (tandem roller and three wheel roller);

advanced backfilling compaction (sheep foot roller and

pneumatic tired roller); water spraying on material backfilling

layer (water tank).

- Quality control of earthworks using heavy equipment in land

clearing, material excavation and loading, material mobilization,

material laying, material backfilling compaction, and water

spraying on backfilling layer, also the anticipation of

construction failure and civil structure failure.

- Analysis of cost components for heavy equipment hire: fixed cost

and variable cost.

- Heavy equipment management in case study of embankment

work (material supply, material mobilization, material laying,

and material compaction), including: preparation and site

organization also method statement; selecting and calculating

heavy equipment quantity; calculation of heavy equipment

productivity; calculation of material and additional labor

requirement on site.

- Unit price analysis of earthworks (excavation on backfilling),

including: material direct cost analysis, equipment hire, and labor

cost; analysis of productivity and quantity of each heavy

22

equipment, analysis of material requirement, analysis of labor

requirement on site.

- Analysis of duration control of earthworks (excavation and

backfilling) observed from the use of heavy equipment type and

quantity, critical productivity of heavy equipment, and the

accuracy of heavy equipment mobilization on site.

- Comprehension in adaptation and mitigation of environmental

impact due to heavy equipment application and its solution in

earthworks (excavation and backfilling) in large scale.


Practice : N/A

Bibliography : 1) Sharma, S.C., 1999, Construction Equipment and Its

Management, 3rd Edision, Khanna Publisher, Delhi.

2) Rochmanhadi, 1985, Alat-alat Berat dan Penggunaannya, Badan

Penerbit Pekerjaan Umum, Jakarta

3) Soekoto, I., 1984, Mempersiapkan Latihan Dasar Konstruksi,

Vol. 1 dan 2, Badan Penerbit Pekerjaan Umum, Jakarta.

4) Peurifoy, R.L., Letbetter, W.B., and Schexnayder, C.J., 1996,

Construction Planning, Equipment, and Methods, 5th Edision,

McGraw-Hill Companies, Inc., New York, USA.

5) Peurifoy, R.L., Schexnagder, C.J., and Shapira, A., 2006,

Construction Planning, Equipment, and Methods, Mc.

GrawHill, New York, USA.

6) Haddock, K., 2011, Modern Earthmoving Machines,

Iconografix.

7) Kementerian Pekerjaan Umum, 2010, Spesifikasi Umum

Bidang Jalan dan Jembatan, Jakarta.

8) Peraturan Menteri Pekerjaan Umum Nomor 11/PRT/M/2013

tentang Pedoman Analisis Harga Satuan Pekerjaan Bidang

Pekerjaan Umum.

30. Course name : Open Channel Hydraulics


Semester : IV

Prerequisite Courses : Fluid Mechanics (Semester II)

Objectives : Students will be able to understand the characteristic of water flow

in open channel and to conduct analysis for the purpose of design

and operation of water structures.


engineering.

b) Able to design system and infrastructure in civil engineering as



c) Able to identify, formulate, and solve civil engineering


resources.

Syllabus : Basic principles of flow, flow classification, continuity equation,

energy equation, momentum equation, shear stress, velocity

distribution on vertical section, empirical velocity equation, specific

energy, uniform flow through open channels, specific energy,

specific force, non-uniform permanent flow, hydraulic jump,

dimension model and analysis, environmental aspects in open

channel hydraulics

23


Practice : N/A

Bibliography : 1) Bambang Triatmodjo, 2003, Hidraulika II, Beta Offset,

Yogyakarta

2) Ranga Raju, K.G., 1981, Flow Through Open Channels, Tata-

McGraw Hill Book Company

3) Hubert Chanson, 2004, The Hydraulics of Open Channel Flow;

An Introduction, Elsevier Ltd.

31. Course name : Geometric Design of Roads

Course code/UCU : TKS2205/2.0 + 1.0 (Studio Studio practice)

Semester : IV

Prerequisite Courses : Introduction to Transportation Engineering (Semester II)

Objectives : 1. Students will be able to comprehensively understand the

concept of road geometric design.

2. Students will be able to conduct road geometric design based

on the standard with the principle of traffic safety and

minimizing the environmental impact.

3. Students will be able to recognize the environmental impact due

to road construction and formulating the solution.

Learning Outcomes : a) Able to conduct design and research, and to analyze and

interpret data.




Syllabus : Definition, role, and important issues in road geometric design;

Definition and classification of road and design vehicles; Speed

characteristics; Space requirements of road components; Technical

requirements of roads and road technical planning criteria, stopping

sight distance and passing sight distance; Safe roadway design

concept (forgiving road, self explaining road, self regulating road);

Selection of best alignment using multi criteria method; horizontal

alignment in road geometric design (topographic map

interpretation, superelevation diagram, junction radius, types of

junction, transition curve, pavement widening at junction, safety

indicator on junction); Vertical alignment in road geometric design

(topographic map interpretation, critical ramp, concave and convex

vertical curves, safety indicator on environment); suitability of

horizontal and vertical alignment; Vehicle accident potential

triggered by deviation of road technical design on site (Road Safety

Inspection (RSI) & Road Safety Audit (RSA)); Introduction to

environmental impact due to road construction and its solution.

Studio practice : Data processing and road geometric design

Practice : N/A

Bibliography : 1) PeraturanPerundangantentangJalan yang berlaku

a. Undang-undang No. 38 Tahun 2004 tentangJalan

b. Undang-Undang No. 22 tahun 2009 tentang Lalu Lintas dan

Angkutan Jalan Raya

c. Peraturan Pemerintah No. 34 tahun 2006tentangJalan

d. Peraturan Menteri Pekerjaan Umum No. 14 Tahun 2010

tentang Standar Pelayanan Minimum Jalan

24

e. Peraturan Menteri Pekerjaan Umum No. 19 Tahun 2011

tentang Persyaratan Teknis Jalan dan Kriteria Perencanaan

Teknis Jalan

f. Standar Desain Nomor UM.01.11-Bt/35 Tahun 2015 tentang

Gambar Tipikal Penampang Jalan dan Bangunan Pelengkap

Jalan yang berwawasan Lingkungan, Berkeselamatan dan

Responsif Gender

2) Departemen Pekerjaan Umum, 1997, Tata Cara Perencanaan

Geometrik Jalan Antar Kota No. 038/TBM/1997

3) Departemen Pekerjaan Umum, 2004, Pedoman Perencanaan

Geometrik Jalan Perkotaan No. RSNI T-14-2004

4) Wright, P.H., 1996, Highway Engineering, John Wiley &

Sons, New York

5) AASHTO, 2004, A Policy on Geometric Design of Highways

and Streets

6) Kementerian Pekerjaan Umum, 2010, Jalan Berkeselamatan di

Indonesia, Kemitraan Australia-Indonesia dalam Rekayasa

Keselamatan Jalan

7) Banks, J. H., 2011, Introduction to Transportation

Engineering, McGrawHill, New York

32. Course name : Water Resources Management


Semester : IV

Prerequisite Courses : Hydrology (Semester III)

Objectives : Students will be able to understand the basic principles of the

development and management of water resources concerning the

hydrological, hydraulic, fulfillment patterns, relevant institution and

regulation aspects, also the formulation of development strategi of

the utilization of water resources.

Learning Outcomes : a) Able to apply mathematics, science and technology in civil

engineering.




c) Able to identify, formulate, and solve the civil engineering


resources.

Syllabus : Definition and scope of water resouces management; basic

principle, institution and introduction to the regulations in water

resources management, water supply system, types and methods of

water requirement prediction (irrigation and non-irrigation), data

requirements for water resources management, determination of

reservoir storage capacity, reservoir release configuration method,

water allocation optimization model, flood control in macro and

micro scale, environmental aspects in water resources management


Practice : N/A

Bibliography : 1. Mays, L.W., 1996, Water Resources Hand Book, Mc.GrawHill

2. Larry W. Mays & Yeou-Koung Tung, 1992, Hydrosystems

Engineering & Management, McGraw-Hill Series in Water

Resource and Environmental Engineering, Singapore

25

3. Louck, D.P., Stedinger, J.R., Haith, D.H., 1981, Water Resources

System Planning and Analysis, Princeton Hall Inc., Englewood

Cliffs, New Jersey, USA

4. Sudjarwadi, M. Pandu S., B. Anton S., Asriningtyas, 2008,

Pengembangan Pengembangan Sumberdaya Air, Biro Penerbit

JTSL FT UGM

33. Course name : Numerical Method I


Semester : IV

Prerequisite Courses : Differential Equation (Semester III)

Objectives : Students will be able to solve various types of mathematical

equiations using numerical method.

Learning Outcomes : Able to apply mathematics, science and technology in civil

engineering.

Syllabus : Introduction, error, absolute and relative error, root-finding

algorithm (bisection method, linear interpolation method, Newton-

Raphson method, secant method, itteration), taylor series, linear

equation system, regression, interpolation, numerical integration

(trapezoidal, Simpson, Gaussian quadrature), solution of ordinary

differential equation (Euler, Heun, Runge-Kutta), partial differential

equation (finite differential explicit and implicit scheme, Crank-

Nicholson).


Practice : N/A

Bibliography : 1. Bambang Triatmodjo, 1992, Metode Numerik, Beta Offset,

Yogyakarta.

2. Chapra, S.C., Canale, R.P., 1990, Numerical Methods for

Engineers, 2nd Ed., McGraw-Hill Book Co., New York.

34. Course name : Soil Mechanics II


Semester : IV

Prerequisite Courses : Soil Mechanics I (Semester III)

Objectives : Students will be able to calculate stress distribution in soil,

consolidation theory, settlement and safety factor of slope

stabilization.


engineering.

b) Memiliki kemampuan dalam merancang dan melakukan

penelitian, serta menganalisis dan menginterprestasi data.




Syllabus : Concept of soil shear strength and direct shear test, triaxial,

unconfines compression test, and vane shear test, stress distribution

(Boussinesq and Westergard theory), building settlement

(immediate, consolidation settelement, secondary), consolidation

settelement speed, effect of implementation time, consolidation

acceleration using vertical drain, slope stability (calculation of

26

safety factor for finite and infinite slope, safety factor calculation

using Taylor method for = 0 and ≠ 0, slope stabilization

calculation using Felenius method, modified Bishop method,

translation landslide).


Practice : Soil shear strength test (direct shear, unconfined compression,

triaxial), consolidation test.

Bibliography : 1) Craig R.F., 1992, Soil Mechanics, Fifth Edition, Chapman &

Hall

2) Das, B.M., 1990, Principle of Geotechnical Engineering, PWS-

KENT Publishing Company

3) Hardiyatmo, H.C., 2004, Mekanika Tanah II, UGM Press,

Yogyakarta

35. Course name : Drainage and Sanitation


Semester : IV

Prerequisite Courses : 1) Introduction to Environmental Engineering (Semester II)

2) Hydrology (Semester III)

Objectives : Students will be able to identify regional hydrogeography system

and understand the complete drainage and sanitation system through

functional design, planning, and construction design including

channel design such as geometry, material and dimension


engineering.






resources.

d) Possess comprehensive knowledge in the impact of



Syllabus : Drainage and sanitation problems (in relation to urbanization and

water balance); drainage and sanitation system paradigm and

function; Classification and fundamentals of sanitation system

definition; analysis of waster water discharge and sanitation

network layout; determination of sanitation system dimension and

construction; drainage system classification; drainage system

planning; rainwater runoff analysis; determination of drainage

network dimension and construction; special drainage system

(airport and sport stadium); drainage concept and pro-water

concept; Catchment system and system benefits; catchment

catchment dimension determination method (Sunjoto (1988), PU

(1990), ITB (1990), ARSIT (1988), MSMAM (Malaysia), Georgia).


Practice : N/A

Bibliography : 1) Castel D.A., McCunnall, J., Trung, I.M., 1984, Field Drainage

Principles and Studio practices, Batsford Academic and

Educational, London, England

27

2) Anonim, 1974, “Drainage Principles and Aplications”,

International Institute for Land Reclamation and Improvement,

Wageningen, The Netherland

3) Brown S.A., J.D. Schall J.D., Morris J.L., Doherty C.L. Stein

S.M., Warner J.C., 2013, Urban Drainage Design Manual

Hydraulic Engineering Circular 22, Third Edition, Federal

Highway Administration, Washington DC.

4) Metcalf and Eddy Inc, Tchobanoglous G., 1981, “Wastewater

Engineering: Collection and Pumping of Wastewater”, Mac

Graw Hill Inc., New York



36. Course name : Railway Engineering


Semester : IV


Objectives : Students will be able to understand the role of railway transportation

in national transportation system, development of railway

technology; able to plan and design railway, station, emplacement,

and railway transportation system.




b) Able to identify, formulate, and solve the civil engineering


resources.

c) Possess knowledge in the latest issues in civil engineering

Syllabus : Role and characteristics of railways; development of railway

infrastructure and facilities; types and functions of railway

components; railway track classification; technical requirements of

railway track; types, classification and activities in railway station,

force applied on track, ROW Plan, basic concept of railway track

planning and design; Railway track geometric design including:

horizontal and vertical alignment. Station and emplacement design

also switch-point and intersection with road. Analysis of train

traction, line capacity, telecommunication and signal system;

introduction to double vertex graph; Regulations and policies

relating to national railway development, railway operation system

and safety also the introduction to environmental impacts of railway

operation.


Practice : N/A

Bibliography : 1) Peraturan Perundangantentang Perkeretaapian yang berlaku

2) Bernhard, Lichtberger, 2005, Track Compendium, Eurailpress,

Tetzlaff, Hestra GmbH & Co. KG.

3) Hay, W.W., 1983, Railroad Engineering, 2nd Edision, John

Wiley & Sons, New York

4) Coenraad, Esveld, 2001, Modern Railway Track, TU Delft,

Netherlands

5) Utomo, S.H.T., 2004, JalanRel, Beta Offset, Yogyakarta

28

37. Course name : Pavement Design


Semester : V

Prerequisite Courses : 1) Building Materials and Fundamentals of Concrete Technology

(Semester III)

2) Geometric Design of Roads (Semester IV)

Objectives : Students will be able to perform mix design for flexible pavement

and able to design both flexible and rigid pavement; also able to

design pavement for runway and apron (airport pavement design)


required by taking into account several obstacles including


b) Possess knowledge in the development of the latest civil

engineering issues.

c) Able to apply the latest technology and software in civil

engineering.

Syllabus : The purpose of pavement material design, types, and pavement

construction materials; Asphalt and aggregate mix (Definition of

asphalt and aggregate, mix technology (basic concept of material

design, gradation design (definition of aggregate gradation,

gradation type and its impact to the mix, gradation specification,

target gradation (definition, function, and case example), aggregate

gradation design using analysis and graphic method);, Asphalt and

aggregate mix), mix properties, mix volumetric characteristics);

Pavement material design (mix design methods, optimum asphalt

content in the mix, mix specification, Marshall Mix Design); Solid

mix process and test result (Types of hot mix (AC, HRA/HRS,

SMA, dll.)); Mix performance evaluation (mix stiffness modulus;

pavement layer deformation, fatigue, durability, creep, etc.)

The aim of road pavement design and identify road pavement

structure (The aim of road pavement design, road pavement

structure (flexible and rigid), function of each pavement layer in

supporting vehicle load); Basic concept of pavement design (Basic

concept of pavement design, Road pavement design parameters: (1)

Soil bearing capacity (California Bearing Ratio (CBR) value, soil

reaction modulus value (k) and soil elastic modulus value (E);

Correlation between CBR, k, dan E), (2) Pavement design load and

damage factor, (3) Pavement layers materialsand relative strength

coefficient, (4) Environmental parameter); Stresses in pavement

structure (Stresses in pavement structure, Parameters in stress

analysis of pavement structure (point load and uniform load above

the pavement, contact plane radius from vehicle wheel), Single layer

theory according to Boussinesq theory and double layer theory

according to Burmister theory, Stress distribution in flexible and

rigid pavement); Pavement thickness design (Pavement thickness

design method, development of pavement thickness design

method); Calculation method of flexible pavement construction

layers (Unbound system, bound system, substandard roads); rigid

pavement thickness design: rigid pavement layers, soil reaction

29

modulus (k), concrete slab tensile strength, concrete slab elastic

modulus (E), types of rigid pavements, Jointed plain concrete

pavement (JPCP), Jointed reinforced concrete pavement (JRCP),

Continuous reinforced concrete pavement (CRCP), types of

concrete slab joints; Wastergaard theory (correlation between CBR

and soil reaction modulus, Types of loading: interior loading, corner

loading and edge loading, Deflection and stress of concrete slab due

to loading, concrete slab stress due to: curling, warping and

friction); Flexible pavement thickness design using component

analysis method: design parameters (Traffic (equivalent number,

LEP, LEA and LER), soil bearing capacity, regional factor, surface

index, relative strength coefficient (ai), minimum pavement layer

thickness, design application); flexible pavement design using

AASHTO 1972 revised 1981 method; Overlay design for flexible

pavement using component analysis method (Bina Marga) and

AASHTO 1972 (revised 1981)

Pavement design of runway (flexible) and apron (rigid): factors

influencing runway and apron pavement; characteristics of plane

affecting the pavement: maximum take off weight, landing gear

type and geometry, load on main landing gear, equivalent annual

departures, conversion factors for landing gears, design aircraft;

Flexible pavement: subgrade, subbase course, base course, surface

course; Rigid pavement: subgrade, subbase or base course, concrete

slab, jointing of concrete pavement.


Practice : Laboratory activities for analysis and mixing of pavement materials

Bibliography : 1) Whiteoak D., 1990, The Shell Bitumen Handbook, Shell

Bitumen UK, Surrey, UK

2) Kreb, R.D. and Walker, R.D., 1971, Highway Materials,

McGraw Hill Book Company, USA

3) Asphalt Institute, 1997, Mix Design Methods, Manual Series

MS-2, USA

4) AASHTO, 1993, AASHTO Guide for Design of Pavement

Structures

5) BinaMarga, 1987, PerancanganTebalPerkerasanLentur

(analisakomponen)

6) TRL, 1993, A Guide to the Structural Design of Bitumen

Surfaced Roads in Tropical and Subtropical Countries, England

7) Yoder, E. J. and Witczak, M. W., 1975, Principal of Pavement

Design, Wiley and Sons, New York

8) Austroad, 2004, Austroad Pavement Design Guide

38. Course name : Statics II


Semester : V

Prerequisite Courses : 1) Statics I (Semester III)

2) Analysis of Stress, Strain, and Deformation (Semester IV)

Objectives : Students will be able to calculate internal forces of static

indeterminate structure due to vertical and horizontal loads

including the stiffness and displacement of the structure.

Learning Outcomes : Able to apply mathematics, science and technology in civil

engineering.

30

Syllabus : Definition of static indeterminate structure and degree of

uncertainty; stability and deformation equation; multi support beam

with continuous span, non-sway frame, andn swat frame; calculate

and draw moment diagram, shear force diagram, and axial force, in

continuous beam, non-sway frame and sway frame, due to vertical

and horizontal loads, and stiffness in single storey and multi storey

frame.


Practice : N/A

Bibliography : 1) Mc.Cormic, JC, 1996, Structural Analysis, International Text

Book Company, Pensylvania

2) Hsieh, Y.Y., 1982, Elementary Theory of Structures, 2nd Ed.,

Prentice Hall

3) Megson, T.H.G., 2014, Structural and Stress Analysis Third

Edition, Butterwort & Heinemann

4) Hibbeler, R.C., 2012, Structural Analysis 8thEdition., Prentice

Hall Int., Inc.

39. Course name : Civil Engineering Softwares I (Hydraulic, Environmental,

Transportation)


Semester : V


Objectives : Students will be able to understand, apply software and hardware,

also able to create simple software in hydraulic, environmental, and

transportation

Learning Outcomes : Able to apply the latest technology and software in civil

engineering.

Syllabus : Application of software in Hydraulic, Environmental, and

Transportation Civil Engineering:

1. Hydraulic engineering: application of software to predict peak

and bottom flow pattern, investigation of flood flow based on

characteristic changes of catchment area (HEC-HMS, WMS,

HEC-RAS), water pipe network design (WATER-NET)

2. Environmental engineering: software for analysis of pollution

distribution dynamics in river flow, river water quality

index/classification rating

3. Transportation engineering: Software VISSIM for micro

simulation and AIMSUN for macro simulation, application of

VISSIM for signalized intersection analysis, application of

AIMSUN for regional transportation simulation; introduction to

software for material characterictics analysis (especially asphalts)

– BANDS; introduction to software for stress and strain analysis

in pavement: BISAR (Shell) and KENPAVE; software for

pavement thickness design: SPDM (Shell Pavement Design

Method).

Studio practice : Software application for analysis and design in Hydraulic,

Environmental, and Transportation Engineering

Practice : N/A

31

Bibliography : 1) Hydrologic Engineering Center, 2010, HEC-RAS River

Analysis System, Applications Guide, Version 4.1, U.S. Army

Corps of Engineers, Davis California

2) Scharffenberg, W.A., dan Fleming, M.J., 2010, User Manual of

Hydrologic Modeling System HEC-HMS, HQ US Army Corps

of Engineers, Washington DC

3) AquaVeo, 2014, WMS 10.0 Tutorial, Introduction to WMS

4) Transport Simulation System (TSS), 2010, Users Manual

Aimsun 6.1., Barcelona.

5) PTV VISION. 2014. PTV VISSIM 7 User Manual. PTV AG,

Karlsruhe, Germany.

40. Course name : Water and Waste Water Management Engineering


Semester : V

Prerequisite Courses : Open channel hydraulics (Semester IV)

Objectives : Students will be able to understand public and environmental health

problems in relation to water resources quality condition, drinking

water quality and waste water quality and drinking water and waste

water quality standard; able to explain types of water treatment

techniques; able to design (basic design) conventional water

treatment technique; able to explain sanitation system according to

a regional condition, able to design (basic design) domestic waste

water treatment technique.


interpret data.



economic, environmental, health andn security obstacles.



resources.

Syllabus : Public health problems in relation to drinking water and waste water

quality; water body, drinking water and waste water quality

standard; fundamentals of water treatment engineering;

fundamentals of conventional water treatment design

(sedimentation, coagulation-flocculation, filtration, and

disinfection); individual and communal/decentral/central waste

water treatment system, waste water reuse/recycle, 3R concept and

in pipe pollution control; domestic waste water production

projection, fundamentals of domestic waste water treatment design

(physical, chemical and biological treatment, including septic tank

and waste pond).


Practice : Field water sampling and laboratory testing for water quality

Bibliography : 1) Peavy, H.S., D.R. Rowe and G. Tchobanoglous, 1986,

“Environmental Engineering”, McGraw-Hill Book Cp, New

York

2) Hofkes, E.H., (editor), 1986, “Small Community Water

Supply”, John Wiley & Sons, Chicester

3) Metcalf & Eddy Inc, 2003, “Wastewater Engineering:

Treatment, Disposal and Reuse, Mac Graw Hill, USA

32

4) Droste, R.L., 1997, Theory and Studio practice of Water and

Wastewater Treatment”, John Wiley & Sons Inc., New York

5) Viessman, W. and Hammer, M.J., 1992, Water Supply and

Pollution Control, 5th-ed., Harper Collins College Publishers,

New York

41. Course name : Irrigation Engineering


Semester : V

Prerequisite Courses : Water Resources Management (Semester IV)

Objectives : Students will be able to conduct assignment in finding, compiling,

processing data, designing irrigation system and able to produce

design drawings/irrigation structure design


interpret data.






resources.

d) The broad education necessary to understand the impact of

engineering solutions in a global, economic, environmental, and

societal contex.

Syllabus : History of irrigation in the world and Indonesia, types of water

sources for irrigation, intake building and irrigation system;

regulations, institutions, irrigation facilities and infrastructures,

irrigation and drainage system design, water structure and drawing

technique, operation and maintenance, environmental aspects in

design and management of irrigation system.

Studio practice : Group assignment for design of intake system, channel, and

irrigation structure

Practice : N/A

Bibliography : 1) Departemen PU, 1986, Standar Perencanaan Irigasi (KP01-07)

2) Lim, Y.C. dan Kim, D.S., 1981, Hydraulic Design Studio

practice of Canal Structure, Korea Rural Environmental

Development Institute

3) Wang, J.K. dan Hagan, R.E., 1981, Irrigated Rice,

Press/Bouldert, Colorado

4) Tabuchi, T. dan Hasegawa, S., 1995, Paddy Field in the World,

JSIDRE

42. Course name : Reinforced Concrete Structure I


Semester : V

Prerequisite Courses : 1) Building Materials and Fundamentals of Concrete Technology

(Semester III)

2) Analysis of Stress, Strain, and Deformation (Semester IV)

Objectives : Students will be able to understand the basic concept of reinforced

concrete structure, and able to perform analysis and design of

section due to flexure, shear, and torsion also to analyze and design

33

beam, slab, stair, column and foundation and interpret the design

into detailed reinforcement.


engineering.




e) Able to identify, formulate, and solve the civil engineering


resources.

Syllabus : Basic concepts of reinforced concrete, properties of reinforced

concrete material, WSD design method. Analysis of rectangular

section due to flexural moment (WSD method). Service condition

review: deflection and cracks, detailing: concrete cover,

reinforcement bar spacing.

USD design method: load factor, reduction factor, required strength,

design strength, and nominal strength; analysis and design of

rectangular section due to flexural moment (USD method);

balanced condition, tension and compression controlled section,

reinforcement bar limits (minimum and maximum), beam section

will single and double reinforcement bar, T-beam section, single

and double reinforcement bar, flexural shear and torsional shear on

beams. Analysis and design of slab.

Beam analysis and design with normal force and flexural moment,

types of sections, beam behavior, centric normal force on short

column with square section, combination of normal force and

flexural moment, interaction diagram M-N; analysis and design of

slender column.

Anchorage length, overlap length, slab design and analysis, one way

and two way slab using moment coefficient method; reinforcement

bar detailing/drawing.

Analysis and design of footing foundation and pile cap, stair design


Practice : N/A

Bibliography : 1) ACI, Building Code Requirements for Structural Concrete (ACI

318M-11), An ACI Standard and Commentary, Farmington

Hills, MI, 2011

2) SNI 2847:2013,Persyaratan Beton Struktural untuk Bangunan

Gedung

3) SNI 1726:2012, Tata Cara Perencanaan Ketahanan Gempa

Untuk Struktur Bangunan Gedung Dan Non Gedung

4) MacGregor J.G., Wight J.K., 2008, Reinforced Concrete

Mechanic and Design, 4th Ed. In SI Unit, Pearson Prentice Hall

5) Nilson, A.H., Darwin, D., Dolan, C.D., 2005, Design of

Concrete Structures, 13th Ed., McGraw Hill

34

43. Course name : Steel Structure I


Semester : V


Objectives : Students will be able to understand the use of steel in civil

engineering building structures, design method and element

analysis including brief description in the implementation of steel

structure element.


engineering.






resources.

Syllabus : Overview of civil engineering building with steel as main material,

types of steel used in civil engineering structure. Mechanical

properties of steel: steel stress-strain diagram, corrosion behavior,

relaxation and fatigue.

Design and analysis of tension and compression beam element.

Types of structural steel connections, bolted connection and welded

connection. Design and analysis of flexural member including types

of profiles to be used. Design and analysis of single column,

compound column, and beam-column in multi-storey building.


Practice : N/A

Bibliography : 1) Salmon C.G, and Johnson, JE, 1980, Steel Structure Design and

Behaviour, Harper and Row, New York

2) AISC 360, 2010, Specification for Structural Steel Buildings,

10th edition

3) Gere, J.M. and Timoshenko, S.P., 2004, Mechanics of

Materials, Sixth Edition, Wordsworth Inc.

4) SNI 1726-2012 - Tata Cara Perencanaan Ketahanan Gempa


5) SNI 1729-2015 Spesifikasi untuk Bangunan Gedung Baja

Struktural

6) AISC, 2009, Specification for the Design, Fabrication, and

Erection of Structural Steel for Building

7) Segui W. T., 2013, Steel Design, 5th Edition, Cengage Learning,

Singapore

8) Wiryanto D,, 2015, Struktur Baja – Perilaku, Analisis & Desain

– AISC 2010, Lumina Press

9) AISC, 2010, Steel Construction Manual 14th Edition, American

Institute of Steel Construction, Chicago, Illinois.

35

44. Course name : Deep Foundation Engineering


Semester : V

Prerequisite Courses : 1) Soil Mechanics II (Semester IV)

2) Shallow Foundation Engineering (Semester IV)

Objectives : Students will be able to design and plan deep foundation, sheet pile,

and bored pile.


engineering.


interpret data.



economical, environmental, health, and security obstacles..

d) Possess knowledge in the latest development of civil

engineering issues.

Syllabus : Definition of sheet pile, cantilever sheet pile, anchored sheet pile,

definition of pile foundation and bored pile, analysis of single pile

bearing capacity, block collapse, pile efficiency, calculation of pile

reaction, pile cap design, pile distance, pile resisting lateral force

(ultimate bearing capacity, pile deflection), pile design for retaining

wall.


Practice : N/A

Bibliography : 1) Bowles, J.E., 1994, Foundation Analysis and Design, Mc.

Graw-Hill, Inc, New York.

2) Coduto, D. P. 1994, Foundation Design: Principe and Studio

practices, Prentice Hall, Englewood Cliffs, New Jersey, USA.

3) Hardiyatmo, H.C. 2010, Analisis dan Perancangan Fondasi II,

UGM Press, Yogyakarta.

4) Suryolelono, K. B., 1994, Teknik Fondasi II, Nafiri, Jogjakarta.

45. Course name : Timber and Bamboo Structure


Semester : V


Objectives : Students will be able to understand physical and mechanical

properties of timber and bamboo; to understand the creation of

timber and bamboo engineering products; to understand materials

and methods of timber and bamboo preservation, able to design

timber construction elements including the connection system.


engineering.






resources.

Syllabus : Project overview of timber and bamboo construction, physical and

mechanical properties of timber and bamboo, timber grading,

introduction to timber and bamboo engineering products i.e.

36

plywood, oriented strand board, glulam, structural composite

lumber, materials and methods for timebr and bamboo preservation,

introduction to timber construction standard code, design of beams

in tension, compression, flexure, beams with combination of flexure

and compression, introduction to types of timber and bamboo

connection, design of timber and bamboo connection, design of

lateral resistance system of timebr construction due to seismic load,

environmental aspects in timber and wood construction.


Practice : N/A

Bibliography : 1) Breyer, D.E., 1980 dan 1988, Design of Wood Structures,

McGraw Hill, Highstown, New York

2) BSN, 2002, Tata cara perencanaan konstruksi kayu Indonesia,

Bandung

3) BSN, 2002, Standar Perencanaan Ketahanan Gempa untuk

Struktur Bangunan Gedung, Bandung

4) Morisco, 1999, Struktur Bambu, Penerbit Nafiri

5) Awaludin, A dan Irawati, I.S., 2005, Konstruksi Kayu, Biro

Penerbit, Departemen Teknik Sipil dan Lingkungan FT UGM

6) Awaludin, A., 2005, Dasar-dasar sambungan kayu, Biro

Penerbit, Departemen Teknik Sipil dan Lingkungan FT UGM

46. Course name : Numerical Method II


Semester : VI

Prerequisite Courses : 1) Numerical Method I (Semester IV)

2) Statics II (Semester V)

Objectives : Students will be able to apply computer-based matrix method in

structural analysis, calculating response (displacement, support

reactions, and internal forces) for truss strcutures (2 and 3

dimension), grid, frame (2 and 3 dimension), elastic support, and

understand several computer program packages for structural

analysis based on matrix method and its application.


engineering.


engineering.

Syllabus : Introduction, relationship between classical method and matrix

method, review of matrix algebra, basic concepts of structural

analysis, idealization, and mathematical modelling, principle of

flexibility and stiffness method, direct stiffness method and its

application in structural analysis of 2- and 3-dimensional truss, grid,

frame, and arch structure, elastic support, computer program and its

application.

Studio practice : The application of computer-based matrix method in structural

analysis

Practice : N/A

Bibliography : 1. Bambang Suhendro, 2005, Analisis Struktur Metode Matrix,

Edisi ke 2, Beta Offset, Yogyakarta

2. Weaver, W, and Gere, J.M, 1980, Matrix Analysis of Framed

Structures, 2nd edition, D. Van Nonstrand Company, New York

37

3. Flemming, J.F., 1986, Structural Engineering Analysis on

Personal Computers, Mc. Graw Hill Inc., New York

4. Ghali, A and Neville, A.M., 1986, Analisis Struktur Gabungan

Metode Klasik dan Matriks, Edisi ke 2 (terjemahan), Penerbit

Erlangga, Jakarta

47. Course name : Dynamic Structural Analysis and Earthquake Engineering

Course code/UCU : TKS 3202/3.0

Semester : VI

Prerequisite Courses : Statics II (Semester V)

Objectives : Students will be able to identify and explain types and

characteristics of dynamic loads and its impact to a structure, to

formulate dynamic problem of single and multi degree of freedom

with/without damping, free vibration, forced vibration and obtain

the solution though analysis/numerical method, calculate structure

response due to harmonic load, impulse load, irregular load, and

base motion. Understanding the event of earthquake, means to

measure earthquake magnitude, calculate forces occur to the

structure due to earthquake, and to design earthquake resistant

structure.


engineering.




c) Possess knowledge in the development of the latest civil

engineering issues

d) Able to apply the latest technology and software in Civil

Engineering.

Syllabus : Dynamic analysis, dynamic load and structural idealization,

centered mass system and distributed mass system, single degree of

freedom system, multi degree of freedom system,

analytical/numerical solution of structure response due to harmonic

load, impulse load, irregular load, and base motion. Earthquake

mechanism and means to measure earthquake magnitude, analysis

of seismic force in building structure, bridge and slope/dam, design

of earthquake resistant structure using elastic and ductile method,

Indonesia seismic code and its application.

Studio practice : None

Practice : Vibration measurement using accelerometer, computer program

application demo and presentation SAP-2000 & RUAMOKO

Bibliography : 1) Bambang Suhendro, 2000, Analisis Dinamik Struktur, Jurusan

Teknik Sipil, Yogyakarta

2) Clough & Penzien, 1993, Dynamic of Structures, Second

Edition, Mc. Graw-Hill, Inc., New York

3) Chopra, A.K., 1995, Dynamics of Structures-Theory and

Applications to Earthquacke Engineering, Prentice Hall Inc.,

New Jersey

4) Park & Paulay, 1975, Reinforced Concrete Structures, John

Wiley and Sons, Inc., New York

5) Peraturan Gempa Indonesia.

38

6) Paz, M., 1985, Structural Dynamics - Theory and Computation,

2nd ed., Van Nostrand Reinhold Co., New York

48. Course name : Introduction to Construction Management


Semester : VI


Objectives : Students will be able to understand project management process

from tender stage to the construction phase.

Learning Outcomes : a) Multidisciplinary team work capability.

b) Leadership, professional responsibility and ethics in civil

engineering.

c) Good communication skill.

d) Comprehensive knowledge in the impact of infrastructure

development implementation to social, economic, and

environmental aspects.

e) Knowlege in the development of the latest issues in civil

engineering.

f) Ability to apply the latest technology and software in civil

engineering.

Syllabus : Discussion in the definition and scope of contruction management,

regulations in Indonesia, project organization, project cycle (from

planning, tender, contruction to monitoring and evaluation stage

especially calculation concept to define the progress of each

contruction work item), tender documents (RKS and design

drawing), calculation of BQ (Bill of Quantity) and cost estimation

RAB, construction products, HSE aspects (Health and Safety),

concept of project planning and scheduling, and Quality manajemen

in construction project.

Studio practice : No structures assignment. However, students will be given 2 group

assignments of tender simulation of design work (before midterm)

and tender simulation of construction work (after midterm) to obtain

comprehension in project cycle.

Practice : None

Bibliography : 1) Griffis, F.H., and Farr, V., 2000, Construction Planning For

Engineers, McGraw-Hill, USA

2) Harris, F., and McCaffer, R., 2001, Modern Construction

Management, Fifth Edition.

49. Course name : Port Engineering


Semester : VI


Objectives : Students will be able to understand ports as the transition place of

transportation mode from water transportation to land transportation

and the opposite. In order for port to function well, the port shall be

supported by good infrastructure complying with international

service standard, the infrastructure include: fairway, wharf,

breakwater, port basin, loading & unloading equipment, and

navigation aid facility.

39






resources.

c) Possess knowledge in the latest development of civil

engineering issues

Syllabus : Meaning and definition of port, types and examples of ports, port

function, introduction to water transportation, development of water

transportation in the world, fundamentals of port design, hydro-

oceanography, breakwater planning, fairway, wharf planning,

fender and dolphin planning, port infrastructure for multi purposes

(brief discussion), navigation aid facility, dredging, case study port

masterplan.


Practice : N/A

Bibliography : 1) Thoresen, C.A., 2006, Port Designer’s handbook:

Recommendations and Guidelines, Thomas Telford

2) CIRIA-CUR, 1991, Manual on The Use of Rock in Coastal and

Shoreline Engineering, Construction Industry Research and

Information Association, London

3) US Army Corps of Engineers, 1994, Coastal Groins and

Nearshore Breakwaters, American Society of Civil Engineers,

New York

4) Bruun, P., 1989, Port Engineering, Vols 1 and 2, Gulf Publishing

Company, Houston

5) Bruun, P., 1985, Design and construction of mounds for

breakwaters and coastal protection, Elsevier, Amsterdam

6) Tsinker,G.P., 1997, Handbook o port and harbor engineering,

Chapman & Hall, London

7) OCDI, 1999, Technical standards for port and harbor facilities

in Japan, Port and Harbour Research Institute, Ministry of

transport, Tokyo, Japan

8) Quin, A.D., 1972, Design and construction of ports and marine

structures, McGraw-Hill, Inc, New York

50. Course name : Research Method, Academic Writing, and Presentation


Semester : VI


Objectives : Students will be able to understand simple research method in civil

engineering; able to understand and conduct scientific writing, able

to comprehend, compose and conduct oral presentation.

Learning Outcomes : a) Able to design and conduct research, and to analyze and

interpret data.

b) Good communication skill.

Syllabus : Scientific writing components, scientific writing techniques

including proposal, thesis manuscript and thesis report, definition of

plagiarism and ways to avoid plagiarism, presentation components,

how to create good presentation, presentation technique,

presentation media.

Studio practice : Essay writing and presentation

40

Practice : None

Bibliography : 1) Achmadi, Muchsin, 1988, Materi Dasar Pengajaran Komposisi

Bahasa Indonesia, Depdikbud Dikti, Jakarta

2) Fajar, M., 2009, Ilmu Komunikasi, Teori dan Praktik, Graha

Ilmu & Univ. Mercu Buana, Yogyakarta

3) Ibrahim, I.S., 2007, Kecerdasan Komunikasi- Seni

Berkomunikasi Kepada Publik, Simbiosa Rekatama Media,

Bandung

4) King, L., Gilbert, B., 2007, Seni Berbicara, Gramedia, Jakarta

5) Harber, Mary (Ed), 1993, Manual on Scientific Writing, TAFE

Publication, Victoria

51. Course name : Software in Civil Engineering II (Building Structure and Material,

Geotechnics and Construction Management)


Semester : VI


Objectives : Students will be able to understand, utilize software and hardware,

also able to create simple software in structural and material

engineering, geotechnics and construction management.

Learning Outcomes : a) Able to design and conduct research, and to analyze and

interpret data.


engineering.

Syllabus : 1) Building Structure and Material: program application for

structural analysisn and building structure design (SAP,

ETABS) and bridge (MIDAS)

2) Geotechnics: Introduction to software Plaxis 2D for stress-strain

analysis, introduction to Slope /W for slope stability analysis

3) Construction Management: MS Project, Primavera

Studio practice : Software application for analysis and design of Building Structure

and Material Engineering, Geotechnics and Construction

Management.

Practice : None

Bibliography : 1) Introductory Tutorial for SAP 2000, 2011, Computers &

Structures, Inc., California USA.

2) Satyarno I., Nawangalam P., Pratomo, R.I.,2011, Belajar SAP

2000, Zamil Publishing, Yogyakarta

3) Primavera P6 Professional Project Manajement, Oracle.

4) SVSOILS: Aknowledge-based database system for

saturated/unsaturated soil properties, SoilVision System, Ltd.

52. Course name : Engineering Economics


Semester : VI


Objectives : Students will be able to understand and apply engineering

economics analysis method for feasibility study or selection of best

alternative in project planning.




41



resources.




Syllabus : Role of engineering economic course in civil and environmental

engineering curriculum; production factors of civil engineering

structures; understanding of capital value, present value, and future

value; calculation of asset depreciation and resource depletion; cost

components (including tax, shadow price, and grace period;

comprehension in project feasibilities (BCR, IRR, dan NPV); civil

engineering project funding; Risk analysis and uncertainty.


Practice : N/a

Bibliography : 1) Kuiper, E., 1977, WaterResources Project Economic,

Butterworth, Canada

2) Sprague, J.C., and Whittaker, J.D., 1986, Economic Analysis

for Engineers and Managers, Prentice-Hall, Englewood Cliffs,

N.J. 07632

53. Course name : Reinforced Concrete Structure II


Semester : VI

Prerequisite Courses : Reinforced Concrete Structure I (Semester V)

Objectives : a) Providing additional knowledge for civil engineering graduates

in special reinforced concrete detail planning.

Learning Outcomes : b) Able to design system and infrastructure in civil engineering as





resources.

d) Knowledge in the latest issue in civil engineering

e) Able to apply the latest technology and software in civil

engineering.

Syllabus : - Definition of structural ductility and the application philosophy

(SRPMB, SRPMM, SRPMK, Dual Frame System); Calculation

of negative moment capacity and positive at beam edges with

relation to structural ductility; force mechanics and force

mechanism and connection design (beam-column).

- Moment redistribution in continuous span, symmetric and

asymmetric design in semi-plastic way.

- Biaxial column reinforcement for rectangular and circle.

- Shear wall analysis of rectangulat and I section.

- Reinforcement bar of couple beam reinforcement, with simplified

assumption.


Practice : N/A

Bibliography : 1) ACI, Building Code Requirements for Structural Concrete (ACI

318M-11), An ACI Standard and Commentary, Farmington

Hills, MI, 2011

42

2) SNI 2847:2013,Persyaratan Beton Struktural untuk Bangunan

Gedung

3) SNI 1726:2012, Tata Cara Perencanaan Ketahanan Gempa






6) Varghese, P.C., 2003, Advanced Reinforced Concrete Design,

Prentice Hall of India Private Limited, New Delhi

7) Park, R., and Paulay, T., 1975, Reinforced Concrete Structures,

Jmateohn Wiley and Sons, NY.

54. Course name : Steel Structure II


Semester : VI

Prerequisite Courses : Struktur Baja I (Semester V)

Objectives : Students will be able to design and analyze girder beam, steel

composite structure as both compression and flexure element.






resources.

c) Possess knowledge in the development of the latest issues in

civil engineering


engineering.

Syllabus : Overview of girder and composite structures in civil engineering

structures, types of girder structures, design and analysis of girder

structure, composite theory of main steel material, types of

composite structure of main steel material, design and analysis of

steel-concrete composite structure in compression structure, design

and analysis of steel-concrete composite structure in flexural

structure, moment resisting frame system concept for steel structure,

(SRPMB, SRPMM, SRPMM, and dual system)


Practice : N/A

Bibliography : 1) SNI 1726-2012 - Tata Cara Perencanaan Ketahanan Gempa


2) SNI 1729-2015 Spesifikasi untuk Bangunan Gedung Baja

Struktural

3) AISC, Specification for the Design, Fabrication, and Erection of

Structural Steel for Building

4) Segui W. T., 2013, Steel Design, 5th Edition, Cengage Learning,

Singapore

5) Wiryanto D, 2015, Struktur Baja – Perilaku, Analisis & Desain

– AISC 2010, Lumina Press

6) ACI, Building Code Requirements for Structural Concrete (ACI

318M-11), 2011, An ACI Standard and Commentary,

Farmington Hills, MI.

7) SNI 2847, 2013,Persyaratan Beton Struktural untuk Bangunan

Gedung

43





10) Oehlers, D.J., Bradford, M.A., 2012, Elementary Behaviour of

Composite Steel and Concrete Structural Members, Taylor &

Francis

55. Course name : Drinking Water Supply Engineering


Semester : VI


Objectives : By the end of this course, students will be able to design drinking

water supply system (piping network and water treatment

installation).


interpret data.






resources.

Syllabus : Problems and demands in drinking water supply system; water

demand; design of drinking water supply system; water source,

availability of water and water intake structure; design of drinking

water netwrk system (carrier network, distribution network, tank &

reservoir, pump, valve & network utilities); water treatment

installation design, operation and maintenance basics of drinking

water supply system.


Practice : N/A

Bibliography : 1) Baruth, E.E. (Technical Editor), 2005, “Water Treatment Plant

Design”, AWWA & ASCE, 4th edition, McGraw-Hill, Inc.,

New York

2) Crittenden, J., 2005, “Water Treatment: Principles and Design”,

John Wiley & Sons Inc., 2nd edition, New Yersey

3) Droste, R.L., 1997, “Theory and Studio practice of Water and

Wastewater Treatment”, John Wiley & Sons Inc., New York

4) Radianta Triatmadja, 2009, Hidraulika Sistem Jaringan

Perpipaan Air Minum, Beta offset, Yogyakarta

56. Course name : Traffic Management


Semester : VI

Prerequisite Courses : Traffic Engineering (Semester III)

Objectives : After studying Traffic Management, students will be able to

understand the meaning, objectives, advantages and various traffic

management strategies; traffic management in road space; traffic

management in various types of intersections; intersection

coordination; speed management for road safety; parking

management; demand management; provision of facilities for

44

pedestrians, slow vehicles and public transportation; and able to

apply the knowledge in a simple case.




b) Comprehensive knowledge in the impact of infrastructure



c) Knowledge in the development of the latest issues in civil

engineering.

d) Able to apply technology and software in civil engineering.

Syllabus : Definition of traffic management; traffic management strategies;

traffic management in road sections; traffic signs and markings;

various traffic management on intersections, traffic managemeny on

priority intersections, traffic management on roundabouts; traffic

management on signalized intersections; intersection coordination;

limitation of traffic speed and traffic safety; parking management;

trip demand management; pedestrian facilities; facilities for slow

vehicles; traffic management on public transportation; several

examples on traffic management in developed countries and

developing countries.


Practice : N/A

Bibliography : 1) Institution of Highways and Transportation (IHT), 1987, Road

and Traffic in Urban Areas, IHT, London

2) Munawar, A., 2004, Manajemen Lalu lintas Perkotaan, Beta

Offset, Yogyakarta

3) Ogden, K. W. and Taylor S. Y., Traffic Engineering and

Management, 1996, Institute of Transport Studies, Monash

University, Australia

4) Berbagai Peraturan Perundang-undangan tentang Manajemen

Lalu Lintas

5) Berbagai Peraturan Perundang-undangan tentang Rambu dan

Marka

57. Course name : Site Investigation


Semester : VI

Prerequisite Courses : 1) Deep Foundation (Semester V)

2) Pavement Design (Semester V)

Objectives : Students will able to understand the techniques for soil

investigation for various civil engineering structures, and to

determine the equipment used.

Learning Outcomes : a) Able to conduct design and research, also able to analyze and

interpret data.






resources.

45




e) Knowledge in the development of the latest issue in civil

engineering.

Syllabus : Investigation program, preliminary investigation and details,

number of boring points, boring depth, boring technique, sample

collection and treatment, SPT test, cone penetration test, fan shear

test, field CBR test, dynamic cone penetration test (DCP), plate load

test, geophysical test and interpretation and correlation of the test

result, landslide investigation and ground movement,

instrumentation and monitoring, site investigation for planning,

design, and performance evaluation of transportation infrastructure,

situation mapping (terrestrical, aerial), bathymetry, obsertvation of

environment physical condition, measurement and sampling of

water quality, hydrometry (water surface, tide, flow speed, wind,

and wave), sediment measurement and sampling, compilation and

analysis of climatology data.


Practice : N/A

Bibliography : 1) Clayton, C.R.I., Matthews, M.C. dan Simons, N.E., 1995, Site

Investigation, Second Edition, Blackwell Science Ltd.

2) Weltman, A.J. dan Head, J.M., 1983, Site Investigation Manual,

CIRIA, London

3) Hardiyatmo, H.C., 2010, Analisis dan Perancangan Fondasi I,

UGM Press, Yogyakarta

58. Course name : River Engineering


Semester : VI


Objectives : Students will be able to understand the river dynamics and able to

identify river potentials, also to understand the technique for

destructive potential of the river and its utilization techniques.

Learning Outcomes : b) Memiliki kemampuan dalam merancang dan melakukan




resources.

Syllabus : Definition of river, river characteristics, river basin, hydrology

cycle, river morphology, geometry, section capacity, river junction

and branching, sediment transport, erosion and sedimentation, local

erosion, river engineering, temporary and permanent river repair,

channel control, water surface control, discharge control, flood

control, sediment control, river mapping and hydrometry, utilization

of river resources, weirs, river model introduction, physical model,

mathematical model, environmental aspect in river engineering.


Practice : N/A

46

Bibliography : 1) Jansen, P. Ph., van Bandegom, L., van den Berg, J., de Vries,

M., Zanen, A., 1979, Principles of River Engineering, the Non-

tidal Alluvial River, Pitman, London

2) Justin, D., Hinds, J., Creager, W.R., 1961, Engineering for

Dams, Vols. I, II, III, John Wiley and Sons, Inc., New York

3) Petersen, M., 1985, River Engineering.

4) Fenton, J., 2011, River Engineering, Institute of Hydraulic and

Water Resources Engineering, Vienna university of

Technology.

59. Course name : Ground Water Flow


Semester : VI


Objectives : Students will be able to understand the concept of formation

mechanism and properties of ground water and the impact to the

surrounding environment.






resources.

c) Knowledge in the development of the latest issues in civil

engineering.


engineering.

Syllabus : Formation of aquifer, knowledge in ground water layers,

permeabilityp, aquifer classification, paraller and radial flow, steady

and unsteady condition, also underground river, environmental

aspect in ground water flow. New pumping method including the

determination of drawdown, calculation in pumping efficiency,

analysis of pumping power requirement, shape factor and drain

spacing function.


Practice : N/A

Bibliography : 1) 6Reddi L.N. 2003. Seepage in Soils, Principles and

Applications, John Wiley & Sons Inc.

2) Sunjoto S., 2002. Recharge Wells as Drainage System to

Increase Groundwater Storage, Proc. on the 13rd IAHR-APD

Congress, Advance in Hydraulics Water Engineering,

Singapore, 6-8 August 2002 Vol.I, pp. 511-514, 2002.

3) Sunjoto S. 2015. Uncertainty of Lugeon Unit Value Related to

the Influence of Drill Diameter and Aquifer Layers. E-Proc. Of

the 36th IAHR World Congress, 28 June-3 July 2015, The Hague

the Netherlands.

4) Sunjoto S. 2015. Simplified Drain-Spacing Computation

Method to Reduce Groundwater Table. E-Proc. of the 36th IAHR

World Congress, 28 June-3 July 2015, The Hague the

Netherlands.

5) Todd D.K. 1980. Groundwater Hydrology, John Wiley & Sons

Inc.

47

6) Linsleyn R.K., M.A. Kohler J.I.H. Paulhus, 1975, Hydrology

for Engineers. New York, McGraw Hill Book Co.

7) Reddi L.N., 2003, Seepage in Soils, Principles and

Applications, John Wiley & Sons Inc.

60. Course name : Construction Health and Safety


Semester : VI


Objectives : Students will be able to understand the Health and Safety Executive

(HSE) aspect in construction and able to implement HSE in

construction project.

Learning Outcomes : a) Comprehensive knowledge in the impact of infrastructure



b) Knowledge in the development of the latest issues in civil

engineering.

Syllabus : Definition and terminology of security, cause of accident, definition

of HSE, rules relating to HSE, HSE management system, Personal

Protective Equipment, HSE Contractual Plan (RK3K),

Environmental Management System, HSE of Construction Work,

HSE of Scaffolding, HSE of Mechanical and Electrical Work, HSE

of Fire Extinguishing System, Construction HSE Inspection,

Construction Accident Analysis.

Studio practice : Presentation of case study paper

Practice : None

Bibliography : 1) Rudi Suardi, 2010, Sistem Manajemen Keselamatan dan

Kesehatan Kerja, Ppm Manajemen

2) Anizar, 2009, TeknikKeselamatan dan Kesehatan Kerja di

Industri, Graha Ilmu, Yogyakarta

3) Daryanto, 2002, Keselamatan dan Kesehatan Kerja, Rineka

Cipta, Malang

4) Ghuzdewan, T.A., 2015, Keselamatan dan Kesehatan Kerja

Proyek Konstruksi, Biro Penerbit KMTS, FT UGM,

Yogyakarta.

61. Course name : Community Development (KKN)

Course code/UCU : UN4101/0.0 + 3.0 (Studio practice)

Semester : VII


Objectives : Students will be able to apply the knowledges obtained from the

courses in synergy with other disciplines for community

development.

Learning Outcomes : a) Multidisciplinary team work.

48



resources.

c) Comprehension in leadership, professional responsibility and

ethics in civil engineering.

d) Good communication skill.

e) Willingness and ability for continuous personal development

and learning.

Syllabus : Involved in KKN-PPM LPPM UGM thematic programs.

Studio practice : Carry out the KKN work program in accordance with the defined

proposal.

Practice : N/A

Bibliography : Direktorat Pengabdian Kepada Masyarakat UGM, 2016, Buku

Pedoman KKN-PPM UGM.

62. Course name : Practice Work


Semester : VII


Objectives : Providing students with knowledge and practical experience in

applied theory in the implementation of work.

Learning Outcomes : a) Multidisciplinary team work.



resources.

c) Comprehension in leadership, professional responsibility and

ethics in civil engineering

d) Good communication skill.

e) Knowledge in the latest development of issues in civil

engineering

Syllabus : Project description (owner, contractor and supervisor), work

organization and system, human resources qualification and

equipment used, scope of work during Practice Work, problems and

technical criteria including non-technical criteria to solve the

problem, construction management and its accountability

relationship, supervision system and quality assurance of the work

result, other aspects in the scope of work relating to civil

engineering.

Studio practice : -

Practice : Conducting practice work and composing the report of practice

work

Bibliography : Jurusan Teknik Sipil dan Lingkungan FT UGM, 2013, Pedoman

Penulisan Tugas Akhir dan Tesis, JTSL FT UGM

63. Course name : Final Assignment

Course code/UCU : TKS 4201/0 + 6.0 (Studio practice)

Semester : VIII


Objectives : Students will be able to conduct comprehensive study and analysis

in order to solve problems in civil engineering.

49


engineering.


interpret data.




d) Able to identify, formulate, and solve the civil engineering


resources.

e) Good communication skill.

f) Knowledge in the latest development of civil engineering issues.

g) Able to apply the latest technology and software in civil

engineering.

Syllabus : Comprehensive design of civil engineering structure based on

analysis result of relevant supporting science..

Studio practice : Comprehensive study and analysis to solve problems in civil

engineering including: design, engineering review, or software

creation.

Practice : -

Bibliography : Jurusan Teknik Sipil dan Lingkungan FT UGM, 2013, Pedoman

Penulisan Tugas Akhir dan Tesis, JTSL FT UGM

64. Course name : Building Bridge Structure Design


Semester : VII

Prerequisite Courses : 1) Reinforced Concrete Structure II (Semester VI)

2) Steel Structure II (Semester VI)

Objectives : Students will be able to design building/bridge in compliance with

technical, security, and environmental aspects.






resources.

c) Knowldege in the latest development of civil engineering issues.

d) Ablel to apply the latest technology and software in civil

engineering.

Syllabus : Introduction: Limit State Design Concept, Design Procedure,

Standard/Code, Design Products

Predesign: Understanding architectural drawings and soil

investigation report; Design of structural plan system (Roof,

Beam, Column, Foundation); Prediction of structural elements

dimension (based on SNI, simple calculation/approach, chart

application)

Application of standards and codes for building structure

design: types of loads, load combinations, Load Path, load

effects, application of SNI 1727:2013; definition of seismic

load, application of SNI 1726:2012; application of SNI

50

Concrete (SNI 2847: 2013), Steel (SNI 1729:2015), Timber

(SNI 7973:2013).

Roof structure design: load analysis & load combination of

roof; structural modeling, structural analysis, result

interpretation; purlin design and its connections; roof sag rod &

bracing design; roof truss beam design, connections and

supports.

Building frame structure design: load analysis, load

combinations, seismic load analysis using static equivalent and

response spectra; structural modeling and structural analysis

using SAP, SAP2000 program result interpretation: definition

of maximum internal forces for design of each beam, column,

etc.

Structural element design: plate, stair, beam, column, joint,

foundation.

Building structure drawing: drawing types, drawing standard,

design drawing, detail drawing.

Calculation of Bill of Quantity (BoQ) for building structure:

calculation of structure quantity, unit price, BoQ.

Technical specification for building structure work

Studio practice : Assignment in building/bridge structural design and cost

Practice : N/A

Bibliography : 1) SNI 1727:2013, Beban minimum untuk perancangan bangunan

gedung dan struktur lain

2) SNI Gempa 1726: 2012, Tatacara perencanaan ketahanan

gempa untuk sruktur bangunan gedung dan non gedung

3) SNI 2847-2013, Persyaratan Beton Struktural Untuk Bangunan

Gedung

4) SNI 1729:2015, Spesifikasi untuk bangunan gedung baja

structural

5) SNI 7973-2013, Spesifikasi desain untuk konstruksi kayu

6) Permen PU No. 11/PRT/M/2013 Tentang Pedoman Analisis

Harga Satuan Pekerjaan

65. Course name : Project Planning and Scheduling


Semester : VII

Prerequisite Courses : 1) Reinforced Concrete Structure II (Semester VI)

2) Steel Structure II (Semester VI)

Objectives : Students will be able to understand the concept of planning,

scheduling, and controlling construction project.






resources.

c) Knowledge in the latest development in civil engineering issues


engineering.

51

Syllabus : Description of planning and scheduling concept, Work Breakdown

Structure (WBS), quantity survey method (QS: Quantity Survey),

creation of project Bill of Quantity (BoQ) based on SNI, creation

strategy of implementation budget plan (RAP), scheduling with Bar

Chart, creation of S-Curve, CPM concept (Critical Path Method) in

project scheduling using (arrow network planning), direct and

indirect cost aspect, project control, and earned value concept.

Studio practice : Assignment in Project Planning and Scheduling with case study

Practice : N/A

Bibliography : 1) Griffis, F.H., and Farr, V., 2000, Construction Planning For

Engineers, McGraw-Hill, USA

2) Harris, F., and McCaffer, R., 2001, Modern Construction

Management, Fifth Edition

66. Course name : Water/Waste Water Treatment Installation Design


Semester : VII

Prerequisite Courses : Drinking Water Supply Engineering (Semester VI)

Objectives : 1) Students will be able to design structure/installation of water

treatment in drinking water supply system of one urban area

with certain activities intensity and water standard condition.

2) Students will be able to design structure/installation of waste

water treatment of similar urban area.






resources.

c) Knowledge in the latest development of civil engineering issues


engineering.

Syllabus : Selection of water treatment process unit; determination of

installation capacity; determination of dimension, layout and

hydraulic analysis of each process unit; determination of layout,

dimension, and hydraulic analysis of installation piping/pum,

installation mechanical system, installation hydraulic profile,

creation of installation system design drawing.

Survey and data preparation of the existing water system condition;

data preparation of technical aspect of design area condition (ease

of operation, human resources, sludge quantity, effluent quality,

river water quality/outfall, energy requirement, housing condition,

general urban planning, map, and road length, clean water supply

facility, etc.), non technical aspects (construction and operation

cost, land availability); calculation of waste water quantity and

quality prediction; selection of treatment technology and flowsheet

creation; calculation of operation & process unit dimension and

piping length also building utilities

Studio practice : Water/Waste Water Treatment Installation Design

Practice : N/A

52

Bibliography : 1) Direktorat Jenderal Cipta Karya, Penyehatan Lingkungan

Pemukiman, 2012, Perencanaan Pengelolaan Air Limbah

dengan Sistem Terpusat

2) Mara, D., 1976, Sewage Treatment in Hot Climate, John Wiley

& Sons, London

3) Saraswati, S.P., 2009, Unit Proses Pengolahan Air Limbah,

Depertemen Teknik SIpil dan Lingkungan

4) Baruth, E.E. (Technical Editor), 2005, “Water Treatment Plant

Design”, AWWA & ASCE, 4th edition, McGraw-Hill, Inc.,

New York

67. Course name : Transportation Infrastructure Design


Semester : VII

Prerequisite Courses : Traffic Management (Semester VI)

Objectives : Students will be able to design transportation infrastructure in

compliance with technical, security, and environmental aspects.






resources.

c) Konwledge in the latest development in civil engineering issues


engineering.

Syllabus : Road infrastructure engineering design; basic theory in road

infrastructure design; review of basic theory of field survey in road

transportation; creation of work program and survey in

transportation; implementation of field survey; public transportation

facility; design of pedestrian facility; design of parking facility;

design of traffic control facility; analysis of traffic impact to the

environment; calculation of quantity and cost analysis.

Studio practice : Intersection design (geometric, layout and road utilities) for several

types of intersection for urban area (Signal & public transportation

stopping facility & special bus lane) dan U – Turn

Primary/Secondary Artery road

Practice : N/A

Bibliography : 1) Peraturan perundangan dan standar terkait dengan prasarana

transportasi yang berlaku

2) ASSHTO, 2011, A Policy Geometric Design of Highway and

Steets, 6th Edition, Washington

3) Ogden, K. W. and Taylor S. Y., Traffic Engineering and

Management, 1996, Institute of Transport Studies, Monash

University, Australia

4) Kazda, A. and Caves, R. E., 2007, Airport Design and

Operation, Elsevier, Jordan Hill, UK.

5) Ashford, N, 1992 Airport Engineering, McGraw-Hill, New

York

6) Horonjeff, R., 1994, Planning and Design of Airports, McGraw

Hill, New York

68. Course name : Geotechnics for Civil Engineering Structure Design

53


Semester : VII

Prerequisite Courses : Site Investigation (Semester VI)

Objectives : Students will be able to design civil engineering structure by taking

into account geotechnical aspects comprehensively from soil

investigation, interpretation of laboratory test results, application of

geotechnics in civil engineering structure, problem solving of

geotechnical and monitoring issues.






resources.

c) Knowledge in the latest development of civil engineering issues


engineering.

Syllabus : Soil investigation for building design; interpretation of laboratory

and field test results; application of geotechnics in building

structure, water structure and pavement problems; application of

soil stabilization using additives; application of soil improvement

using geosynthetic; application of soil improvement in embankment

andn excavation; study of field cases.

Studio practice : Assignment in Geotechnical Structure Design

Practice : N/A

Bibliography : 1) Ingles, O.G. and Metcalf, J.B., 1972, Soil Stabilization-

Principlesand Studio practice, Butterworths, Sydney,

Melbourne, Brisbane

2) Transportation Research Board (TRB), 1987, State of The

ArtReport 5-Lime stabilization, Transportation Research

Board,National Research Council, Washington

3) Department of the Army and the Air Forces (1994),

SoilStabilization for Pavements, Army TM 5-822-14, Air

ForceAFJMAN 32-1019, Washington DC

4) Holtz, R.D. and Kovacs, W.D., 1981, An Introducing

toGeotechnical Engineering, Prentice-Hall, Inc., Englewood

Cliffs,New Jersey

5) Hardiyatmo, H.C., 2009, Stabilisasi Tanah untuk Jalan

Raya,Gadjah Mada University Press., Yogyakarta

6) Koerner, R.M.,2005, Designing with Geosynthetics, Prentice-

Hall,Englewood Cliffs, N.J.

7) Clayton, C.R.I., Matthews, M.C. dan Simons, N.E., 1995, Site

Investigation, Second Edition, Blackwell Science Ltd.

8) Weltman, A.J. dan Head, J.M., 1983, Site Investigation

Manual,CIRIA, London

69. Course name : Hydraulic Structure Design


Semester : VII

Prerequisite Courses : River Engineering (Semester VI)

Objectives : Students will be able to design hydraulic structure in compliance

with technical, security, and environmental aspects.

54






resources.

c) Knowledge in the latest development of civil engineering issues.


engineering.

Syllabus : Design of dam/weir/water power structure/coastal structure; design

flood and wave,

Studio practice : Studio practice hydraulic structure design

Practice : N/A

Bibliography : 1) Pedoman Penyusunan Spesifikasi Teknis Volume II : Bendung,

http://www.pu.go.id/balitbang/sni/pdf/modul/013.pdf

2) Sri Harto Br., 2000, Hidrologi Teori-Masalah Penyelesaian,

Nafiri, Yogyakarta

3) Anonim, 2008, Manual Pembangunan Pembangkit Listrik

Tenaga Mikrohidro. IBEKA-JICA. Jakarta

4) Triatmadja, R., 2009, Teknik Pantai, Diktat Kuliah

70. Course name : Concrete Technology

Course code/UCU : TKS4109/1.5 + 0.5

Semester : VII

Prerequisite Courses : Building Materials and Fundamentals of Concrete Engineering

(Semester III)

Objectives : Students will understand the creation of concrete which requires

design and implementation for special requirement.






resources.


Syllabus : Students will be able to design and create special concrete which is

made with requirements, implementation, and for special

requirement such as Self Compacting Concrete (SCC), Roller

Compacted Concrete (RCC), Soil Cement, Mass Concrete,

Concrete for rigid pavement, concrete in aggressive environment,

precast concrete, and tilt-up concrete. Students will also be able to

recalculate the concrete mix design if sand and gravel used are not

in SSD (Saturated Surface Dry) condition and if plasticizer is used

in concrete mix. Concrete workability test apart from slump test is

also introduced for example Vebe Time, Compaction Test, U-Type

Test, and Flow Test.


Practice : Students conduct physical and mechanical properties test of

concrete basic materials, test procedure of concrete mix properties,

creation of mix example, maintenance, also hard concrete properties

test.

http://www.pu.go.id/balitbang/sni/pdf/modul/013.pdf

55

Bibliography : 1) Gambhir, M.L., 1986, Concrete Technology, Tata McGraw-

HillPublishing Company Limited, New Delhi

2) Shetty, M.S., 1997, Concrete Technology, S.Chand &

CompanyLtd., New Delhi

3) SNI (Standar Nasional Indonesia) yang terkait.

71. Course name : Prestressed and Precast Concrete Structure


Semester : VII

Prerequisite Courses : Reinforced Concrete Structure I (Semester V)

Objectives : 1) Students will understand design and implementation procedure

of prestressed concrete simple beam structure.

2) Students will understand design and implementation of precast

concrete.






resources.


Syllabus : Prestressed concrete structure: principles and basic concept of

prestressed concrete, types of prestressed concrete structure,

materials & equipment, types of tendon profiles and structural

analysis due to prestressing force, section properties, section

stresses and allowable stresses, prestressing force losses, flexural

and shear strength limit condition in beams. Design of anchorage

zone. Scope of discussion: static determinate beam (simple beam).

Precast concrete structure: application of precast concrete in civil

engineering structure, advantages and drawbacks, aspects to be

taken into account in precast structure design. Connections between

precast components. Building frame structure analysis made of

precast concrete. Several ways in the creation of floor system

(horizontal stabilizing system) and shear wall (vertical stabilizing

system) made of precast concrete. Structural element design, for

example slab plate, beam, column, and connection.


Practice : N/A

Bibliography : 1. Nawy, E.G., 2000, Prestressed Concrete, A Fundamental

Approach 3th Ed., Prentice Hall, Eng.Cliffs NJ

2. Gilbert, R.I., & Mickleborough, N.C., 1990, Design of

Prestressed Concrete, Unwin Heyman Inc., Cambridge, Mass

3. Collins & Mitchell, 1991, Prestressed Concrete Structures,

Prentice Hall, Eng.Cliffs NJ

4. A.E. Naaman, 1982, Prestressed Concrete Analysis and Design,

Fundamentals, Mc. Graw Hill, N.Y.

5. Elliot, K.S., 2002, Precast Concrete Structures, Butterworth

Heinemann Publications

6. Elliot K.S. and Tovey, a.K., 1996, Precast Concrete Frame

Building, Design Guide, British Cement Association, BCA’s

Publisher

7. PCI, Precast/Prestressed Concrete Institute, 1985, PCI Design

Handbook, third edition, Chicago, Illinois.

56

8. ACI T1.1-01, 1999, Acceptance Criteria for Moment Frames

based on Structural Testing and Commentary

72. Course name : Bridge Structure


Semester : VII


Objectives : Students will be able to understand the design of highway bridge

superstructure, from bridge deck plate to load bearing main structure,

for concrete girder bridge, steel frame bridge, and steel-concrete

composite bridge.






resources.



engineering.

Syllabus : Types of bridges, bridge structure components, and bridge loading

(highway andn railway). Deck design. Design of concrete girder

bridge (reinforced concrete, prestressed concrete). Steel-concrete

composite bridge design. Steel truss bridge design.


Practice : N/A

Bibliography : 1) Supriyadi, B., 1997, Analisis Struktur Jembatan, Biro Penerbit

KMTS FT UGM, Yogyakarta

2) Padosbajayo, 1994, Pengetahuan Dasar Struktur Baja, Penerbit

Nafiri, Yogyakarta

3) Kusuma, G.H., 2010, Perencanaan Bangunan Baja, Penerbit

Universitas Petra, Surabaya

4) Dep. PU, 1992, Bridge Design Manual (Panduan Perencanaan),

Bridge Management System 1992, Jakarta

5) Dep. PU, 2005, Standard Pembebanan untuk Jembatan, Yayasan

Badan Penerbit PU, Jakarta

6) AISC, 2000, Specification for the Design, Fabrication, and

Erection of Structural Steel for Building

7) Barker, M.R., Puckett, A.J., 1997, Design of Highway Bridges:

Based on AASHTO LRFD Bridges Design Specifications, John

Wiley & Sons, Inc. New York, USA

8) Troitsky, M.S., 1994, Planning and Design of Bridges, John

Wiley & Sons Inc. New York, USA

9) Salmon C.G, and Johnson, JE., 1980, Steel Structure, Design and

Behaviour, Harper and Row, New York

73. Course name : Monitoring and Control of Water Pollution


Semester : VII


Objectives : Students will be able to explain physical, chemical, and biological

properties of water quality & process phenomenon that produces

water quality on water body, understand the units and parameters

57

of water quality, students will be able to take sample, and measure

water sample on site also analysis of quality in laboratory, also data

management and process, conduct study in simple water quality

modeling to calculate river carrying capacity, pollution control

strategi in off stream and instream, understand the way to define

and calculate water quality status and its relation to ecohydraulic

river management.

Learning Outcomes : a) Memiliki kemampuan dalam merancang dan melakukan




resources.

c) Comprehensive knowledge in the impact of infrastructure



Syllabus : Definition of water health/water body; introduction to natural

phenomenon and the impact of human activities to physical

chemical properties of water and its toxicity; water quality

monitoring system, water sampling techniques, water quality

analysis, parameters and standards of water quality, management

and process of water quality data; pollutant properties, and the

impact of pollutant to water quality and ecosystem, River sefl

purification, effluent limited water bodies, water quality limited

water bodies, carrying and storage capacity of river water pollution,

and Streeter Phelp water quality model, WQ Index and water quality

quantification and ecohydraulical river water quality management.


Practice : N/A

Bibliography : 1) Sawyer, C.N., Mc.Carty, P.L. and Parkin, G.F., 2003,

”Chemistry for Environmental Engineering and Science”, Fifth

Edition, Mc.Graw-Hill, New York

2) Peavy, H.S., Rowe, D.R. and Tschobanoglous, G., 1986,

“Environmental Engineering”, McGraw-Hill Book Co.,

Singapore

3) Clesceri, L.S., Greenberg A.E. and Eaton, A.D. (ediotrs), 1998,

”Standard Methods for the Examination of Water and

Wastewater, APHA, Washington

4) PP RI No. 82 Tahun 2001 tentang Pengelolaan Kualitas Air dan

Pengendalian Pencemaran Air

74. Course name : Pavement Construction


Semester : VII

Prerequisite Courses : 1) Pavement Design (Semester V)

2) Earth Moving (Semester IV)

Objectives : 1) Students will be able to understand the root problem of road

structural damage

2) Students will be able to understand quality characteristic and

performance rating indicator of asphalt aggregate pavement

(flexible pavement) and cement aggregate pavement (rigid

pavement).

58

3) Students will be able to understand the pavement construction

process systematically and comprehensively.

4) Students will be able to understand the interaction of pavement

construction components to the negative impacts, also

adaptation and environmental effect mitigation on site.



economic, environmental, health and safety obstacles.



resources.


construction implementation.

d) Knowledge in the latest development of civil engineering issues.

Syllabus : Root cause of road pavement structure damage; definition and

classification of road pavement, comprehension in characteristic and

performance of asphalt aggregate pavement (flexible pavement) and

cement aggregate pavement (rigid pavement); comprehension in the

pavement construction process at each stage of road construction:

preservation, rehabilitation, reconstruction and new road

construction; stages of implementation and quality control process of

pavement; rock material supply process; aggregate grains formation

process; implementation of Job Mix Formula (JMF) and introduction

to field equipment for field trial; field equipment performance

control; material technology and road pavement preservation

equipment; productivity analysis, unit price, pavement construction

cost components.


Practice : N/A

Bibliography : 1) Kementerian Pekerjaan Umum, 2010, Spesifikasi Umum

Bidang Jalan dan Jembatan, Divisi-5 : Perkerasan Aspal, Jakarta

2) Kementerian Pekerjaan Umum, 2010, Spesifikasi Umum

Bidang Jalan dan Jembatan, Divisi-6 : Perkerasan Berbutir dan

Beton Semen, Jakarta

3) Peraturan Menteri Pekerjaan Umum Nomor 11/PRT/M/2013

tentang Pedoman Analisis Harga Satuan Pekerjaan Bidang

Pekerjaan Umum

4) FHWA, 2001. PCC Pavement Evaluation and Rehabilitation,

NHI Course 131062, Federal Highway Administration,

Washington, DC

5) FHWA, 2005. Full-Depth Repair of Portland Cement Concrete

Pavements, Pavement Preservation Checklist Series, Federal

Highway Administration, Washington, DC

75. Course name : Rock Mechanics


Semester : VII

Prerequisite Courses : 1) Introduction to Geology (Semester II)

2) Soil Mechanics I (Semester III)

3) Soil Mechanics II (Semester IV)

Objectives : Students will be able to understand the fundamentals of rock

mechanics in civil engineering works, especially tunnels and rock

slope stabilization.

59


engineering.


interpret data.




d) Knowledge in the latest development of civil engineering issues.

Syllabus : Definition of cycle and types of rocks and the role of rock mechanics

in the application, rock technical specifications, rock classification

in several systems, stress-strain behavior: rock collapse criteria,

application of rock mechanics in tunnel and rock slope stabilization

works.


Practice : N/A

Bibliography : 1) Goodman, R. E, 1980, Introduction to Rock Mechanics, John

Wiley & Sons., New York

2) ASTM, 2003, Section 4. Volume: 04.08 & 04.09 soil & Rock

3) JSCE, 2002, Pedoman Pekerjaan Terowongan Pegunungan

4) Day, R.W., 2000, Geotechnical Engineer’s Portable Handbook,

Mc Graw Hill, New York

76. Course name : Water Power Structure


Semester : VII


Objectives : Students will be able to understand the concept of water power

structure, utilization of water energy, design of simple water power

structure.

Learning Outcomes : a) Able to conduct design and analysis, and to analyze and interpret

data.




c) Knowledge in the latest development in civil engineering issues

Syllabus : History of water power utilization, definition of power and energy,

water power equation, electricity generation efficiency, definition

of the most economical main pipe carrying channel dimension.

Load diagram, load factor, capacity factor, unit load curve, daily and

yearly capacity of storage pond, definition of construction

discharge, analysis of river discharge measurement, discharge mass

line, non-dimensional discharge mass line, discharge addition line,

storage pond capacity, types of water power structure, penstock,

head race, anchor block, purification pond, types of sand box,

trashrack, hydraulic turbine, impulse turbine, reaction turbine,

turbine constant, cavitation, draft tube dan water hammer.


Practice : N/A

Bibliography : 1) Doland, J.J, 1954, Hidro Power Engineering, The Ronald Press,

New York

2) Mosonyi, E., 1965, water Power Development, Vol. I, II,

akademisi Kiado, Budapest

60

3) Creager, W.P., and justin, J.D., 1955, Hydroelectric Hand -

book, John wiley, New York

77. Course name : Fundamentals of Coastal Engineering


Semester : VI


Objectives : Students will be able to understand and design coastal structure

based on the applied norm, standard, guideline and manual.


interpret data.



resources.

Syllabus : Coast and sea as future resources, types and function of coastal and

offshore development and design principles, linear wave theory,

random wave theory, wave spectrum, sea water tide, forces on fixed

strucure: inertia and drag, forces on small structure (Morrison’s

equation), forces on large structure (Froude Krylov and Diffraction

Theory), design application, random wave effect (response

amplitude operator), implementation of offshore construction

(construction method), coastal zone management and coast

conservation, coast sediment transportation, environmental aspect

in coastal engineering.


Practice : N/A

Bibliography : 1) Stewart, R.H., 2000, Introduction to Physical Oceanography,

TexasA & M University Publ. Texas

2) Triatmadja, R., 2010, Tsunami, Kejadian, Penjalaran, Daya

rusakdan Mitigasinya, Gadjah Mada Univeristy Press

3) Triatmadja, R., 2009, Teknik Pantai, Diktat Kuliah

4) Triatmodjo, B., 1992, Teknik Pantai, Beta Offset, Yogyakarta.

5) Yuwono, Nur, 1998, Pengelolaan dan Pengamanan Daerah

Pantai,PAU IT UGM, Yogyakarta

78. Course name : Natural Disaster Mitigation


Semester : VII


Objectives : Students will be able to explain several physical phenomenon of

natural disaster, pre-disaster aspects, disaster process, post-disaster

aspects, disaster risk, also disaster risk management.

Learning Outcomes : a) Able to conduct design and reserach, and to analyze and

interpret data.



resources.

Syllabus : Types of natural disasters (earthquake, tsunami, flood, drought,

landslide), the process of natural disaster (preceeding phenomenon,

during the event, and aftermath), calculation of disaster risk index,

disaster risk management (mitigation, structural aspect, non-

61

structural aspect), disaster response management, rehabilitation and

reconstruction.


Practice : N/A

Bibliography : 1) Radianta Triatmadja, 2010, Tsunami, Kejadian, penjalaran,

Daya rusak dan Mitigasinya, Gadjah Mada University Press

2) Direktorat Jenderal Pesisir dan Pulau-pulau Kecil, 2004,

Pedoman Mitigasi Bencana di Wilayah Pesisir dan Pulau-pulau

Kecil, Departemen Kelautan dan Perikanan

3) Siswoko, 2012, Upaya Mengatasi Masalah Banjir Secara

Menyeluruh, PT. Mediatama Saptakarya, Yayasan Badan

Penerbit Pekerjaan Umum, Jakarta

4) Peraturan Kepala BNPB Nomor 4 Tahun 2008 Tentang

Pedoman Penyusunan Rencana Penanggulangan Bencana

79. Course name : Foreign Language (English)


Semester : VII


Objectives : Students will be able to understand technical terms in civil

engineering and able to correctly apply the terms contextually in

communication in English, both written and spoken, with standard

grammar for formal writing/presentation.

Learning Outcomes : a) Good communication skill.

b) Willingness and ability for continuous self development and

learning.

Syllabus : Grammar review; introduction to scientific writing; overview on

effective presentation; jargons in civil engineering.


Practice : N/A

Bibliography : Day R.A. dan Gastel, B., 2012, How to write and publish a scientific

paper, Cambridge University Press.

80. Course name : Foreign Language (Japan)


Semester : VII


Objectives : Students will be able to read and understand sentences written in

hiragana, katakana and basic kanji, able to perform daily

conversation and classroom conversation spoken slowly, students

will recognize several civil engineering terms in Japanese.

Learning Outcomes : a) Good communication skill.

b) Willingness and ability for continuous self development and

learning.

Syllabus : Introduction, greetings, basic conversation, Japanese grammar

(sentence structure, particle, present tense, present continuous tense,

past tense, invitation sentence, interrogative sentence, negative

sentence, imperative sentence, prohibition sentence, suggestion

sentence, permission sentence), vocabulary verb (I, II dan III),

transformation of vocabulary verb (–te, dan –ta), noun, adjective

(bentuk i dan na), Japanese letters: hiragana, katakana and 80 basic

Kanji.

62


Practice : N/A

Bibliography : 1) Yoshida, Y. 1992. Japanese for Today. Gakken

2) Kano, C., Takenaka, H., Ishii, E., Shimizu, Y., 1990. Basic

Kanji Book. Bonjinsha

81. Course name : Infrastructure Maintenance and Repair


Semester : VIII


Objectives : Students will be able to understand the concepts of infrastructure

maintenance and repair

Learning Outcomes : a) Able to identify, formulate, and solve the civil engineering


resources.

b) Knowledge in the latest development of civil engineering issues.


engineering.

Syllabus : Maintenance, Rehabilitation and Reconstruction strategy

(Maintenance, rehabilitation and reconstruction - M,R&R) including

infrastructure operation phase. Analysis of structural strength using

software SAP or SUNPRO. Recommendation from analysis result,

building repair program organization, building components repair

techniques, budget plan, repair schedule.


Practice : N/A

Bibliography : 1) Holmes M and Martin LM, 1983, Analysis and Design of

Structural Connections, Willey and Sons

2) Rockey KC, Evan HR, Grifths DW, 1983, The Finite Element

Method, 1983, Collins

3) Kirby PA, and Nethercot DA, 1980, Design for Structural

Stability, 1980, Collins

4) Hudson, W. R., Haas, R. C. G., & Uddin, W., 1997,

“Infrastructure Management”, McGraw -Hill

5) Kodoatie, R.J., 2005, Pengantar Manajemen Infrastruktur,

Bibliography Pelajar

82. Course name : Offshore Structure


Semester : VIII

Prerequisite Courses : Mathematics, Chemistry, Hydraulics, Structural Analysis, Steel

Structure, Reinforced Concrete Structure, Earthquake Engineering

Objectives : Students will be able to apply knowledge in mathematics, solve

practical problems in analysis and design of simple offshore

structure from production stage to installation and operational

stage.

Learning Outcomes : a) Able to design system and infrastructure in civil engineering by

taking into account several obstacles including economic,

environmental, health and security obstacles.

63



resources.

c) Knowledge in the latest development of civil engineering

issues.


engineering

Syllabus : Definition and introduction to offshore structure, types, offshore

structure system, integrated design of offshore structure

(considering creation, mobilization, installation, and operational

stages), repetition/deepening of several related topics i.e.

hydrodynamics (fluid flow behavior, structure dynamic response

due to wave force, random sea wave analysis, fatigue effect in

material mechanics properties especially steel), buckling effect

especialy pipe section member, marine structure foundation, steel

and reinforced concrete corrosion in saline environment,

construction method, feasibility evaluation of offshore structure


Practice : N/A

Bibliography : 1. Mather, Angus (1995). “Offshore Engineering”, Witherby &

Company Ltd. ISBN 1-85609-078-7

2. Committee on Standardization of Oilfield Equipment &

Materials (CSOEM), API (American Petroleum Institute),

www.api.org

83. Course name : Finite Element Method


Semester : VIII


Objectives : Students will be able to understand the basic principles of finite

difference method and finite element method and the application in

civil engineering.


engineering.


engineering.

Syllabus : Introduction, history of the development of finite element method

and its application in civil engineering. Approach solution concept,

optimization criteria, weighted residual method: collocation

method, subdomain, least-square, and Galerkin. Theoretical

development, numerical computation, and limit condition. Element

concept: discretization, convergen condition, random point,

assembly rule, trial function and Gauss integration in element,

coordinate transformation. Solution and application strategy in

hydraulic engineering.

3D elasticity theory, balance equation, strain-displacement, stress-

strain, compatibility. Energy method, potential energy, and

minimum potential energy, Rayleigh-Ritz. Finite Element Method

displacement formulation; 2D element: plane stress, plane strain,

axissymmetry, flexure plate, and plate above elastic foundation; 3D

https://id.wikipedia.org/wiki/Istimewa:Sumber_buku/1856090787

http://www.api.org/

64

element: plate, shell, and solid. Dynamic analysis, non-linear

geometry, and non-linear material. Application in structural

engineering, geotechnical and pavement. Introduction to several

software in civil engineering.


Practice : N/A

Bibliography : 1) Suhendro, B., 2000, Metode Elemen Hingga dan Aplikasinya,

Yogyakarta: Jurusan Teknik Sipil & Lingkungan, FT UGM

2) Cook, R.D., Malkus, D.S. & Plesha, M.E., 2002, Concepts and

Applications of Finite Element Analysis. 4th ed. Neww York:

John Wiley & Sons

3) Zienkiewicz, O.C. & Taylor, R.L., 2006, The Finite Element

Method. Massachussets Elsevier

4) Zienkiewicz, O.C. Taylor, R.L. & Nithiarasu, 2006, The Finite

Element Methodfor Fluid Dynamics, Massachussets Elsevier

84. Course name : Waste Water Management and Treatment


Semester : VIII


Objectives : Students will be able to plan and design collection system/network

and waste water treatment structure both individual and

communal/central system and understand the consequence of

technology selection and configuration of process units/flowsheet,

and fundamentals of operation and maintenance.


interpret data.






resources.

Syllabus : Waste water treatment by physical-chemical techniques, such as

flocculation coaggulation, neutralization, absorbtion. Review of

waster water treatment installation planning and design including

influence factors of planning and design of waste water treatment

system and structure, and advanced design in preliminary treatment,

primary treatment and secondary treatment for one area.


Practice : N/A

Bibliography : 1) Metcalf & Eddy, Inc, 2003, “Wastewater Engineering:

Treatment, Disposal and Reuse”, McGraw-Hill Higher

Education, International Edition, New York

2) Joseph A. Salvato, Environmental Engineering and Sanitation,

John Wiley & Son, Inc. Canada

3) Peavy, H.S., Rowe, D.R. and Tschobanoglous, G., 1986,

“Environmental Engineering”, McGraw-Hill Book Co.,

Singapore

65

85. Course name : Airport Engineering


Semester : VIII

Prerequisite Courses : 1) Introduction to Transportation Engineering (Semester II)

2) Introduction to Transportation Planning (Semester III)

Objectives : To provide students with the following abilities:

1) Identify the requirements of airport infrastructure and facilities

2) Identify problems in airside and landside infrastructures

3) Evaluate the performance of airport service

4) Plan geometry of air facility, including runway, taxiway, and

apron.






resources.



environmental aspect.

Syllabus : History of civil aviation and its development. The advantages and

disadvantages of air transportation with other transportation modes.

International civil aviation organization. Airport typical layout and

components. Airport classification. Airplane categories according

to FAA. General description of Indonesian airport, types,

characteristics, and airplane development. Airplane weight

component. Load and cruise distance. The effect of airplane

performance to runway. Declared distance. Definition of runway

direction and number. Obstacles of airport area. Selection of airport

location. Airport configuration. General design of airside

infrastructure geometry. Taxi system and configuration. Visual and

instrument flight rules (VFR dan IFR). Separation distance of air

traffic. Air navigation aid.


Practice : N/A

Bibliography : 1) Horonjef, Robert, et.al., 2010, Planing and Design of Air Port,

Mc Graw Hill

2) Graham, Anne, 2008, Managing Airports, an International

Perspective, Third Edition, Elsevier Ltd.

3) Wells, Alexander T., 2000, Airport Planning and Management,

fourth edition. McGraw Hill

4) FAA,1983, Airport Design Standards – Transport Airport

5) ICAO, 2004, Aerodrome Annex 14

86. Course name : Soil Improvement


Semester : VIII

Prerequisite Courses : 1) Soil Mechanics I (Semester III)

2) Soil Mechanics II (Semester IV)

Objectives : Students will be able to understand the basics of soil improvement.


interpret data.

66






resources.




e) Knowledge in the latest development of civil engineering issues

Syllabus : Definition of soil improvement, shallow compaction, deep

compaction, vertical drainage, vibroflotation, vibro replacement,

soil strengthening, stone column, soil strengthening using

geosynthetic, mechanical stabilization, stabilization with additives

(chemical stabilization), lime-soil, cement-soil, and fly ash-soil

stabilization.


Practice : N/A

Bibliography : 1) Ingles, O.G. and Metcalf, J.B., 1972, Soil Stabilization-

Principles and Studio practice, Butterworths, Sydney,

Melbourne, Brisbane

2) Transportation Research Board (TRB), 1987, State of The Art

Report 5-Lime stabilization, Transportation Research Board,

National Research Council, Washington

3) Department of the Army and the Air Forces (1994), Soil

Stabilization for Pavements, Army TM 5-822-14, Air Force

AFJMAN 32-1019, Washington DC

4) Holtz, R.D. and Kovacs, W.D., 1981, An Introducing to

Geotechnical Engineering, Prentice-Hall, Inc., Englewood

Cliffs, New Jersey

5) Hardiyatmo, H.C., 2009, Stabilisasi Tanah untuk Jalan Raya,

Gadjah Mada University Press., Yogyakarta

6) Koerner, R.M.,2005, Designing with Geosynthetics, Prentice-

Hall, Englewood Cliffs, N.J.

87. Course name : Sediment Transport


Semester : VIII

Prerequisite Courses : 1) Fluid Mechanics (Semester II)

2) Open Channel Hydraulics (Semester IV)

Objectives : Students will be able to understand the hydraulics of sediment

transport and its application in technical design of civil engineering

structure.


interpret data.



resources.

Syllabus : Sedimentation problem, properties of water and sediment, particle

fall speed, initial movement of sediment particle, transport

mechanism and base configuration, base sediment transport (bed

load), suspension sediment transport (suspended load), riverbed

67

degradation and agradation, stable channel design, debris flow,

sediment transport in estuary, dam sedimentation.


Practice : N/A

Bibliography : 1) Yang, CT, 1996, Transport of Sediment, Mc Graw Hill

Publishing Company

2) Dyer, Keith R, 1985, Coastal and Estuarine Sediment

Dynamics, John Willey & Sons

3) Graf, W.H., 1984, Hydraulics of Sediment Transport, Mc. Graf

Hill, N.Y., USA

4) Vanoni, V. A., 1975, Sedimentation Engineering, ASCE, N.Y.,

USA.

5) Yang, CT, 1996, Transport of Sediment, Mc Graw Hill

Publishing Company.

6) Situs internet USBR, USLE

88. Course name : Hydrology and Applied Hydraulics

Course code/UCU : TKS4209/2

Semester : VIII

Prerequisite Courses : 1) Hydrology (Semester III)

2) Fluid Mechanics (Semester II)

3) Open Channel Hydraulics (Semester IV)

Objectives : Students will be able to understand the hydrological phenomenon,

both in river system and communal water system, also able to

operate several softwares to determine hydrological design scale,

the impact of catchment area treatment to large and small extremem

flow.

Students will be able to understand several flow phenomenon in

simple channel, including simple channel (single channel, prismatic

section), river network, andn flow through hydraulic structure, also

master mathematical model software one dimension

hydrodynamics.


interpret data.



resources.


engineering.

Syllabus : Hydrology review (rain-flow response and frequency analysis),

effect of land closure (vegetation, road network, infrastructure) to

continuous flow phenomenon (low flow) also eventual flow (peak

flow), global weather change, low and peak flow calculation

method, software application to predict peak and low flow pattern

based on characteristic change in catchment area (HEC-HMS,

WMS), environmental aspect in the implementation of hydrological

analysis.

Review of flow types (permanent flow, non-permanent flow,

uniform flow, non-uniform flow), basic equation of flow and

numerical solution, one dimensional mathematical model

(algorythm, numerical solution, hydraulic stability), application of

hydrodynamic mathematical model for flood routing: simple

68

channel (single channel, prismatic section), junction, bridge,

culvert, permanent dam, movable dam.


Practice : N/A

Bibliography : 1) Ponce, 1990, Principle in Engineering Hydrology, Butterworth



3) F.J. Mock, 1973, Land Capability Appraisal Indonesia, Water

Availability Appraisal, FAO UN, Bogor, Indonesia

4) Scharffenberg, W.A., 2013, Hydrologic Modeling System

HEC-HMS: User’s Manual, U.S. Army Corps of Engineers,

HEC, Davis, CA

5) Sujono, J., 2014, Petunjuk Singkat Aplikasi HEC-HMS, Jurusan

Teknik Sipil dan Lingkungan FT UGM.

6) USAC, 2010, HEC-RAS Hydraulic Reference Manual, U.S.

Army Corps of Engineers, Institute for Water Resources,

Hydraulic Engineering Center, Davis, USA

89. Course name : Construction Method


Semester : VIII


Objectives : Students will be able to understand the construction process from

preliminary works to finishing works.






resources.



engineering.

Syllabus : Describing the concept of the importance of understanding each

construction method to gain result in compliance with the

specification given in the contractual document which include the

description in method statement: land clearing and bowplank

preparation, earthworks, shallow foundation (footing), deep

foundation (bored pile, driven pile), wall work and cussion setting,

scaffolding and formwork, concrete structure reinforcement,

planning and execution of concrete work, roof structure, precast

concrete.


Practice : N/A

Bibliography : 1) Allen, E. dan Iano, J. 2008, Fundamental of Building

Construction:Materials and Methods, Wiley, New York

2) Spence, W. P., 2006, Construction Materials, Methods,

andTechniques, Delmar Cengage Learning

3) Nunnally, S. W., 2010, Construction Methods and

Management,Prentice Hall

4) Illingworth, J. R., 2000, Construction Methods and Planning,

SponPress

69

90. Course name : Courses Outside Department


Semester : VIII


Objectives : To provide students with the insight of the role of other disciplines

related to planning, design, construction, and utilization of public

infrastructure.

Learning Outcomes : Willingness and ability for continuous self development and

learning.

Syllabus : Adjusting to syllabus from courses taken.


Practice : N/A

Bibliography : Adjusting the bibliography of courses taken

MASTER IN CIVIL ENGINEERINGSYLLABI

i

Table of Contents

GEOTECHNICAL ENGINEERING

TKSA176102 Research Metodology (Credits: 3) ............................................................................................. 1

TKSA176103 Advanced Numerical Methods (Credits: 3) ............................................................................... 1

TKSA176104 Continuum Mechanics (Credits: 3) ............................................................................................ 1

TKSA176105 Advanced Soil Mechanics (Credits: 2)....................................................................................... 1

TKSA176201 Infrastructure Management (Credits: 3) ..................................................................................... 1

TKSA176202 Special Topics (Credits: 4) ......................................................................................................... 2

TKSA176203 Finite Element Method for Geotechnic (Credits: 2) ................................................................... 2

TKSA176204 Advanced Foundation Engineering (Credits: 2) ......................................................................... 2

TKSA176205 Soil Dynamic Analysis (Credits: 2) ........................................................................................... 2

TKSA176206 Applied Rock Mechanics and Tunneling (Credits: 2) ................................................................ 2

TKSA176207 Stability of Excavation (Credits: 2) ............................................................................................ 2

TKSA176208 Water Flow in Porous Media (Credits: 2) .................................................................................. 3

TKSA177101 Fieldworks (Credits: 2) .............................................................................................................. 3

TKSA177102 Geotechnic for Dams (Credits: 2) .............................................................................................. 3

TKSA177103 Rock Slope Stability (Credits: 2) ............................................................................................... 3

TKSA177104 Engineering Geology (Credits: 2) .............................................................................................. 3

TKSA177201 Thesis (Credits: 8) ...................................................................................................................... 3

STRUCTURAL ENGINEERING

TKSA176101 Engineering Statistics (Credits: 3).............................................................................................. 4




TKSA176108 Advanced Steel Structures (Credits: 2) ...................................................................................... 5

TKSA176109 Advanced Structural Dynamic Analysis (Credits: 2) ................................................................. 5

TKSA176201 Infrastructure Management (Credits: 3) ..................................................................................... 5

TKSA176202 Special Topics (Credits: 4) ......................................................................................................... 5

TKSA176213 Advanced Concrete Structures (Credits: 3) ................................................................................ 6

TKSA176214 Advanced Timber and Bamboo Structures (Credits: 2) ............................................................. 6

TKSA176215 Earthquake Resistance Structures (Credits: 3) ........................................................................... 6

TKSA176216 Plastic Analysis of Structures (Credits: 2) ................................................................................. 6

TKSA176217 Bridge Structural Analysis (Credits: 2) ...................................................................................... 7

ii

TKSA177101 Fieldworks (Credits: 2) .............................................................................................................. 7

TKSA177105 Advanced Mechanic of Materials (Credits: 2) ........................................................................... 7

TKSA177106 Advanced Finite Element Method (Credits: 2) .......................................................................... 7

TKSA177107 Plate and Shell Analysis (Credits: 2).......................................................................................... 7

TKSA177108 Advanced Concrete Technology (Credits: 2) ............................................................................. 7

TKSA177201 Thesis (Credits: 8) ...................................................................................................................... 8

WATER RESOURCES ENGINEERING

TKSA176101 Engineering Statistics (Credits: 3).............................................................................................. 8




TKSA176106 Advanced Hydrology (Credits: 2) .............................................................................................. 9

TKSA176107 Coastal Hydrodynamics (Credits: 2) .......................................................................................... 9

TKSA176201 Infrastructure Management (Credits: 3) ................................................................................... 10

TKSA176202 Special Topics (Credits: 4) ....................................................................................................... 10

TKSA176209 Water Resources Engineeing & Management (Credits: 2) ...................................................... 10

TKSA176210 River Hydrodynamics (Credits: 3) ........................................................................................... 10

TKSA176211 Computational Hydraulics (Credits: 2) .................................................................................... 10

TKSA176212 Irrigation and Drainage Engineering (Credits: 2) .................................................................... 11

TKSA177101 Fieldworks (Credits: 2) ............................................................................................................ 11

TKSA177201 Thesis (Credits: 8) .................................................................................................................... 11

INFRASTRUCTURE MANAGEMENT

TKSA176102 Research Metodology (Credits: 3) ........................................................................................... 12

TKSA176103 Advanced Numerical Methods (Credits: 3) ............................................................................. 12

TKSA176104 Continuum Mechanics (Credits: 3) .......................................................................................... 12

TKSA176114 Building Maintenance and Preservation (Credits: 2) ............................................................... 12

TKSA176115 Bridge Management System (Credits: 2) ................................................................................. 12



TKSA176227 Forensic Engineering (Credits: 3) ............................................................................................ 13

TKSA176228 Pavement Management System (Credits: 2) ............................................................................ 13

TKSA176229 Assesment and Rehabilitation of Hydraulic and Offshore Structures (Credits: 2) .................. 13

TKSA176230 Geotechnical Aspect for Infrastructure Management (Credits: 2) ........................................... 13

TKSA176231 Monitoring & Instrumentation (Credits: 2) .............................................................................. 13


iii


PROJECT CONSTRUCTION MANAGEMENT




TKSA176116 Construction Law Aspect (Credits: 3) ...................................................................................... 15

TKSA176117 Project Planning and Monitoring (Credits: 2) .......................................................................... 15



TKSA176232 Computer Application in Construction Management (Credits: 2) ........................................... 15

TKSA176233 Aset Management (Credits: 2) ................................................................................................. 15

TKSA176234 Public-Private Partnership (Credits: 3) .................................................................................... 16

TKSA176235 Construction Productivity (Credits: 2) ..................................................................................... 16

TKSA176236 Construction Method and Heavy Equipment Management (Credits: 2) .................................. 16



CONSTRUCTION MATERIALS TECHNOLOGY

TKSA176101 Engineering Statistics (Credits: 3)............................................................................................ 17




TKSA176112 Material Durability (Credits: 2)................................................................................................ 17

TKSA176113 Microstructure of Materials, Smart Materials, Composite Materials (Credits: 2) ................... 18



TKSA176222 Concrete Mix Design and Fabrication (Credits: 3) .................................................................. 18

TKSA176223 Bamboo and Wood Technology (Credits: 2) ........................................................................... 18

TKSA176225 Pavement Materials (Credits: 2) ............................................................................................... 19

TKSA176226 Non-Ordinary Concrete (Credits: 2) ........................................................................................ 19


TKSA177109 Metal and Alloy Technology (Credits: 2) ................................................................................ 19


iv

WATER AND WASTEWATER TREATMENT ENGINEERING

TKSA176101 Engineering Statistics (Credits: 3)............................................................................................ 20




TKSA17610 Sanitation System, Public and Environment Health (Credits: 2) ............................................... 20

TKSA17611 Water Conservation Technology (Credits: 2) ............................................................................ 20



TKSA176218 Domestic Waste Water Treatment Infrastructure (Credits: 2) ................................................. 21

TKSA176219 Water Supply System Infrastructure (Credits: 2) ..................................................................... 21

TKSA176220 Water Quality and Environmental Conservation Technology (Credits: 3) .............................. 21

TKSA176221 Infrastructure for Waste Management (Credits: 2) .................................................................. 22



1

Geotechnical Engineering

TKSA176101 Engineering Statistics (Credits: 3)

Study on probability, random variable and distribution, random variable transformation, momentum

and expectation, probability model (binomial-Poisson, exponential-gamma-beta-uniform-normal-

log, normal-Weibull, extreme value-chi, t and f-statistics, parameter estimation, hypothesis testing,

linier model analysis, reliability.

TKSA176102 Research Metodology (Credits: 3)

Various research types, process and research steps including problems formulation, literature review,

hypothesis, experimental design, research implementation, data analysis, summarizing and writing

research report. Scientific works writing for publications.

TKSA176103 Advanced Numerical Methods (Credits: 3)

Introductions on Numerical Methods, root equations, linear and non linear equation systems,

regression, interpolation, numerical integration, solving ordinary differential equations, solving

partial differential equation and computer programming.

TKSA176104 Continuum Mechanics (Credits: 3)

Introduction, matrix algebra, numerical interpolation and integration. Elasticity and Plasticity Theory

in Geotechnical Engineering, yield criteria, nonlinearity material dan geometry. Principle of Virtual

Work and Potential Energy Theory. Deplacement Formula in Finite Element Method. Two

Dimensional (2D) Element for Plane Strain, Axissymetry. Three Dimensional (3D) Element for Solid

Analysis. Application of Continuum Mechanics in Geotechnical Problems.

TKSA176105 Advanced Soil Mechanics (Credits: 2)

Study on soil types, grain size analysis, soil volume and mass and their correlations, Atterberg Limits,

soil classifications, effective stress-shear strength of saturated clay, Mohr-Coulomb Failure Theory,

shear strength of sand, saturated clay, unsaturated clay, pore pressure coefficient, stress line, stress

distributions, total consolidation, consolidation rate, immediate settlement, total settlement.

TKSA176201 Infrastructure Management (Credits: 3)

Slope movement and landslide, landslide types and handling, theory of slope stability and safety

factor, slope stability of circular slip surface, the role of vegetation on in slope stability, landslide

investigation and movement mechanism, advanced investigation landslide mitigation, SIDCOM

(Survey Investigation Design Construction Operation Maintenance) landslide mitigation, landslide

modeling, structural landslide mitigation in several cases. characteristics, assessment and

investigation of landslide, slope stability analysis using software, landslide mitigation planning based

on SNI (National Standard in Indonesia).

2

TKSA176202 Special Topics (Credits: 4)

Study on popular topics related to geotechnical engineering fields. The topics can be different every

academic year.

TKSA176203 Finite Element Method for Geotechnic (Credits: 2)

Finite element methods in geotechnics study about Introductions, matrix algebra, interpolation

function and numerical integration, Elasticity and Plasticity Theory for Geotechnic, yield criteria,

non-linearity material and geometry. Principle of virtual work and Potential Energy Theory,

Displacement Formulation in the finite element methods, 2-D Element for Plane Strain, Axissymetry,

3-D Element for solid analysis, Application in the various geotechnical problems.

TKSA176204 Advanced Foundation Engineering (Credits: 2)

Introductions, Types of Foundation, (1) superficial foundation, types of collapse, capacity theory,

Terzaghi Theory, side loading capacity, eccentric, Meyerhof Theory, Vesic and Hanzen, resistance

to the lifting force, decreased tolerance, (2) Pile foundation, Types of Pile Foundation, Pole Capacity

Means Statics and Dynamics, Pile Group, Pile Efficiency, Pile sideways, Lateral Load on the Pole,

Pole Deflections, Pole Test, (3) Caisson, (4) Lateral Earth Pressure, Coulomb and Rankine Theory,

the application of Rankine Theory on retaining walls and plaster ground construction.

TKSA176205 Soil Dynamic Analysis (Credits: 2)

Introduction, basic vibration and wave propagation in soil media (single and two degrees of freedom),

wave in elastics media, dynamics load characteristics for soil, vibration effects in foundation,

dynamics analysis in superficial and deep foundation, earthquake and soil vibration, lateral force on

retaining wall, influence of vibration on the retaining walls, liquefaction, stability of soil deposits

under the influence of earthquake.

TKSA176206 Applied Rock Mechanics and Tunneling (Credits: 2)

Introduction (tunnel definition, rock cycle and classification, sample of tunnel construction), index

properties of rock, rock mass classification systems, the stress-strain behaviour of rock material, shear

strength of intact rock and rock masses, The Hoek-Brown strength criterion and introduction to

RocLab software, tunnel planning and construction method, stress deformation analysis of a circular

tunnel, design and construction of tunnel support system, tunneling method using drilling and

blasting. Tunnel plan, design and construction based on Japan Society of Civil Engineers (JSCE)

standard, shield tunneling based on JSCE standard.

TKSA176207 Stability of Excavation (Credits: 2)

Lateral earth pressure, Rankine and Coulomb earth pressure theory, cohessive soil excavation, open

excavation, Taylor method, Bishop method, base stability of excavation, excavation methods,

retaining wall, anchor design and stability, application of shotcrete and anchor, diaphragm wall and

strut, circular diaphragm wall and sheet plie, modification slope stability method and tunnel.

3

TKSA176208 Water Flow in Porous Media (Credits: 2)

The definition of porous media and flow in porous media, basic theory and equation of water flow in

porous media, radial flow, water flow in unconfined aquifer, flownet, review on water flow in

saturated porous media, aquifer formation and its parameters, review on Darcy’s law, permeability

and its test, the relationship between suction and coefficient of permeability, analytical solution for

two dimensional flow, soil filters and its application, seepage control and dewatering, steady state

flow and transient flow in unsaturated soils.

TKSA177101 Fieldworks (Credits: 2)

Fieldworks experience allows students the opportunity to practice the application of theory and apply

the knowledge acquired through academic preparation, while learning the skills of an entry level

practitioner. Student can choose one of two choices: (1) internship in a project, company or institution

and (2) case study based on real project. A supervisor will be appointed for each student. In the end,

the students have to write and report their activity to the supervisor.

TKSA177102 Geotechnic for Dams (Credits: 2)

Introduction, roles of reservoirs and dams, foundation and subgrade, embankment dams materials and

criteria, rockfill and gravity dams, dams stability, design of dams from many aspects, embankment

dams and dams monitoring, hydrology-hydraulics-geotechnical analysis on dams planning, seepage

theory, continuity equation, Darcy Law, piping theory, calculation of seepage through an earth dam

(Dupuit’s solution, Schaffernak’s solution, Casagrande’s solution), presentation and discussion.

TKSA177103 Rock Slope Stability (Credits: 2)

Introductions, stone characterisation and discontinuitas, rock mass movement phenomenon, failure

criteria and rock shear strength, concept and analysis of rock slope stability, rocks water influence,

rock slope stabilitation, seismic slope stability, rock slope satbility with stereographic projection,

kinematics analysis on rock slope, application of kinematics analysis on rock excavation, application

of kinematics analysis on rock-bolt design, rock slope stabilization using slope geometry alteration,

rock slope stabilization using slope drainage and reinforcement.

TKSA177104 Engineering Geology (Credits: 2)

Introduction, the effect of topography on engineering constructions, the effect of stones on

engineering constructions, engineering properties of stones and rocks, the effect of geological

structures on engineering constructions, the effect of aquifers on engineering constructions, the

definition of geology engineering map, geotechnical maps uses, how to make geotechnical map, rock

mass classification, surface and subsurface investigation method, rockfall hazard methods, geology

for civil engineering, tsunami and earthquake, volcano: sub-surface stratification, application of

geological engineering on tunnel, dam, and bridge, analysis of soft soil exploration, study cases and

summary.

TKSA177201 Thesis (Credits: 8)

This course including: research proposal seminar, publication (at least national level), thesis seminar

and defense. Students will explore different ways of finding information, defining the scope of a

4

project and doing research, as well as different ways of communicating the results. The Master's thesis

course includes the stages of defining a topic and formulating a problem statement, selecting and

reviewing relevant literature, designing an empirical study as well as performing it, including data

collection and analysis, analysing the empirical data, make theoretical conclusions and finally writing

and rewriting a written report called a Master's thesis. The students works with two supervisors.

Structural Engineering TKSA176101 Engineering Statistics (Credits: 3)

Introduction of engineering statistics. Data definition, collection and processing. Measures of central

tendency and dispersion. Bivariate data, coefficient of correlation, regression and interpolation.

Inferential statistics. Application and case study. Probability, Probabilistic Hazard, Analysis of

Probability. Space sample and event. Discrete and continues variable. Distribution, random

distribution, binomial distribution, uniform distribution, exponential distribution. Confidence level,

distribution random variable. Fundamental reliability, example of reliability analysis calculation for

structural safety, reliability analysis, linear function, non-linear fnction. Design of experiment and

other statictics application, analysis of variance.


The essence of science and knowledge. Experimental research. Hypothesis: null hypothesis, forming

a hypothesis. Writing a research proposal. Writing master thesis. Research proposal presentation.

Research approaches in civil engineering field (analytical, numerical, eksperimental, practical

experiences). Model and prototype. Geometric scale, material, elastic and strength model. Structural

model theory and experimental method (pi-buckingham theorem, similitude requirement). Examples

of models (the true model, adequete model, distorted model). Equipment and instruments in structure

laboratory. Visit to structure laboratory.


Introduction (error theory, Taylor series, numerical deference), application of numerical methods in

civil engineering field, equation roots (half-interval method, linear interpolation method, Newton

Raphson method, Secant method, iteration method), Numeric integration (Trapezoid Method,

Trapezoidal Method with multiple parts, Simpson method, Integral with unequal part length and

quadrature method), Regression analysis (least squares method for linear curves, non linear curve

linearization and polynomial regression), interpolation (linear interpolation, squared interpolation,

general form of polynomial interpolation, Lagrange polynomial interpolation), ordinary differential

equation solution (one step method, Euler method, Euler method error, Taylor series with higher

order, Heun method, modified Euler method, Runge Kutta method), solution of partial differential

equations (by using finite difference methods, stability, consistency), Nonlinear Simultaneous

Equations (Secant stiffness method, modified Newton-Raphson method), Eigenvalue problem

solution (inverse iteration method, subspace iteration method), numerical solution of dynamic

problem Multi Degree of Freedom (MDOF) systems.

5


Real structure problem (plasticity, viscoelastic soil, fluid, 3D, static vs dynamic loading, isotropic vs

unisotropic, linear vs non-linear material behavior, linear vs non-linear geometry, short vs long term

behavior, soil-structure interaction, fluid-structure interaction, combination fluid-soil-structure

interaction, combined gravity and thermal loading). Fundamental of mathematics (notation, matrix,

vectors, tensors and the application in civil engineering field). Vectors (vectors drawing, vectors

properties, dot products, and cross products) and transformation laws. Kinematics: particle motion,

deformation and strain, homogenious motion, general motion, rigid body motion, pronciple stretch,

velocity gradient tensor, strain tensor, linearization, mass and mass conservation, body force, surface

fraction, momentum and momentum conservation, tension tensor. Principal stress transformation.

Isotropic homogen. Failure theory. Shear-stress distribution of beam. Beam deflection. Plane stress

and plane strain.

TKSA176108 Advanced Steel Structures (Credits: 2)

Introduction. Basic equation for beam-column. Exact and approximate solution method. Theory of

material failure criteria. Deflection method for inelastic beam-column analysis. Bending moment

method and its applications. Applications of steel structures: skeleton bridge, steel composite bridge,

steel box bridge, cable stayed bridge, suspension bridge. Connection span. Shape factor. Bracing:

Concentrically Braced Frame (CBF) and Eccentrically Braced Frame (EBF).

TKSA176109 Advanced Structural Dynamic Analysis (Credits: 2)

Introduction of structural dynamic analysis, Single Degree of Freedom (SDOF): equation of motion

and its solution, Multi Degree of Freedom (MDOF): equation of motion and its solution. Spring-mass

system as a solution of dynamic system, numerical solution based on finite element method for

structure with dynamic load. Eigenvalue problem solver for truss and frame. Problems and solutions.

Natural (undamped) frequency and damped frequency. Free vibration, damped vibration and

resonance. Signals, Fast Fourier Tansform (FFT) and Discrete Fourier Transform (DFT). Range band

frequency and how to reduce noise.


Infrastructures, samples, management method and problems. Life cycle analysis of building and

infrastructure. Repair cost estimation and control. Infrastructure management framework. Facility

management. Management in Operation. Damage Investigation. The roles and skills of Infrastructure

Manager. Decision making in Infrastructure Management (aims and strategy). Decision making with

sustainability criteria (alternative analysis, finance strategy). Sustainable organization, design and

operation. Emergency readiness. Safety management of operation and maintenance. Standard

Operating Procedure (SOP)


Study on popular topics related to structure engineering fields. The topics can be different every

academic year.

6

TKSA176213 Advanced Concrete Structures (Credits: 3)

Rectangular profile beam, T-profile beam, bending shear, shear torsion; rectangular and circular

profile column with uniaxial and biaxial moments; Structure ductility, beam-column joint details for

full Ductility design. Shear wall design and reinforcement details (bending and shear); coupling

beams (bending shear, diagonal splitting shear, and support damage); Concrete cracking, long-term

deflection, moment redistribution; Reinforced concrete plates: Strip Method, yield line theory, flat

plate; Reinforced Concrete Design using Strut and Tie models (Basic, terms and requirement in SNI,

and applications on "disturb region": Short consoles, high beams, dapped end beam, hollow beams,

pile cap).

TKSA176214 Advanced Timber and Bamboo Structures (Credits: 2)

Introduction to timber and bamboo as environment friendly materials. Wood and bamboo anatomy.

Wood and bamboo physical properties. Wood and bamboo mechanical properties. Physical and

mechanical properties test. Wood and bamboo grading system. Deterioration of wood and bamboo.

Wood and bamboo preservation. Adhesive technology of wood and bamboo. Engineered wood and

bamboo products. The principle of designing wood structures and joints. The in-plane racking

resisance of timber walls under horizontal and vertical loading. Journal review: latest researches on

wood and bamboo.

TKSA176215 Earthquake Resistance Structures (Credits: 3)

Earthquake phenomenon and its effects on constructions, earthquake hypocenter and scale (how to

approximate epicenter and hypocenter, earthquake scale at hypocenter, local scale intencity, empirical

relationship between earthquake scale and return period, earthquake risk), seismic hazards (seismic

motion records, spectrum response, seismic hazards maps, seismic design category according to the

function and type of construction), equivalent lateral force analysis and response spectrum analysis,

seismic response history procedure, performance based seismic design, capacity-spectrum curve,

analysis of building with structural control (base isolator and damper). Fundamental concept of

seismic design (ductility, dynamic response. Effect of building shape (building motion, irregularities,

philosophy od spectrum response). Structural computer and modeling. Concrete structure design

requirement. Steel structure design requirement. Masonry and wood structure design requirement.

Non structural component design requirement.

TKSA176216 Plastic Analysis of Structures (Credits: 2)

Introduction. The differences between elastic and plastic analysis. Moment-curvature analysis of steel

section, reinforced concrete section and composite section. Software application for calculation of

section’s momen-curvature. Analysis of load and inelastic deflection on a simple beam. Structure’s

plastic analysis using software. Ultimate load of continuous beam and steel frame. Limit analysis and

design of continuous beam and steel frame. Factors affecting plastic moment. Deflection of beam and

steel frame. Application of yield line theory on reinforced concrete slabs. Application of Hillerborg

strip method on reinforced concrete slabs.

7

TKSA176217 Bridge Structural Analysis (Credits: 2)

Study on bridge classifications, landscape and form the structure for concrete and steel bridge.

Structures load on the under and top of the bridge and the combinations. Comprehension method,

procedures analysis and earthquake resistant bridge structure design, top structures of the bridge

design, vehicle deck plate, lengthwise and crosswise thunder, laying down, accessories and

framework stems of bridge. Under structures of the bridge design: abutment, pillar, foundation and

safety. Study on length-landscape bridge design (exceptional bridge), such as stayed cable and bridges

suspension and also bridge maintenance.







TKSA177105 Advanced Mechanic of Materials (Credits: 2)

Understanding of civil engineering structural material based on deformation mechanisms, such as

elastic, plastics, linear, non linear behavior, fracture and fatigue. Theory applications on structural

elements from steel, aluminium, concrete/ reinforced concrete, timber and composite.

TKSA177106 Advanced Finite Element Method (Credits: 2)

Finite element method basic concept, 3-D elasticity basic theory, virtual work principle and potential

energy.1-D element for truss and frame analysis, 2-D element for field stress and strain, curved plate

and axis ymetry,3-D element for solid and shell analysis. Isoperimetric element and numerical

integration. Dynamic analysis, structural stability and non linear structural analysis. Demo: SAP-

2000 Program, ATENA, SIGMA/W and PLAXIS Program.

TKSA177107 Plate and Shell Analysis (Credits: 2)

Study on Curved Plate Theory, differential equations, condition boundary for thin plate, thick plate,

orthotropic plate, plate on the elastic foundation. Solution of analytics method (Navier, Levy, Strip

Method) and numerical method (Finite Difference and Finite Element Method), Plate theory with

membrane and lateral force combinations, application on the civil engineering structures.

TKSA177108 Advanced Concrete Technology (Credits: 2)

Concrete material, concrete mix design and concreting. Characteristics of fresh concrete such as

consistency, workability, repeated compression, overnight concrete, hydration heat, plastic crack.

Characteristics of concrete such as compressive strength, flexural strength, tensile strength and wear

resistance, water impermeability, durability in aggressive environments, temperature endurance,

shrinkage and creep. Special concrete: lightweight concrete, non-sand concrete, heavy concrete, mass

concrete, high performance concrete, fiber concrete, polymer concrete, concrete with artificial

aggregate. Concrete with special handling such as grouting, underwater concrete, self compacting

concrete, roller compacting concrete, preplaced concrete, prepacked concrete, shotcrete, ferrocement,

8

concrete with large aggregate. Concrete mix design using computer programs, concrete management

and quality control (Demo).









Water Resources Engineering


Introduction on statistics and probability (statistics definition and application, data, sample and

population, data and sampling errors, data organization with table and graph), probability (definition,

sample space, sample elements, events, conditional probability, total probability, Bayes theorem,

permutation and combination). Random variable (discrete and continuous random variable, random

variables and probability distributions, random variable properties, statistics size). Discrete and

continuous probability distribution (hypergeometric, binomial, Poison, uniform, exponential, normal,

log-normal, etc). Normal distribution, PDF and CDF curves, andconfidence level. Hypothesis testing

and frequency analysis. Regression and interpolation. Interpretation of correlation coefficient.

Univariate and multivariate data generation. Problem sample: calculation of regression. Introduction

to mass curve. Application of statistics in the real case.


Research methodology. The principle of research and problem formulation. Research topics. Data

collection, research stages and research cycle. Research requirements (researchers, topics, data, and

proposal). Research ideas: inovation and invention. Literature maps (science concept and technology

implementation). Narrowing topics: choosing research focus based on problems.

Hydraulic modeling. Introduction (the roles of hydraulic model, the types of hydraulics model,

principle in modeling, congruence). Dimensional analysis (Rayleigh, Buckingham, Basic Echilon

matrix, stepwise, Langhaar methods). Instrumentation (data collection instruments, data aquisition,

control instrument, samples of instruments). Reproduction of hydraulic phenomenon (Scale Law,

Scale condition, undistorted and distorted model, wave modeling, morphological processes), Fixed

bed hydraulic model design (estuary, sea water intrution, wave refraction and difraction, settling

basin, breakwater). Moving bed hydraulic model design (morphological processes, sediment

transport in river and coast, scouring, tilting model). Prosedure of hydraulic model planning. Samples

of hydraulic model and discussion.

9


Introduction, errors, absolute and relative errors, root equations (half interval method, linear

interpolation method, Newton-Raphson method, secant method, iteration method), Taylor series,

linear equation system, regression, interpolation, numerical integration (trapezoidal, Simpson, Gauss

Quadrature), Ordinary differential equations (Euler, Heun, Euler modification, 2nd, 3rd and 4th Order

Runge-Kutta), partial differential equations: solution of parabolic equations (differentiation to

scheme of explicit, implicit, and Crank-Nicholson), solution of elliptical and hyperbolic equation,

solution of mass transport equation.


Flow classifications (steady, unsteady, viscid, inviscid, incompressible, compressible, rotational and

irrational). Streamlines. Example of streamlines calculation. Kinematics (Particle Movement using

Lagrange and Euler Method), Continuity Equation (integral and differential type). flow function,

velocity potential, drawing streamlines. Vortexs: free and forced vortex flow. Superposition flow

(sink, source, doublet, circulation, samples of flow, Bernoulli equation on airplane wings).

Fundamental concepts of hydrodynamics (constant volume system, constant mass system, mass

continuity, volume continuity). Application of hydrodynamic equation: Navier-Stokes Equation for

Lamiar flow). Reynolds Equation (flows in cylindrical pipe, turbulent flow equation. Turbulent and

laminar boundary layer equation. Hydrodynamic force (shear force, lift force, drag force).

TKSA176106 Advanced Hydrology (Credits: 2)

Introduction (the role of hydrology, responsibility of a hydrologist), watershed system, basic concepts

of hydrology (water cycle: rainfall, infiltration, interception, evapotranspiration, run-off), water

balance, rainfall (evaluation of rainfall stations network using Kagan method, rainfall data test and

correction), Hydrometry (mid section area method, mean sectional area method, rating curves),

Hydrograph and unit hydrograph (synthetic and observed). Rainfall-runoff transformation, rainfall

distrubution, observed unit hydrograph (polynomial and collins method, representative unit

hydrograph), synthetic unit hydrograph (Nakayasu, Gama I, SCS, Limantara, ITB-I and II). Loss

Method (phi-index, SCS, Green-Ampt infiltration), Routing (Channel routing: Muskingum and

Muskingum-Cunge, reservoir routing), frequency analysis (frequency analysis of rainfall and

discharge data, selecting probability distribution, Chi-square test, L-moment method).

TKSA176107 Coastal Hydrodynamics (Credits: 2)

Wave mechanics (introduction of long wave Airy theory, Navier Stokes equation, momentum

equation, linear long wave equation, wave characteristics method). Long wave reflection and

transmission (mixing wave, long wave along channel, Bessel function). The effect of friction on wave

(long wave with bottom friction, wave through mangrove forest). Geostropic effects on long wave.

Storm surge. Problems and solutions. Coast and estuary tide analysis (equilibrium theory, tidal

components, Harmonic analysis). Tides: causes, processes and effects. Mixing theory (difussion,

longitudinal shear dispersion), tidal motion in estuaria (mixing with tides, tidal prism method). Flows

through estuaria (fress water/flood and tides interaction, stratification in estuary). Sediment dynamics

im eastuary and coastal area.

10


Introduction (Hydraulic Infrastructure, Water Cycle, Water Use and Distribution, Infrastructure

Management System). Sustainable infrastructure. Operation and Maintenance (Purpose of

Maintencance, Principle in Maintenance, Problems in Maintenance, Type of Maintenance). Dam

failure (Maintenance of Dam, Embankment Dams Failure, Concrete Dam Failure, Failure

Prevention). Performance Indicators of Hydraulic Structures. Water infrastructure and social

paradigm. Recognizing the Infrastructure Design (Functional Design, Current situation of Object,

Output DED–TOR). Hydraulic Infrastructures, Reservoir Routing, Reservoir Operation.


Study on popular topics related to water resources engineering fields. The topics can be different

every academic year.

TKSA176209 Water Resources Engineeing & Management (Credits: 2)

Water Resources, Water for Life, Water Use. Water Resource Management (multipurpose water

management, objective of water management, how to manage. WMS system function). Integrated

Water Resources Management/IWRM (water issues, authorities of water, water governance).

Element pattern, system interaction of IWRM. Water sources and availability. Balancing suppl and

demand in reservoir. Problem of water: water scarcity. Water resources system (definition, analysis,

components, performance). Reservoir water balance. Reservoir simulation (single purpose reservoir

simulation, multi purpose reservoir simulation, global and local water balance, watershed water

balance, water balance simulation in irrigation reservoir). Optimetion in water resources management

(introduction, examples, optimation using Multi Objectives Linear Program).

TKSA176210 River Hydrodynamics (Credits: 3)

River dynamics, secondary flow by Rozovki and river morphology, Erosion and Sedimentation

(sediment sources, erosion and sedimentation processes, sediment transport equation, estuary

dynamics, case study: Kali Opak). Flood (description, flash flood, debris flood), Monitoring of River

Hydraulic and Hydrology. River Hydrometry (discharge, sediment transport). Degradation and

Agradation of River Bed (problems, Saint Venanf-Exner Formulation, analytical study). Flow around

water structures and local scouring (weirs, pillars). River bed and river side protection from scouring.

Pollutant transport (diffusion and convection equation, analytical solution for 1-D diffusion

equation). Flood mitigation (Flood basic concept and mitigation strategies, eco-hydraulics aspect on

flood mitigation, flood mitigation with polder system, flood mitigation with drainage system, flood

control structures: retention pond, dykes, etc, hyperconcentration flow and debris flow, sediment

control structures).

TKSA176211 Computational Hydraulics (Credits: 2)

Introduction to Mathematical Models. Characteristics of Partial Differential Equation (hyperbolic

equation, parabolic equation, eliptic equation). Numerical solution with finite difference methods

(Crank Nicholson). Unsteady flow equation (Saint Venant Equation). Numerical Solution (Double

sweep method). Manual of HEC-RAS SWMM (stability, accuracy and sensitivity). Flow

measurement (velocity, water table, etc) in laboratory flume. Simulation water flow in flume using

11

HEC-RAS. Bridge and culvert. Simulation of river water flow with bridge or culvert structure using

HEC-RAS. Inline Structure Simulation using HEC-RAS. Lateral Structure Simulation using HEC-

RAS

TKSA176212 Irrigation and Drainage Engineering (Credits: 2)

Water resources (hystory of water resources management for food security). Philosophy of Irrigation

(definition, hydraulic structures, irrigation structures, paddy field, irrigation water function, irrigation

water sources, soil-plant-water relationship). Pre-construction phase (Survey, Investigation, Design

and Land Acquisition. Requirements for planning new irrigation network. Classification of Irrigation.

History of Irrigation in Indonesia). Irrigation Management (Water resources policy in Indonesia,

Culture and Tradition, Dynamics and Complexity in Irrigation Water Distribution. System Approach

and Irrigation Management Model). Sluice gate management (sluice gate operation: opening and

closing). Quantification analysis (objective function, items and categories, category weight

estimation and normalization, correlation coefficient). Irrigation water availability and demand

(hydrology: low-flow analysis, water demand, water balance, cropping pattern). Drainage module

(design criteria, data collection, hydrology and hydraulics analysis). Irrigation water management

(operation, maintenance, rehabilitation, safety, priority analysis). Optimation (Multi Attribute

Decision Making: SAW, WP, TOPSIS). Book Review (Surface Irrigation Chapter 11: Fundamentals

of Surface Irrigation Hydraulics)















Infrastructure Management


Study on the mean value, standard deviation, coefficient of variation, histogram, Gauss curve,

probability distribution, probability graph paper, characteristic values, data comparison, Chi-square

12

Test, Least-square, Correlation Coefficient, Student's t-distribution, curve fitting, Error analysis.

Solving problems through available statistical programs, such as:

- Statistical applications on structural engineering

- Standardization of experimental object design

- The evaluation of concrete quality

- Trendline/ derivation of empirical formulas for mechanical materials

- The application of statistics on the calculation of seismic loads, the equivalent of vehicle loads,

and the equivalent of noise load.


The course presents research processes (finding, formulating and solving problems through literature

studies, hypotheses, and proved by laboratory experiment or theoretical/numerical analysis, data

analysis, discussion and conclusions). Presentation methods (written/paper, presentation through

multimedia programs).


The course presents optimization methods for various problems of applied cases including:

introduction to linear programming, simplex method, transportation modelling with various

variations, deterministic and stochastic dynamic programming and inventory models, queing systems

and several other methods in the scope of operation research.












and plane strain.

TKSA176114 Building Maintenance and Preservation (Credits: 2)

The lecture explain the ways to execute building maintenance programs, organizations, technical

maintenance of building components, budgeting, maintenance schedules etc. The lecture will also

explain how maintenance programs can be run effectively and should not only focus on technical

issues or delegating maintenance work to contractors (outsourcing).

TKSA176115 Bridge Management System (Credits: 2)

The course provides introduction to materials, forms, types and functions of bridge parts, airports and

roads related to feasibility requirements during operations/services through as-built drawing or field

13

survey. Technical criteria of bridge (related regulations). Soil investigation for the foundation of

abutment and pier. Types and forms of support and connecting systems between bridges (joint/hinge,

roller/rocker, rubber bearings). Causes of damage and bridge maintenance/repairment procedures .


The course provides knowledge related to infrastructure management frameworks, planning, needs

assessment, and performance indicators, in service monitoring and evaluation, life-cycle costs and

benefit analysis.


Study on popular topics related to infrastructure management fields. The topics can be different every

academic year.

TKSA176227 Forensic Engineering (Credits: 3)

Study on the scope of work, procedures for collecting data types, processing data and presenting

results. Understanding of cases at the stages of survey, design, execution and operation of buildings.

Explaining the technical problems of the design survey, construction-operation. Planning for repair,

supervision and claim handling costs.

TKSA176228 Pavement Management System (Credits: 2)

Flexible and rigid pavement types together with materials used, aggregate and concrete. Material

selection technology, mixing technology and its relation to the design of pavement thickness.

Execution methods in the field. Types of damage and repair methods for flexible and rigid pavement.

TKSA176229 Assesment and Rehabilitation of Hydraulic and Offshore Structures (Credits: 2)

Introduction of systems and management of clean water networks, controlling building, discharge,

clean water/drinking water pressure. Introduction of the shape and function of sewage and waterways

(septic tank buildings, discharging wells, alignment, size, estimated deposits) and management

methods. General introduction to hydrology, catchment area and the relation to systems and

management of drainage networks. Management of functions and maintenance of coastal building,

irrigation channel and irrigation building, dam, and weir.

TKSA176230 Geotechnical Aspect for Infrastructure Management (Credits: 2)

The lecture provides introduction to the principles of soil mechanics, foundation engineering, soil

investigation to evaluate the stability of building structures. Foundation structure improvement

(underpinning), foundation improvement, compression, mechanical and chemical repairment.

Improvement of slope stability, dam, building foundation, and road.

TKSA176231 Monitoring & Instrumentation (Credits: 2)

Study on the procedures and tools used to evaluate the feasibility requirements of residential

buildings, hotel, hospital and public buildings for various related aspects. Study on the same scope

for road, railway and bridge. Monitoring tools and the ways of evaluating buildings, airport and sea

facilities.

14















Project Construction Management













The course presents research processes (Discovering, formulating and solving problems through

literature studies, hypotheses, and proof by laboratory experiment or theoretical/numerical analysis,

data analysis, discussion and conclusions). Presentation methods (written/paper, presentation through




introduction of linear programming, simplex method, transportation modelling with various



15












and plane strain.

TKSA176116 Construction Law Aspect (Credits: 3)

The principles of construction contract, contract document, competitive bidding, construction

processes, guarantees in the contract for construction work execution, legal aspects related to rights

and obligation of each construction work stakeholder together with relations to job change,

scheduling and delay, different condition of project, payment and guarantee, nominated sub-

contractor and supplier, as well as the construction law in international contract.

TKSA176117 Project Planning and Monitoring (Credits: 2)

Project breakdown, arrow diagrams, precedence diagrams, determination of activity duration, project

scheduling calculation, communication of project schedule, project control, time-cost adjustment,

resource leveling, LoB, program evaluation and review technique (PERT), overlapping workflows.


The course provides knowledge related to infrastructure management frameworks, planning, needs

assessment, and performance indicators, in service monitoring and evaluation, life-cycle costs and

benefit analysis.


Study on popular topics related to infrastructure management fields. The topics can be different every

academic year.

TKSA176232 Computer Application in Construction Management (Credits: 2)

Program algorithm, database, php, spreadsheet application, procurement and auction application on

construction contract: stages and processes, facility and infrastructure, transparency, document

auction, internet security system, software application of project management and construction.

TKSA176233 Aset Management (Credits: 2)

Infrastructure management framework, planning, needs assessment, and performance indicator, in-

service monitoring and evaluation, life-cycle cost and benefit analysis.

16

TKSA176234 Public-Private Partnership (Credits: 3)

Providing students the knowledge of how to analyze economic value of a civil engineering project,

both new and existing projects. Definition of PPP, its development, alternative infrastructure

development (transportation, water supply building, communication networks, etc.), objective,

excellence, principles of execution, contract form, government collaboration process with private

sector, its problems, case study, interest concept, financial mathematics, composition and cost

comparison, risk analysis, feasibility analysis (BCR, IRR, NPV), financial mathematics (Present

Value and Single Future Value, Uniform Present Value and , decreasing and increasing gradient

value, Sinking Fund Factor, Capital Recovery Factor), transport economics, construction, hydro, Cost

composition and Cost Comparison, concepts of Probability and Risk, feasibility study.

TKSA176235 Construction Productivity (Credits: 2)

Study on problems related to productivity in construction work including the definition of

productivity, system, process, management, job assignment analysis, transcription method and

productivity measurement method and other matters related to human behavior as factor affecting

construction productivity.

TKSA176236 Construction Method and Heavy Equipment Management (Credits: 2)

Construction methods of building, construction method of steel truss bridge, construction method of

suspension bridge, land excavation, types of heavy equipment used in construction work, estimation

of tool productivity, estimation of tool cost, and work time analysis.















17

Construction Materials Technology













The course presents research processes (Discovering, formulating and solving problems through

literature studies, hypotheses, and proof by laboratory experiment or theoretical/numerical analysis,

data analysis, discussion and conclusions). Presentation methods (written/paper, presentation through




introduction of linear programming, simplex method, transportation modelling with various














and plane strain.

TKSA176112 Material Durability (Credits: 2)

Recognition of the technical requirements of building materials (SNI and other applicable standards)

including: the properties of hard concrete (measurement of quality, its properties to natural

temperature, compressive strength, tensile strength, shear strength, air/water porosity). The properties

18

of concrete materials against air (CO2), SO3-, CaCl, NaCl, and fire. The properties of steel material

against CaCl, NaCl, heat/fire, and other corrosive materials. The properties of wood/bamboo material

against insects (termites, teters). The properties of asphalt material (against deterioration, heat and

rain). The properties of other materials such as: aluminum, bronze, brass, glass, wall paint and wood

paint, glaze, politur, melamine, flexiglas, etc. against corrosion of chemicals, sea water, acid or wind.

Economic aspects of building effects with high durability materials.

TKSA176113 Microstructure of Materials, Smart Materials, Composite Materials (Credits: 2)

The course presents the development of materials based on time period : stone age, bronze age, iron

age, composite material age, synthetic material age, and smart material age. Composite materials:

metal alloy, fiber reinforced concrete plastic, fiber reinforced concrete, rubber based materials. The

evolution of material utilization: mechanical properties, functional properties, multifunctional

properties, smart materials (utilization of mechanical, multifunctional, and information functions).

Smart materials: types, concepts of using sensor, actuator, and combination of

sensor+actuator+controller, and utilization as smart structures. Several examples of smart structure

experiments utilizing smart materials.


Infrastructures, samples, management method and problems. Life cycle analysis of building and

infrastructure. Repair cost estimation and control. Infrastructure management framework. Facility

management. Management in Operation. Damage Investigation. The roles and skills of Infrastructure

Manager. Decision making in Infrastructure Management (aims and strategy). Decision making with

sustainability criteria (alternative analysis, finance strategy). Sustainable organization, design and

operation. Emergency readiness. Safety management of operation and maintenance. Standard

Operating Procedure (SOP)


Study on popular topics related to material technology fields. The topics can be different every

academic year.

TKSA176222 Concrete Mix Design and Fabrication (Credits: 3)

The course presents the determination of the comparison of concrete mixture, both regular and special

concrete using various methods such as ACI Method, British Method, SNI Method and other methods

that have been introduced. Special concrete including concrete for aggressive environment,

lightweight concrete, heavy concrete, mass concrete, non-sand concrete, concrete with fly ash, fiber

concrete, high quality concrete. Concrete mix design using computer programs. Methods for mixing,

transporting, casting and treating concrete. (Demo/practicum).

TKSA176223 Bamboo and Wood Technology (Credits: 2)

Knowledge of the physical and mechanical properties of wood, bamboo and engineered wood

products; The principle of designing wooden structures; Design of tensile element, flexural element

and others receiving loads combination; Wood joint design; Lateral load restraint system;

Preservation of bamboo and wood, drying technology of wood and bamboo, treatment of fireproof

19

wood, technology of wood gluing and application to civil buildings, bamboo joint, laminated bamboo,

the principle of designing bamboo joint, application of bamboo as the component of frame structure,

application of bamboo as composite structure material with concrete.

TKSA176225 Pavement Materials (Credits: 2)

The couse presents flexible and rigid pavement types together with materials used, aggregate and

concrete. Material selection technology, mixing technology and its relation to the design of pavement

thickness. Execution methods in the field. Types of damage and repair methods for flexible and rigid

pavement .

TKSA176226 Non-Ordinary Concrete (Credits: 2)

This course discusses the physical, mechanical and chemical properties of special concrete, which

includes strong types, compressive strength, elastic modulus, plasticity, strong shock, shrinkage,

creeping, air tightness, sulfate reinforcement, and so on. Special concrete contains: lightweight

concrete, high compressive strength concrete, mass concrete, airtight concrete, sulfate resistant

concrete, fiber concrete, polymer impregnated concrete, latex modified concrete, and so on.

Discussion of the results of the latest research. Introduction to quality standards and methods for

testing concrete, testing labs.







TKSA177109 Metal and Alloy Technology (Credits: 2)

The course presents various types of metals and alloys, high strength low alloy steels, dual phase

steels, stainless steels, cast irons, cast and wrought alluminium alloys, titanium alloys, magnesium

alloys, alloys produced by non conventional methods (rapidly solidified alloys). Characteristics and

mechanism of solid state transformation phase. Kinetics. Technology and processes of fabrication,

casting, roling and thermomechanical process. Various demonstrations about metal and alloy

technology and fabrication.









20

Water and Wastewater Treatment Engineering


Introduction. Statistics parameters. Frequency table and graph. Binomial Distribution. Normal

Distribution. Level of Confidence. Hypothesis Testing. Linear Regressions. Polinomial Regression.

Multivariable regression. Introduction to mass curve. Application of statistics in the real case.


Introduction. Research requirements. The types of research proposals. Writing research proposal.

Research Procedure. Writing Master Thesis Report. Scientific Research. Engineering Research.

Problems Formulation. Discussions.


Introduction (Taylor Series, numerical differentiation). Root equations (half interval method, linear

interpolation method, Newton-Raphson method, secant method, iteration method). Linear Equation

System (Gauss Elimination, Gauss-Jordan Method, Double sweep method, iteration method). Linear

programming. Graphic Methods. Optimation using solver. Diffusion Equation. Application of Double

Sweep method for diffusion equation.


Introduction. Fluid dynamics equation. Navier-Stokes Equation. Applications of Navier-Stokes

Equation. Boundary Layer. Friction Force. Drag Force. Hydraulic Particle in Water. Diffusion

Equation. Convection Equation (vertical, transversal and longitudinal). Particle hydraulics in a filter.

Flow types in a reactor and mass balance.

TKSA17610 Sanitation System, Public and Environment Health (Credits: 2)

Sanitation and hygiene (definition according to WHO, global sanitation problems, water balance and

public health). Water related diseases (water borne diseases, water based diseases water washed

diseases, insect vector diseases, prevention methods, selecting water source). Pollutant and pollutant

source (water sources and quality, pollution causes and sources, domestic waste, industrial waste,

agricultural waste, preventing pollution). Environment toxicology, eco-toxicology, environment

pollution. Water treatment procedure and septic tank. Sanitation system and waste management.

Cubluk, septic tank, first in first out, anaerob and aerob system. Onsite system. Toxic and Hazardous

Waste. Blackwater Treatment Plant. Air Pollution (classification, sources, impacts, pollutant types,

pollutant management, treatment of gases from chimney)

TKSA17611 Water Conservation Technology (Credits: 2)

Population growth, urbanization, and water resources problem. Rainwater management (hydrological

cycle, retention pond, biopores, recharge wells, detention pond, green roof). Case Studies: rainwater

management. Students presentation: rainwater harvesting system, wetlands, retention ponds,

detention ponds, rain garden, green roof). Impact of Climate Change on Agricultural Sector.

Comprehensive water conservation. The concepts of water conservation. Land requirement for water

conservation.

21


Introduction (Infrastructure definition, Infrastructure components, the functions of infrastructure).

Management (Management Definition, Scope of Management). Risk management. Basic of

Infrastructure Management. Bottom-Up Concept. Infrastructure and layout. Development processes

and models. Water supply system planning. Feasibility Study. Discussions. Water supply system:

Operation and Maintenance.


Study on popular topics related to water and waste water treatment fields. The topics can be different

every academic year.

TKSA176218 Domestic Waste Water Treatment Infrastructure (Credits: 2)

Introduction (Waste water characteristics, wastewater discharge and quality prediction, pollutants in

domestic waste water, waste water management paradigm). Types of waste water treatment (waste

water management system, basic considerations), Preliminary treatment (grit chamber, grease trap,

equalization pond, design criteria, operation, maintenance, monitoring and evaluation). Primary

treatment (sedimentation, imhoff tank, design criteria, operation, maintenance, monitoring and

evaluation). Secondary treatment (aerobic and anaerobic: processes and reactors, anaerobic baffle

tank reactor, Facultative Ponds, Anaerobic Ponds, aeration pond, aerobic filter/contact bed filter:

design criteria, operation, maintenance, monitoring and evaluation). Secondary treatment (maturation

pond: design criteria, operation, maintenance, monitoring and evaluation). Nitrification and

denitrification: design criteria, operation, maintenance, monitoring and evaluation. Phytoremediation:

design criteria, operation, maintenance, monitoring and evaluation. Sludge treatment (sludge

characteristics, dewatering, biogass tank, sludge composting and recycling: design criteria, operation,

maintenance, monitoring and evaluation). Waste water treatment plant syatem (planning procedure,

configuration, flow diagram, flow sheet, removal efficiency, mass balance, technical drawing, case

study)

TKSA176219 Water Supply System Infrastructure (Credits: 2)

Introduction (water availability problems: quantity and quality, water supply problems: infrastructure,

human resources, budget, organization. Case study). Water supply system (water source, reliability

study: quantity and quality aspect). Intake infrastructure (from spring, groundwater, river,

reservoir/lake, gallery wells, rain water harvesting). Design criteria of water intake structure. Pipe

networks (water flow in pipe, loop network, reservoir and tank, valves, pumps, pumps performance

curve, pumps efficiency, serial and parallel pumps, design of pumps). Water supply network

simulation using Waternet. Water treatment infrastructure (sedimentation system, coagulation and

flocculation, filtration, neutralization, aeration, and dissinfention).

TKSA176220 Water Quality and Environmental Conservation Technology (Credits: 3)

Introduction (paradigm, problems, pollutant loads and environmental carrying capacity). Limnology.

Water quality monitoring. Biomonitoring and laboratory/field works. Water quality indeks and

environment information system. Water quality status determination method and water quality

conservation targets. Calculating water quality indeks. Utilizing computer software (HEC-RAS) to

22

simulate environmental carrying capacity and water quality modeling. Climate and water quality.

Climate change and its impacts on water resources management and water quality. Waste water

treatment system. Engineering and social efforts for water quality and environment concervation. The

role of community in water quality and environment conservation.

TKSA176221 Infrastructure for Waste Management (Credits: 2)

Solid waste management. National Policy on Waste Management and Eco-Friendly City. Waste

Management Strategy in Balikpapan. Waste Management Policy by Regional Planning and

Development Agency (BAPPEDA) Special Region of Yogyakarta (DIY). Waste Management in

Piyungan Landfill. Site visit: Sukunan Village and Piyungan Landfill. Waste Condition in Special

Region of Yogyakarta. Assignments (Waste management unit treatment, Pyrolysis and incinerator,

RDF gassification, composting, anaerobic digester, landfill)














and rewriting a written report called a Master's thesis. The students works with two supervisors

MASTER IN TRANSPORTATION SYSTEM AND ENGINEERING SYLLABI

i

Number of Contents

Transport Planning and Environment ....................................................................................................... 1

Analytical Methods ................................................................................................................................... 2

Transport Infrastructure Project Management .......................................................................................... 3

Transport Economics ................................................................................................................................ 4

Transport Infrastructure Design ................................................................................................................ 5

Traffic Safety ............................................................................................................................................ 5

Transport Planning and Modelling ........................................................................................................... 6

Transport Research Methodology ............................................................................................................. 7

Public Transport Planning ......................................................................................................................... 7

Traffic Flow Theory .................................................................................................................................. 8

Traffic Management .................................................................................................................................. 8

Transport Infrastructure Management ...................................................................................................... 9

Land-Use and Transport Interaction ......................................................................................................... 9

Pavement Design and Evaluation ........................................................................................................... 10

Pavement Construction Material ............................................................................................................. 11

Geotechnic .............................................................................................................................................. 11

Geometric Design and Evaluation .......................................................................................................... 12

Pavement Management System .............................................................................................................. 13

Freight Transport..................................................................................................................................... 14

Supply Chain Management ..................................................................................................................... 14

Transport Modes Integration ................................................................................................................... 14

Transport Infrastructure Management .................................................................................................... 15

Road and Rail Transport Infrastructure Design ...................................................................................... 16

Air and Sea Transport Infrastructure Design .......................................................................................... 17

Road and Rail Transport Management ................................................................................................... 17

Road and Bridge Planning and Design ................................................................................................... 18

Road Management System...................................................................................................................... 19

Bridge Management System ................................................................................................................... 19

1

1. Course Title : Transport Planning and Environment

Credits : 3

Objective(s) : The objectives are to ensure that students will have a sound understanding of the major environmental effects of transport and transport infrastructure, at a local and global levels including how to identify, to predict and to evaluate the environmental impacts; To ensure that students are aware of a range of measures available to reduce or mitigate environmental effects. To ensure that students are able to apply a range of techniques as part of an environmental appraisal (Environmental Impact Assessment).

Syllabi : Regulation on the environmental development programme (UU No. 4 Tahun 1982; UU No. 23 Tahun 1997; PP No. 27 Tahun 1999; KMLH on ‘AMDAL’; Other regional/international regulations). Introduction to Transport and Environment Planning (Environmental effects and sources; Environmental factors). Environmental problems analysis (Manifest problem; Root problem; Environment Assessment). Vibration Impact (Vibration impact to the human; Vibration impact to the structure; Vibration standard determination). Noise levels and noise index (Noise level and noise index; DB (A,B,C); L10 , L90 , Noise climate; Noise Impact (noise sources, noise dispersion methods, noise impact and the health, noise impact and disturbance to the human, noise standard quality). Calculation of road noise levels. Air pollution sources and its distribution (Air pollution sources; Air pollution dispersion methods); Air pollution impact to the environment (global environment, healthy, Quality standard of the air); Calculation of the air pollution level (Basic model in the prediction of the air pollution levels and Practical model in the prediction of the air pollution levels.)). Road design, land take and the impacts (Introduction; Road design impacts; Land take impact; Effect on mobility). Definition and forms of Environmental Impact Assessment “AMDAL & UKL-UPL”. Methods of “AMDAL, RKL and RPL”. AMDAL & UKL – UPL for transport infrastructure project

References : Lassiere, A., 1973, The Environmental Evaluation of Transport Plans, department of Transport, London, UK.

Salter, R.J., and David C.H., 1977, Transport and The Environment, Crosby Lockwood Staples, London, UK.

Sharp, C. & A. Jenning, 1976, Transport and the Environment, LUP Leicester, United Kingdom.

Brockenbrough, R.L. and Boedecker, Jr., K. J., 2003, Highway Engineering Handbook, Mc-Graw-Hill, New York.

Department of Transport, 1988, Calculation of Road Traffic Noise, HMSO, London.

2

2. Course Title : Analytical Methods

Credits : 3

Objective(s) : The objectives are to ensure that students understand the process of transport survey design, are familiar with the range of survey techniques available and are able to judge which technique would be appropriate in which circumstances. To ensure that students understand the principles underlying the statistical analysis of transport data and are equipped to select and interpret appropriate statistical tests; To ensure that students are able to analyse traffic data.

Syllabi : Introduction (Traffic analysis process; Data type; Data presentation; Sampling methods). Distribution (Central tendency measurement: mode, median. arithmetic mean, biometric mean, harmonic mean; Distribution dispersion: minimum, maximum, range, variance, standard deviation, standard error, relative dispersion (coefficient of variation)); Distribution form: symmetry, kurtosis; Distribution types: Discrete distribution (binomial distribution, Poisson distribution, geometric distribution), Continuous Distribution (normal distribution, negative exponential distribution, gamma distribution, log-normal distribution)). Field Survey (Field survey: survey methods, utilizing survey equipment, data reduction). Estimation Problems and Hypothesis tests (Problems estimation: estimating the mean, difference between two mean, proportion, difference between two proportions, variance, ratio of two variance; Hypothesis tests : Testing a statistical hypothesis, one and two tailed test, the use of P-values in decision making, single sample tests on single mean (variance unknown), two samples tests on two means, one sample test on a single proportion, two sample tests on two proportion, goodness of fit test, test for independence, test for homogeneity, testing for several proportions). Regression Analysis and Multivariate Multiple Regression (Simple linear regression and correlation; Multivariate multiple regression). Non-parametric tests (Non-parametric tests– distribution tests: binomial and multinomial distributions, normal distribution, chi-squared distributions). Optimization (Unconstrained optimization; Constrained optimization). Traffic Volume Analysis (Traffic Volume Analysis: ADT and AADT, expansion factors, peak hour factor, saturation flow, distribution factor, origin-destination matrix, traffic volume diagrams). Traffic speed, Headways and Parking Analysis (Traffic speed and delays analysis; headways analysis; parking analysis). Pedestrian, Traffic Volume and Traffic Speed Analysis (Pedestrian analysis; Traffic volume analysis; Traffic speed analysis). Survey Design: Delay, Queue Length, Saturation Flow and Parking Surveys (Delay on the intersection suevey; queue length on intersection survey; Saturation flow survey; Parking survey).

References : Chong, E.K.D and Zak, S.H, 1996 , An Introduction To Optimization, John Wiley & Sons Inc., New York.

Greene, W.A, 1997, Economic Analysis (logit : Model for Multiple Choices-Chap 19), Prentice Hall, New York.

Johnson, R.A. and Wichern, D.W, 1982 , Applied Multivariate Statistical Analysis, Chapter 7, Prentice Hall, Inc.

Taylor, MAP and Young W, 1988, Traffic Analysis, New Technology & New Solutions, Hargreen Publishing Company, Australia (Part 1-2).

Taha, H.A., 1988, Operation Research, An Introduction, 7th Edition, Prentice Hall International, Edition.

3

Walpole, R.E. dan Myers, R.H., 1993, Probability and Statistics for Engineers and Scientists.

3. Course Title : Transport Infrastructure Project Management

Credits : 2

Objective(s) : The objectives are to ensure that students will understand procedure of tender and contract locally and internationally; law aspects in the implementation contract of road construction including the escalation estimation. Understanding of document is started from instruction to the participants of the tender, condition of general contracts, the picture and the quantity and also the cost, technical conditions; understanding of the function of the consultant and the supervisor, understanding of National and International specification

Syllabi : Project management (transport infrastructure projects, project management, project initiation and successfull); risk management and project appraisal (investment and sanction selection, project appraisal, project evaluation, engineering and management risks); environmental impact to the project management (enviromental impact assesment (EIA), baseline study and impact prediction, environmental legislation, environmental impact, statement, monitoring and auditing of environmental impacts, environmental economics), Quality management (quality system and implementation, quality circles and quality plans, Total Quality Management (TQM)); project organization; project manager; project budgeting system, project cash flow; site planning and earned value analysis (EVA) (programming and network analysis, project management software selection, logical frame work; value of work done control, aplikasi dan studi kasus EVA, cost escalation); job contract strategy; tender procedure and contract policy; procurement (national and international); consultant contract implementation; International projects (comparison of turnkey contracts and BOOT projects, performance spesification, bidding turnkey contracts, concession contracts and cosnsession agreements, organizational and contractual structure, procurement strategis and consession periods, classification of BOOT projects, risks fundamental to BOOT projects, BOOT package structure, advantages and disadvantages of BOOT projects); turnkey and BOOT project (project management for developing countries).

References : 1. Austen A.D.; Neale R.H. “Manajemen Proyek Konstruksi, Pedoman, Proses dan Prosedur”, (1994), P.T. Pustaka Binaman Pressindo, Jakarta.

2. Asian Development Bank Hand Out, 2000, “Project Implementation and Administration Seminar, The Project Cycle”, Dep. Kimbangwil, Jakarta.

3. Barrie Donald S; Paulson, JR Boyd C.; Sudinarto, 1993, “Manajemen Konstruksi Profesional”, Edisi Kedua, Penerbit Erlangga, Jakarta.

4. Bintoro Tjokroamidjojo, Prof., 2001, “Good Governance” (Paradigma Baru Manajemen Pembangunan), Lembaga Administrasi Negara, Jakarta.

5. Dep. PU., 1998, “Petunjuk Praktis Pengendalian Pelaksanaan Proyek di Bidang Pekerjaan Umum untuk Para Pemimpin Proyek/Bagian Proyek”, Yayasan Badan Penerbit PU., Jakarta.

6. Fuady Munir, SH., MH., LLM, 1998, “Kontrak Pemborongan Mega Proyek”, PT. Citra Aditya Bakti, Bandung.

7. Haswell CK; DS de Silva, “Civil Engineering Contract and Prosedure”, (1982), Butterworth & Co. (Publishers) Ltd, Cambridge, England.

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8. Hardi William, 2000, ”Good Governance Basic Procurement Workshop”, World Bank Office, Jakarta.

9. John G.: Sawyer C. Arthur Gilliot,”FIDIC Conditions of Contract 4 th ed“, (1987), Thomas Telford ASCE.

10. Keputusan Presiden RI No.80 Tahun 2003, “Pedoman Pelaksanaan Pengadaan Barang/Jasa Instansi Pemerintah jo Keppress RI No. 61 tahun 2004”, Jakarta.

11. Peraturan Pemerintah RI No. 28 Tahun 2000, ”Usaha dan Peran Masyarakat JAKON”, Yayasan Badan Penerbit PU, Jakarta.

12. Peraturan Pemerintah RI No. 29 Tahun 2000, “Penyelenggaraan JAKON”, Yayasan Badan Penerbit PU., Jakarta.

13. Peraturan Pemerintah RI No. 30 Tahun 2000, “Penyelenggaraan Pembinaan JAKON”, Yayasan Badan Penerbit PU., Jakarta.

14. Pusdiklat Dep. Kimbangwil, 2000, ”Tatacara Pengadaan Barang/Jasa Luar Negeri”, Dep. Kimbangwil, Jakarta.

15. Smith J. Nigel, “ Engineering Project Management”, (1995), Blackwell Science Ltd, Australia.

16. Undang-Undang RI No. : 18 tahun 1999, “Jasa Konstruksi” (1999), P.T. Medisa, Yayasan Badan Penerbit PU., Jakarta.

4. Course Title : Transport Economics

Credits : 3

Objective(s) : The objectives are to ensure that students will have a sound understanding of the principles and practice of transport economic and that they will be able to apply the requisite techniques and procedures.

Syllabi : Basic meaning of economic (Law of diminishing returns; Law of increasing demand; Subsistence economy; Invests, surplus). Transport demand (Demand curve behaviour; The influenced factors; Elasticity). Transport supplies for land transport, sea transport, air transport, modal and infrastructure (Basic principle; fixed and variable costs; Joint, common cost; Generalized cost; Case for highway and railway). External costs (Transport external; External Values; Congestion phenomenon; Congestion Values). Transport Pricing (Basic principle for pricing; Marginal Cost Pricing; Cost discrimination; Peak Traffic Problems; Subsidy). External cost collection (Principle of polluter’s pay; Congestion charges; parking charges; subsidy and environment). Project Appraisal (Appraisal types; Economy and financial analysis; Shadow pricing; Advantage cost analysis; Sensitivities). Transport and regional development (Transport and economical development; Developing countries cases; Transport and regional development; Transport and urban development). Transport Regulation (Theory of regulation; Priority in the transport policy; Reform in the regulation).

References : Button, K.J., 1982. Transport Economics, Heinemann, London.

Evans, A.W., 1985. Urban Economics, Basil Blackwell, Southampton.

Perpres 67, 2005, Kerjasama pemerintah swasta dalam penyediaan infrastrktur publik

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5. Course Title : Transport Infrastructure Design

Credits : 3

Objective(s) : Basic concept of transport infrastucture design: transport planning versus the need of transport infrastructure development, transport infrastructure design based on needs and technical standard references, general steps in carrying out detailed engineering design of transport infrastructure. Road geometric design: (hierarchy of road network (class and function), road components (urban and rural), vehicle characteristics and road components, standards and regulations for road technical design, horizontal and vertical alignment analysis, minimum road network services. Terminal design: terminal types and components, indicators and benchmarks for terminal performance (location, site and access), technical design standards and regulations for terminal. Airport Design: airport types and components, indicators and benchmarks for airport performance, standards and regulations for airport technical design. Port Design: port types and components, indicators and benchmarks for port performance (location, site and access), technical design standards and regulations for port. Railtrack and Train Station Design: types and components of railtrack and train station, indicators and benchmarks for railtrack and train station performance (location, site and access), technical design standards and regulation for railtrack and train station.

Syllabi :

References : Molenaar, AAA, 1977. Pavement Design and Maintenance System in Texas and their Applicability for the Netherlands, TU Delft.

Molenaar, AAA, 1983. Structural Performance and Design of Flexible Road Construction and Asphalt Concrete Overlays, TU Delft.

………., 2000, Referensi Kepelabuhanan Seri 1 – 11, PT. Pelabuhan Indonesia.

Hay W.W, , 1982,Railroad Engineering, Second Edition , John Wiley & Sons.

Mundrey J.,S.2000, Railway Track Engineering, Third Edition, Tata McGraw-Hill Pusblishing Compony Limited, New Delhi.

Esveld, C., 2001. Modern Railway Track. Delft: Delft University of Technology

Profillidis, V. A., 2009. Railway Management and Engineering. Third Edition, Burlington: Ashgate Publishing Company

Subyanto, 1982, Dinamika Kendaraan-Rel: Suatu Pembahasan Mengenai Gerakan Perjalanan Kereta Api di Atas Jalan Baja Ditinjau Dari Segi Operasi Teknis, Bandung

Utomo, S., H., T., 2009. Jalan Rel. Yogyakarta: Beta Offset Yogyakarta

Hardiyatmo, H. C., 2014. Mekanika Tanah 2. Yogyakarta: Gadjah Mada University Press

6. Course Title : Traffic Safety

Credits : 2

Objective(s) : The objectives are to ensure that students will understand factors affecting traffic accident (individual, systemic - complex). To introduce the problem of the traffic safety in the developing countries, the observation of the factors of source of the traffic safety, drivers, transports and roads, the concepts to analyze the problems of the traffic safety and black spot

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Syllabi : Introduction, definition, objectives and traffic safety problems (traffic safety in the developing contries, the rolr of traffic safety); factors causing traffic accidents (accident rate calculation methods, traffic accident time periods, accident prediction without taking into account of location); analysis of factors affecting individual traffic accident case; analysis of factors affecting complex traffic accident case; comparative evaluation in traffic accident and dangerous accident area (cost benefit study, before and after study, definition of dangerous accident area – black spot, black site, black area and how to solve the problem); The analysis of accident, the data needs and information. The steps in handling and the management of the traffic safety including the implementation program. Traffic Safety Programme (problem identification, designing traffic safety programme). Road Safety Audit (on the planning process, Basic Design and Detailed Design steps, construction and operational steps)

References : 1. Jacobs, G.D. dan Sayer, I, 1984, Road Accident in Developing Countries-Urban Problems and Remedial Measures, Collection of the Official Reports, International School of Transportation Safety, Imaiff, Italy.

2. Garber, N.J. and Hoel, L.H., 1988, Traffic and Highway Engineering, West Publishing Company, New York.

3. TRRL, 1991, Toward Safer Road in Developing Countries, TRRL, UK.

4. Proctor, S. et al, 2001, Practical Road Safety Auditing, Thomas Telford, London.

7. Course Title : Transport Planning and Modelling

Credits : 3

Objective(s) : The objectives are to ensure that students will understand the role and purpose of the main types of transport models; To become familiar with the advantages and disadvantages of each of a range of modelling techniques available and to be able to select an appropriate model for a given task; To use a basic modelling package to analyse a realistic 'real life' problem.

Syllabi : TPM problem and scoupe (technical problems, strategis problems, conceptual problems, planning vision, planning mission, strategical planning, institution culture); objective classification (technical objectives, strategical objectives, conceptual objectives); TPM flow chart (problem identification, reference study, factual observation and modelling determination, determination of planning variables); Zone determination, planning of survey (makro zone determination, meso zone determination, mikro zonecredit determination, variable assessment planning, survey organization, survey carrying out); data analyze and application (planning system and road network structure, integrated approachment in transport planning, urban transport general planning); trip generation model (regression analyzis, categorised analyzis, model variable forecast, trip generation); trip distribution model (growth factor model, gravitation or synthetic model, synthetic model calibration); modal split model (influence factor in modal split, logit model); trip assignment model (basic concept, assignment methods, all or nothing model, stochastic model, equilibrium model); other models (elastic analysis, vehicle ownership forecast, modelling utizing the stated preference data).

References : Ortuzar, J. de Dios & Willumsen, L.G., 1994. Modelling Transport, John Wiley & Sons.

Papacostos, cs., 1987. Fundamentals of Transportation Engineering, Prentice Hall International Inc., New Jersey

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Sheffi, Y, 1990. Urban Transportation Network : Equilibrium Analysis with Mathematical Programming Methods, Prentice Hall Inc, New Jersey

8. Course Title 9. : Transport Research Methodology

Credits : 3

Objective(s) : The objectives are to ensure that students will understand the relation between the pure and the applied science. The variety and general pattern of research, an identification of problems, library research, theory and hypothesis, data collection (sampling, error, interview) and the processing, research in engineering sciences, writing technique, experimental design, method of non experimental research, research through observation data, multidimensional measurement.

Syllabi : Principal of research (general definition of science, basis research, research function in the science development); research procedure (scientific research procedure, sustainable scientific research); obstruction in research (researcher: difficultie in problem formulation, braveness in presenting the actual data, lack of ability); researcher requirements (competence requirement: objectivity, honesty and discipline); problems in research. Research proposal arrangement: systematics, definition and function of each elemen in the proposal, interconetivity between elemens. Research implementation (research preparation, procedure, equipment and tools, analysis preparation); research report writing (systematics, interconnectivity each element in the report, technical requirement and writing guideline); writing papper (systematics for journal and seminar papper, technical problem in presentation), historical methods (phenomenon reconstruction, applied technology, lost data collection design); descriptive methods (lost data arrangement); experimental methods (control variable); grounded research method (categorized data), action research methods, free variables manipulation, research approach principal (theoretical deduction and data induction as theory), sampling, interview, measurement (reliability, validity, psychological and sociological measurement); Research subject in transport (transport system and management, transport engineering, subject from journal, pappers and internet), Research resume (abstract, presentation technique).

References : 1. Kerlinger, F.N., 1990, Asas-asas Penelitian Behavioural, Gadjah Mada University Press, Yogyakarta.

2. Moch. Nazir, 1988, Metode Penelitian, Ghalia Indonesia.

3. Singarimbun M, Sofian Effendi, 1989, Metoda Penelitian Survai, LP3ES, Jakarta.

9. Course Title : Public Transport Planning

Credits : 3

Objective(s) :

Syllabi : History, public transport and city growth, history and principles of public transport planning, modal systems and technology (train, bus, paratransit), public transport planning (transport system management, public transport demand, system planning and service, public transport performance, public transport alternatives comparation, public transport planning and policy, public transport regulation, public transport planning and transport system management, public transport route and stop/interchange planning, public transport planning (vehicle size, number of vehicles, tariff and subsidy), public transport and sustainable transport, public transport integration.

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References : Gray, GE & Hoel, LA, 1992. Public Transportation, Prentice Hall, New Jersey Vuchic, VR, 1981. Urban Public Transportation System and Technology, Prentice Hall,

New Jersey

10. Course Title : Traffic Flow Theory

Credits : 3

Objective(s) : The objectives are to ensure that students will understand

Syllabi : General traffic characteristics consist of the basic, the speed, the spacing and the headway and parking. Theory of the traffic flow covers the understanding of the basic, the measurement method, the variable relation, macro and micro modelling, the flow and its distribution. Whereas the analysis and study of the traffic technique consist of the volume study, the travel study of time and delay, the intersection study, capacity of the roads and the service level, facility and parking system. The transportation technology includes the detector, the system of area traffic control, the signs and marks technology, the transports navigation, the transportation system, the introduction of the program and the on line control.

References : 1. May, A.D., 1990, Traffic Flow Fundamentals, Prentice Hall, New Jersey.

2. Hobbs, F.D., 1967, Traffic Engineering.

3. Institute of Transportation Engineers, 1976, Transportation and Traffic Engineering Handbook, Prentice Hall, New Jersey.

4. Garber, NJ and Hoel, LH, 1988, Traffic and Highway Engineering, West Publishing Company, New York.

5. Picnataro, Louis J., 1973, Traffic Engineering Theory and Practice, Prentice Hall, New Jersey.

11. Course Title : Traffic Management

Credits : 2

Objective(s) : The objectives are to ensure that students will understand the Integrated traffic management consists of the concept and the process, law and the traffic regulations, signs and the traffic marks, lightening, the traffic signal. The increasing of the capacity and the smoothness of the flow cover the intersections, access, the areas, one way road, the rising of flow, the turning of flow, route guidance. The system of priority and the limitation: bus priority, pedestrian precincts, the environmental priority and parking.

Syllabi : Introduction to traffic management (definition and objectives of traffic management, traffic management strategies, case studies); Link (case studie on passenger car unit, link capacity and speed studies calculation according to ‘MKJI” – Indonesian highway capacity manual, application the traffic management on link); parking (calculation method of parking parameters, on street and off street parking); traffic control (sign, mark, traffic signal, parking coordination method); coordination of on-land intersection and traffic signal coordination (unsignalized intersection, unsignalized roundabout, signalized junction,

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signalized roundabout, traffic signal coordination); pedestrian (pedestrian level of service, pedestrian facilities calculation, pedestrian coordination); bicycle (bicycle facilities – types, calculation, and coordination); public transport coordination methods (public transport priority, public transport policies); traffic management models in accordance to traffic safety; one way road, the rising of flow, the turning of flow, route guidance; traffic management policies.

References : 1. Lapierre, R., Steierwald, G., 1987. Verhehrsleittechnik fuer den Strassenverhehr Band I + II, Springer Verlag, Berlin

2. Munawar, A., 2004, Manajemen Lalulintas Perkotaan, Beta Offset, Yogyakarta

3. White, Peter R., 1978. Planning for Public Transport, The Anchor Press Ltd., Essex, U.K.

12. Course Title : Transport Infrastructure Management

Credits : 2

Objective(s) : The objectives are to understand the principles of engineering design as they apply to transport systems. They should also be familiar with the engineering design requirements associated with road construction and maintenance and with public transport infrastructure. To ensure that students are equipped with the theoretical understanding and practical skills needed for the design of safe and efficient highway links, junctions and car parks, and that they understand the advantages and disadvantages of different solutions.

Syllabi : Transport infrastructure management concept (road network hirarchy concpet (class and function) and its consequencies to the right of way (ROW) and road componen (urban and rural), and its consequencie to the site implementation. Enforcement status in the connection of the funding system of road network management. Basic concept of road transport infrastructure performance: road network performance indicators and standards, link and junction, and pavement; Concept of minimum service standard on road network performance, road performance evaluation and the infrastructure treatment method in terms of man power enforcement, equipment, fund, material and methods condition.



David Croney D., 1977. The Design and Performance of Road Pavement, TRRL London.

Yoder, E.J., and Witczak, M.W., 1975. Principles of Pavement Design, McGraw Hill.

Haas R., Hudson W.R., and Zaniewski, J. (1994): Modern Pavement Management, Krieger..

13. Course Title : Land-Use and Transport Interaction

Credits : 2

Objective(s) : The objectives are to ensure that students will understand the definition and the concept, the dynamic intersection of the land use and transportation, the process of the land use and

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transport design, the intersection of the land use and transportation in the local and regional scale. The land use model for agriculture and urban area, model reformation.

Syllabi : Basic understanding of land-use and urban economics (general description of transport system and land-use interaction, understanding of land as economical goods and the urban economical principal; intruducing the land-use (definition and concept of land use, land-use introduction, land-use controlling, urban development); conceptual study on transport system and land-use interaction theory (conceptual study: principal and development of transport system and land-use inreraction theory, case study). Urban land use planning and its relation to transport planning; micro economic theory in land use; spacial-interaction theory (review on transport distribution model: Furness, Gravity Model, Intervening Opportunity, Entropy Maximizing/Tri Proportional Approach, Lowry Model, etc.).

References : 1. Blunden, WR & Black, JA, 1984. The Land Use Transport System, Pergamon Press, Australia

2. Banister, D., Watson, S., Wood, C., 1994, The Relationship between Energy Use in Transport and urban Form, Working Paper 10, Planning and Development Research Centre, University College London.

3. Chapin, Jr. F. and E.J. Kaiser, 1979, The Land Use/Transportation System, 2nd Edition, Pergamon Press, Sydney.

4. De la Barra Tomas, 1989, Integrated Land Use and Transport Modelling : Decision Chains and Hierarchies, Cambridge University Press, Great Britain.

5. Button, K.J., 1993, Transport Economics, 2nd Edition, Edward Elgar Aldershot.

6. DEPDAGRI, 1987, Peraturan Menteri Dalam Negeri No.2 Th. 1987 tentang Pedoman Penyusunan Rencana Kota, Dit.Jen. Bangda, Depdagri, Jakarta.

7. ECMT, 1992, Structural Changes in Population and Impacts on Passenger Transport, Round Table 88, ECMT, Paris.

8. Horowitz, J.L., 1984, Land Use Impacts of Highway Projects, dalam Alex Anas : Principles and Parables of Transportation Research/Land-Use Interaction.

9. Kaufmann, J.L., and H. Jacobs, 1987, A Public Planning Perspective o Strategic Planning, Journal of American Planning Associantion, Vol 53, No.1

10. Webster F.V., Bly, P.H. Laulley, N.J., 1988, Urban Land-Use and Transport Interaction : Policies and Models, Report of the International Study Group on Land-Use/Transport Interaction (ISGLUTI), Avebury, Aldershot.

14. Course Title : Pavement Design and Evaluation

Credits : 3

Objective(s) :

Syllabi : Knowledge of the basic concepts of hard layer design, Boussinesq, Burmister and multilayers theory, Westergaard theory. Pavement design application using AASHTO method, Road Note 29 and 31, Asphalt Institute, runway pavement design, pavement maintenance management: overlay, recycling (recycling, mixed design and implementation), surface dressing, surface treatment, joint sealing, crack sealing. Equilibrium equation,

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stress-strain, strain-displacement and axissymetry, plate above elastic foundation, three-dimensional solid, computer program and their applications to pavement.

References : The Asphalt Institute MS-I, 1970 : AC No.150/5320 – 6D Airport Pavement Design and

Evalution. AASHTO, 1986, Guide for Design of Pavement Structures, AASHTO, Washington D.C. Suhendro,B., 1994, Metoda Elemen Hingga, Jurusan Teknik Sipil Universitas Gadjah Mada. Manual Program SAP-90. Manual Program Sigma/W.

15. Course Title : Pavement Construction Material

Credits : 3

Objective(s) : The objectives are to ensure that students will understand the characteristic of aggregate, asphalt and mixture technology.

Syllabi : Aggregate (petrology, phisical and chemical behaviour, adhession, gradation and aggregate structural design, surface area, aggregate substitution, segregation, contamination, degradation, aggregate as road material, additives); Asphalt-aggregate mixture (mixing technology (HMA and CMA), mixture characteristics, compactor and compaction level, density and voids analysis, asphalt-filler ratio, mastics viscosity, asphalt content, asphalt film thickness, moisture susceptibility of mix, densification and refusal density, mix performance, pavement deterioration, aggregate-asphalt mix design, “Asbuton” technology, Superpave); Pavement and pavement structure (pavement type, advantage and disadvantage of the pavement types); asphalt characteristics (composition, molecular structure, compotition concept model); Asphlat rheology (asphalt hardening, temperature susceptibility, Penetration Index, stiffness modulud, penetration, ductility, viscosity); asphalt modification (backgorund and definition, modifiers, applications); asphalt emulsion (contents and production/manufacture, cold mix design using aspahlt emulsion); Concrete characteristics (cement characteristics, cement types and additives, aggregate gradation, aggegate toughness and abrassion level, water-cement ratio); Concrete behavoiur (water-cement ration on realtion to the flexural/compression/splitting strengths, workability, compactibility, segregation); hard concrete characteristics (cylinder test, permeability, modulus of rupture, resistance to abbrasion), concrete design methods (British and graphical methods).

References : Roberts Freddy L, Kandhal Prithvi S, Brown, E Ray, Lee dan Yinn, Kennedy, Thomas W, 1991. Hotmix Asphalt Materials, Mixture Design and Construction, Napa Education Foundation Lannam, Maryland

Whiteoak, D., 1990. The Shell Bitumen Handbook, 4th edition. Riversdell House, London

Whiteoak, D. dan Reed, J. 1990. The Shell Bitumen Handbook, 5th edition. Thomas Telford Publishing, London

16. Course Title : Geotechnic

Credits : 2

Objective(s) : Reviews the engineering properties of soils and site investigation in sufficient detail to provide a basis for application to highway structure.

Syllabi : Soil identification: Unified and AASHTO classification; Soil Compaction: compaction method, control of compaction, compaction equipment, vibroflotation, CBR test. Subgrade: effect of water and weather on subgrade, shear strength of soil, settlement,

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expansive soil, slope stabilization, slide down problems (identification, slope repairement), Soil improvement for road construction: settelement speeding up (vertical drainage); soil stabilization with limestone, cement and asphalt emultion; Soil reinforcement theory; geotextile application; geogrid; and steel lining for retaining wall, geosynthetic application for road construction

References : Abramson, L.W., Lee, T.S., Sharma, S. dan Boyce, G.M., 1996. Slope Stability and Stabilization Methods. John Willey & Sons, New York.

Cernica, J.N., 1995. Geotechnical Engineering – Soil Mechanics. John Willey & Sons Inc. Canada.

Federal Highway Administration, 1998. Highway Slope Maintenance and Slide Restoration Workshop. US Departement of Transportation, Report No. FHWA-RT-88-040, Desember 1988, Washington DC.

Geotechnical Control Office, 1991. Geotechnical Manual for Slopes. Geotechnical Control Office Eng. Development Departement, Hongkong.

Giray, D.H. and Sotir, R.B., 1996. Biotechnical and Soil Engineering Slope Stabilization – A Practical Guide for Erosion Control. John Willey & Sons, New York.

17. Course Title : Geometric Design and Evaluation

Credits : 2

Objective(s) :

Syllabi :

References

:

Road geometric design concept starting from analysis of road route selection, road design and interchange form with environmental sustainability by prioritizing the principles of safety, horizontal alignment design application, vertical alignment design application, road picture (3D), grade separated intersection design, road complementary building (bridges, culverts, road drainage channels), the concept of road geometric evaluation for each step of design, alternative problem solutions or road geometric with special condition and grade separated intersection. Undang-undang No. 38 Tahun 2004 tentang Jalan Peraturan Pemerintah No. 34 tahun 2006 Undang-Undang No. 22 tahun 2009 tentang Lalu Lintas dan Angkutan Jalan Raya Departemen Pekerjaan Umum, 1992, Standar Perencanaan Geometrik untuk Jalan

Perkotaan, Direktorat Jenderal Bina Marga. Departemen Pekerjaan Umum, 1997, Tata Cara Perencanaan Geometrik Jalan Antar

Kota, Direktorat Jenderal Bina Marga. Departemen Pekerjaan Umum, 1997, Manual Kapasitas Jalan Indonesia, Jakarta AASHTO, 2004, A Policy on Geometric Design of Highways and Streets, USA Austroads, 2003, Rural Road Design, A Guide to the Geometric Design of Rural Roads,

Australia. Banks, J. H., 2011, Introduction to Transportation Engineering, McGrawHill, New York. Oglesby, C.H. and Hicks, R.G., 1982, Highway Engineering, John Wiley & Sons, New York. Pd T-18-2004-B Penentuan Klasifikasi Fungsi Jalan di Perkotaan Schoon, J.,G., 2000, Geometric Design Projects for Highways, ASCE Press, Virginia. South African National Roads Agency Limited, 2001, Pretoria. Wright, P.H., 1996, Highway Engineering, John Wiley & Sons, New York

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18. Course Title : Pavement Management System

Credits : 2

Objective(s) : This course presents the different elements of pavement management systems, which encompasses a wide spectrum of activities including planning, programming of investments, design, construction, maintenance, and periodic evaluation of performance. Furthermore, to ensure that students will understand the most common forms of deterioration pavements; a range of investigative techniques that may be used to identify the forms of deterioration; a range of remedial measures which may be used and be able to select the most practical and economic course of action; the overall process of managing the highway asset.

Syllabi : Introduction to Pavement Management (The process of pavement management; Benefits of pavement management); Data base: data types, data format, data access hirarchy. Base concept on the pavement deterioration prevention. Pavement Performance Measures (The serviceability-performance concept; Roughness and skid resistance measurement; Visual Surface distress survey procedures and techniques) Pavement performance analysis (structural and functional performance analysis): pavement performance indicators and standards (structural and functional), road pavement remaining service life; Performance monitoring methods: visual survey (PCI and Bina Marga methods), surface course roughness (Mu- Meter, British Pendulum Tester), surface course eveness (Laser Beam profilometer), pavement deflection (Benkelmen Beam, Falling Weight Deflectometer); Maintenance Planning and Rehabilitation Strategies (Maintenance need and impact analysis; Development of annual and long-term work plans) Prediction Deterioration Models (Factors that affect performance; Types of prediction models; Prediction deterioration model development; Method to assess the precision and accuracy of the developed model). Road structure deterioration (pavement, shoulder, road bed, drainage). road construction deterioration process. Vehicle damage factors analysis, material characteristics analysis, regional factor analysis, construction analysis); Embankment: slope stabilization analysis, embankment erosion, soil layer density level analysis); Road drainage (surface drain and sub-drain). Application of road deterioration analysis methods (stress-strain response analysis (analytical approach, pavement structure model, multi-layer theory (one layer, two layer and three or more layer systems; thickness equivalent); software application (BISAR and CIRCLY); Pavement Structural Design and Economic Analysis (Structural response model; Cumulative damage theory; Structural analysis and design of different types of pavements; Cost and benefit estimation; Life-cycle costs analysis and maintenance planning); Variability, Reliability and Risk in Pavement Management (Definitions and concepts; Formulation of pavement reliability; Influence of variability on pavement management); Prioritization and Optimization (Factors affecting network-level component selection; Criteria for candidate section selection; Prioritization techniques; Optimization procedures); Emerging Technology in Pavement Management Systems (Nondestructive testing; Real-time data collection; Geographic information system and pavement management Decision support system and expert system).

Textbooks : Haas R., Hudson W.R., and Zaniewski, J. (1994): Modern Pavement Management, Krieger.

Shahin, M.Y. (1994): Pavement Management for Airports, Roads, and Parking Lots, Kluwer Academic Publishers

References : Shahin, M. Y., 2006, Pavement Management for Airports, Roads, and Parking Lots (2nd edition), Springer, New York.

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Haas, Ralph C.G., Hudson, Ronald W., Zaniewski, John P., 1994, Modern Pavement Management, Krieger Publishing Company.

Hudson R., Haas, W.R. and Uddin, W. (1997): Infrastructure Management, McGraw-Hill.

AASHTO (2001): Pavement Management Guide.

19. Course Title 20. : Freight Transport

Credits : 3

Objective(s) :

Syllabi : Freight transport needs, Freight transport urgency, Freight classification, Cargo forms, Intermodal freight transport, Freight transport types variation, Freight transport modes types, Freight transport management, Good movement, Freight transport design, Freight transport planning, Freight transport demand, Freight transport distribution.

References : Institute of Transportation Engineers, 1976, Transportation and Traffic Engineering Handbook, Prentice Hall, New Jersey. Gray, GE & Hoel, LA, 1992. Public Transportation, Prentice Hall, New Jersey Vuchic, VR, 1981. Urban Public Transportation System and Technology, Prentice Hall,

New Jersey

20. Course Title : Supply Chain Management

Credits : 3

Objective(s) :

Syllabi : History, freight transport and city growth, history and principles of supply chain management planning, modal systems and technology (rail, bus, paratransit), transport planning to support supply chain management (transport system management, public transport demand, system and service planning, public transport performance, public transportation alternatives comparation, Public Transport Regulation related to multimodal transportation to support supply chain management.

References : Gray, GE & Hoel, LA, 1992. Public Transportation, Prentice Hall, New Jersey Vuchic, VR, 1981. Urban Public Transportation System and Technology, Prentice Hall,

New Jersey

21. Course Title : Transport Modes Integration

Credits : 2

Objective(s) :

Syllabi : Transport modes integration concepts: integration planning or integrated transport based on needs and technical standard references, general steps in carrying out detailed technical design of transport infrastructure. Road network system and management concepts: Road network hierarchy (class and function), Road components (urban and

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rural), vehicle characteristics and road components, technical design standards and regulations for road, horizontal and vertical alignment analysis, minimum road network services. Terminal Management: terminal types and components, indicators and benchmarks for terminal performance (location, site and access); technical design standards and regulations for terminal. Airport Management: airport types and components, indicators and benchmarks for airport performance; technical design standards and regulations for airport. Port Management: port types and components, indicators and benchmarks for port performance (location, site and access), technical design standards and regulations for port. Railtrack and Station Management: railtrack and station types and components, indicators and benchmarks for railtrack and station performance (location, site and access), technical design standards and regulations for railtrack and station. Intermodal transport connectivity concepts: optimizing performance between modes and intermodal transport with efficiency and implementation effectiveness benchmarks. Seamless transportation application in selected cases.

References : ………., 2000, Referensi Kepelabuhanan Seri 1 – 11, PT. Pelabuhan Indonesia.

Hay W.W, , 1982,Railroad Engineering, Second Edition , John Wiley & Sons.

Mundrey J.,S.2000, Railway Track Engineering, Third Edition, Tata McGraw-Hill Pusblishing Compony Limited, New Delhi.

Esveld, C., 2001. Modern Railway Track. Delft: Delft University of Technology

Profillidis, V. A., 2009. Railway Management and Engineering. Third Edition, Burlington: Ashgate Publishing Company

Utomo, S., H., T., 2009. Jalan Rel. Yogyakarta: Beta Offset Yogyakarta Institute of Transportation Engineers, 1976, Transportation and Traffic Engineering Handbook, Prentice Hall, New Jersey. Gray, GE & Hoel, LA, 1992. Public Transportation, Prentice Hall, New Jersey Vuchic, VR, 1981. Urban Public Transportation System and Technology, Prentice Hall,

New Jersey

22. Course Title : Transport Infrastructure Management

Credits : 2

Objective(s) :

Syllabi : Transport infrastructure management concepts. Road network: (Road network hierarchy (class and function), Road components (urban and rural), Indicators and benchmarks for road networks performance, sections and intersections, Minimum service standards for road networks, road performance evaluation methods, causes of road performance degradation, road management efforts. Pavement management: basic concept of pavement management, types of structural and functional pavement damage (flexible and rigid), possibility of factors causing pavement damage, monitoring methods of pavement performance, methods pf pavement damage repairment, handling pavement strategies; airport pavement evaluation with ACN/PCN method. Terminal: terminal types and components, indicators and benchmarks for terminal performance (location, site and access); evaluation methods of terminal performance, factors of terminal performance decline, terminal management and development efforts. Airport: airport types and components, indicators and benchmarks for airport performance; evaluation methods of airport performance, factors of airport performance decline, airport management and development efforts. Port: port types and components, indicators and benchmarks for port

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performance (location, site and access); evaluation methods of port performance, factors of port performance decline, port management and development efforts. Train Station : train station types and components, indicators and benchmarks for train station performance (location, site and access), evaluation methods of train station performance, factors of train station performance decline, train station management and development efforts.



David Croney D., 1977. The Design and Performance of Road Pavement, TRRL London. Yoder, E.J., Witczak, M.W., 1975. Principles of Pavement Design, McGraw Hill.

………., 2000, Referensi Kepelabuhanan Seri 1 – 11, PT. Pelabuhan Indonesia.

23. Course Title : Road and Rail Transport Infrastructure Design

Credits : 3

Objective(s) :

Syllabi : Construction steps of road infrastructure (design location in the step): pre FS, FS, BD, DED, land acquisition. Geometric design of intercity roads: road components, determination of road route, horizontal and vertical alignment design of road segments; intersection design (at grade intersection including roundabout and grade separated intersection). Urban road geometric design: road components, determination of road trail, road horizontal and vertical alignments design; Intersection design (related to this given in MLL). Parking facilities design: Determination of vehicle standards, SRP, alley lanes; Determination of parking configuration, capacity calculation, access design. Terminal design for buses and rest areas: Terminal types and components, determination of terminal location, terminal layout design, terminal access design. Cargo terminal design: Terminal types and components, determination of terminal location, terminal layout design, terminal access design

References : Undang-undang No. 38 Tahun 2004 tentang Jalan Peraturan Pemerintah No. 34 tahun 2006 Undang-Undang No. 22 tahun 2009 tentang Lalu Lintas dan Angkutan Jalan Raya Departemen Pekerjaan Umum, 1992, Standar Perencanaan Geometrik untuk Jalan

Perkotaan, Direktorat Jenderal Bina Marga. Departemen Pekerjaan Umum, 1997, Tata Cara Perencanaan Geometrik Jalan Antar

Kota, Direktorat Jenderal Bina Marga. Departemen Pekerjaan Umum, 1997, Manual Kapasitas Jalan Indonesia, Jakarta AASHTO, 2004, A Policy on Geometric Design of Highways and Streets, USA Austroads, 2003, Rural Road Design, A Guide to the Geometric Design of Rural Roads,

Australia. Banks, J. H., 2011, Introduction to Transportation Engineering, McGrawHill, New York. Oglesby, C.H. and Hicks, R.G., 1982, Highway Engineering, John Wiley & Sons, New York. Pd T-18-2004-B Penentuan Klasifikasi Fungsi Jalan di Perkotaan Schoon, J.,G., 2000, Geometric Design Projects for Highways, ASCE Press, Virginia. South African National Roads Agency Limited, 2001, Pretoria. Wright, P.H., 1996, Highway Engineering, John Wiley & Sons, New York

17

24. Course Title : Air and Sea Transport Infrastructure Design

Credits : 3

Objective(s) : The objectives are to ensure that students will understand air transport and se transport facilities.

Syllabi : Air transport. Airport classification, airport location, airport configuration, airside facility infrastructure, landside facility infrastructure, determining direction and runway numbering, declared distances (TORA, TODA, ASDA, LDA), physical obstacles (conical surface, inner horizontal surface, approach surface, transitional surface, balked landing surface, take off climb surface); landing area geometric design (runway, taxiway and apron), air craft parking system, navigation aids.

Sea Transport: definition of ship, harbour and port. passenger terminal design, dockside, terminal for conventional general cargo, bulk freight terminal, bulk dry freight terminal, container terminals.

References : Molenaar, AAA, 1983. Structural Performance and Design of Flexible Road Construction and Asphalt Concrete Overlays, TU Delft. David Croney D., 1977. The Design and Performance of Road Pavement, TRRL London. The Asphalt Institute MS-I, 1970 : AC No.150/5320 – 6D Airport Pavement Design and Evalution. AASHTO, 1986, Guide for Design of Pavement Structures, AASHTO, Washington D.C. ………., 2000, Referensi Kepelabuhanan Seri 1 – 11, PT. Pelabuhan Indonesia.

25. Course Title : Road and Rail Transport Management

Credits : 2

Objective(s) : The objectives are to ensure that students will understand management strategies for highway and railway infrastructure.

Syllabi : Highway management strategies: basic concept, basic soncept of road network performance, Road network hierarchy. Indicator and standard pavement performance (structural and functional). Basic concept of public transport performance. Basic concepts of freight tranport network performance: indicators and standard of fright transport network performance,. Basic theory of traffic engineering: link and junction capacities; parking capacity (on – off street parking); road network accessibility theory. Traffic management basic concept: demand management; supply management. Sstrategic management system for public road transport: public transport network (passengers); Freight transport network; Terminal (passengers and goods); road network, link and junction.

Railway management strategies: railway network hierarchy; railway transport technology (conventional train, Maglev, monorail); Railway trace capacity; indicator and standard of trace performance and railway track); factors influencing decreasing train station performance (emplacement). Basic concept of railway maintenance management. Maintenance for railway components: rail (type of deterioration, controlling and rehabilitation methods); railway tie (type of deterioration, controlling and rehabilitation methods); Balast (type of deterioration, controlling and rehabilitation methods); railway

18

bed (type of deterioration, controlling and rehabilitation methods). Improvement strategy for railway trace and track: capacity improvement, improvement the railway track quality. Train station: Basic concept of train station; Indicator and standars of train station, management and development strategies of train station performance. Fare system of train: railway operation cost, fare policy in accordance to level of service and demand.

References :

26. Course Title : Manajemen Transportasi Udara dan Laut

Air and Sea Transport Management

Credits : 2

Objective(s) : The objectives are to ensure that students will understand demand analysis, operational analysis of air transport and sea transport; and also capacity concepts of capacity.

Syllabi : Air Transport Management: Demand analysis: air transport forecast (passenger and aircraft); demand management: runway capacity (saturation capacity, practical hourly capacity, sustain capacity, declared capacity); operational analysis: factors influencing the capasity of runway system, peak hourly movement; passenger handling concept; aeronautical and non aeronautical.

Sea Transport Management Sea transport and comodities (demand analysis); nautical aspects of port planning (demand management); operational analysis: conventional general cargo terminal management, bulk terminal management, dry bulk terminal management, container terminal management.

References :

27. Course Title : Road and Bridge Planning and Design

Credits : 3

Objective(s) :

Syllabi : The concept of road and bridge planning and design, Construction steps of road and bridge infrastructure (design location in the step): pre FS, FS, DED, construction, post-construction (operation-maintenance). Road trail and bridge selection analysis, Road and bridge form design with environmental sustainability by prioritizing the principles of safety, Horizontal alignment design application, Vertical alignment design application. Road picture (3D), Grade separated intersection design, Road complementary building (bridge, culvert, road drainage channel), SIDLACOM (Survey, Investigation, Design, Land Acquisition, Construction, Operation and Maintenance)

References : AASHTO, 2004, A Policy on Geometric Design of Highways and Streets, USA Austroads, 2003, Rural Road Design, A Guide to the Geometric Design of Rural Roads, Australia. Banks, J. H., 2011, Introduction to Transportation Engineering, McGrawHill, New York. Departemen Pekerjaan Umum, 1992, Standar Perencanaan Geometrik untuk Jalan Perkotaan, Direktorat Jenderal Bina Marga.

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Departemen Pekerjaan Umum, 1997, Tata Cara Perencanaan Geometrik Jalan Antar Kota, Direktorat Jenderal Bina Marga. Departemen Pekerjaan Umum, 1997, Manual Kapasitas Jalan Indonesia, Jakarta Oglesby, C.H. and Hicks, R.G., 1982, Highway Engineering, John Wiley & Sons, New York. Peraturan Pemerintah No. 34 tahun 2006 Pd T-18-2004-B Penentuan Klasifikasi Fungsi Jalan di Perkotaan Schoon, J.,G., 2000, Geometric Design Projects for Highways, ASCE Press, Virginia. South African National Roads Agency Limited, 2001, Pretoria. Wright, P.H., 1996, Highway Engineering, John Wiley & Sons, New York Undang-Undang No. 22 tahun 2009 tentang Lalu Lintas dan Angkutan Jalan Raya Undang-undang No. 38 Tahun 2004 tentang Jalan

28. Course Title : Road Management System

Credits : 3

Objective(s) :

Syllabi : Road asset management concepts, Road damage types, Road damage factors, Monitoring and evaluation methods of road structural strength, Road maintenance methods, Road condition monitoring and evaluation, Road function feasibility tests (technical and administrative), Road assistance priority levels arrangement.

References : Molenaar, AAA, 1983. Structural Performance and Design of Flexible Road Construction and Asphalt Concrete Overlays, TU Delft. David Croney D., 1977. The Design and Performance of Road Pavement, TRRL London. The Asphalt Institute MS-I, 1970 : AC No.150/5320 – 6D Airport Pavement Design and Evalution. AASHTO, 1986, Guide for Design of Pavement Structures, AASHTO, Washington D.C.

29. Course Title : Bridge Management System

Credits : 2

Objective(s) :

Syllabi : Bridge spans and shapes, Bridge components and their functions (upper, lower, base and auxiliary buildings, and bridge safeguard), Bridge damage types and causes, Bridge functions feasibility assessment (inventory, routine, detailed, and special inspections), Bridge management information systems and bridge condition assessment, Determination of the remaining bridge capacity value, Bridge condition monitoring, Bridge evaluation procedures (upper and lower buildings), Methods of maintenance, reparation, reinforcement/improvement and bridge replacement.

References : Ditjen Bina Marga, 1993, Sistem Manajemen Jembatan: Panduan Prosedur Umum IBMS, Departemen Pekerjaan Umum, Republik Indonesia Ditjen Bina Marga, 2011, Manual Pemeliharaan Jembatan, Departemen Pekerjaan Umum, Republik Indonesia Austroads, 2002, Bridge Manajement Systems: the State of the Art, Austroads, Australia

20

MASTER OF ENGINEERING IN NATURAL DISASTER MANAGEMENTSYLLABI

i

TABLE of CONTENS

1. Research Metodology ........................................................................................................................... 1

2. Data Processing Techniques ................................................................................................................. 1

3. Landslide and Ground Movement ...................................................................................................... 2

4. Waves and Tsunami .............................................................................................................................. 3

5. Volcanology ........................................................................................................................................... 4

6. Applied Hydrology and Hydraulics ........................................................................................................ 4

7. Information System on Natural Disaster .............................................................................................. 5

8. Assessment of Damage and Loss in Natural Disaster ........................................................................... 6

9. Flood and Debris Flow ........................................................................................................................... 6

10. Flood Early Warning System ............................................................................................................. 7

11. Drought, Flood, and Debris Flow Risk Mitigation ............................................................................. 8

12. Earthquake Dynamic ......................................................................................................................... 9

13. Landslide Early Warning System ....................................................................................................... 9

14. Earthquake Risk Mitigation ............................................................................................................. 10

15. Volcanic Eruption and Sedimentology ............................................................................................ 11

16. Volcanic Disaster Early Warning System ......................................................................................... 11

17. Volcanic Disaster Risk Mitigation .................................................................................................... 12

18. Pyroclastic Flow Model ................................................................................................................... 12

19. Natural Disaster Emergency Management ..................................................................................... 13

20. Disaster Risk Mitigation Community Development Base ............................................................... 13

21. Integrated Coastal Area on Disaster Management ........................................................................ 14

22. Field Training ................................................................................................................................... 15

23. Thesis .............................................................................................................................................. 16

1

1. Research Metodology

Credits: 2

Research processes and steps, signs, terms and condition in research. Research stages and cycles.

Procedure of reference searching and schedule settings. Research preparation, research topic

selection, research proposal preparation, research report writing, and paper writing.

Action research, problems and case studies, hypotheses, case study design, data processing,

optimization methods, result interpretation, research presentation, application of research

methodology, introduction to decision support systems. Preparation of thesis research proposals.

References

1. Hira, D.S., 2008. Operations Research, S. Chand Publishing.

2. Leedy, P. D., 1997. Practical Research, Planning and Design. Prantice Hall, New Jersey.

3. Sri Harto Br, 2011. Metodologi Penelitian; Prinsip Penelitian dan Penulisan. Pegangan

kuliah.

Learning methods: classical (face to face), discussion, and practice.

Assessment methods: assignments and examinations.

2. Data Processing Techniques

Credits: 3

General understanding of statistics, statistical unit, data presentation, probability, random

variables, probability distribution, range of beliefs, hypothesis testing, regression and

interpolation, correlation, frequency analysis, data generation, time series data analysis,

introduction of statistical program software packages and numerical analysis.

Reference

1. Crewson, P., 2006. Applied Statistics Handbook.

2. de Smith, M.J., 2014. Statistical Analysis Handbook, a web-based statistics resource. The

Winchelsea Press, Winchelsea, UK.

3. Haan, Charles T., 2002. Statistical Methods in Hydrology, 2ndEd., The Iowa State Univ.

Press, Ames, Iowa, USA.

4. Kottegoda, N.T. and Rosso, R., 2008. Applied Statistics for Civil and Environmental

Engineers, ISBN: 978-1-405-17917-1.

Learning methods: classical (face to face), discussion, and tutorial / training on statistical

program software packages and numerical analysis using data collected from natural disaster

phenomena, and exercises.

Assessment methods: quiz, assignments and examinations.

2

3. Landslide and Ground Movement

Credits: 2

Definition of landslides and land movements,

Geological and rock aspects,

Earth and tectonic evolution (faults, folds, joints and other structures),

geological map,

preliminary stages,

classification and description of land and rocks in the field of engineering,

topography and geology of landslides and their formation process,

the influence of ground water,

geotechnical investigations in landslide areas,

classification and mechanism of soil movement processes,

causes of ground motion (control and trigger factors of ground motion),

slope stability and rock slope kinematic analysis (stereographic projection),

design of landslide prevention techniques,

predictions of landslides,

method of vulnerability mapping (spatial prediction),

introduction to land movement risk reduction,

landslide disaster management from social aspect,

integrated landslide disaster management.

References

1. Cornforth, D. H., 2005. Landslide in Practice: Investigation, Analysis, and

Remedial/Preventative Options in Soils, John Wiley & Sons.

2. Hunt, R. E., 2007. Geologic hazards : a field guide for geotechnical engineers, CRC Press

Taylor & Francis Group 6000 Broken Sound Parkway NW, ISBN 1‑4200‑5250‑0.

3. Lee, E. M., 2005. Landslide Risk Assessment, Thomas Telford Ltd.

4. Nakamura, H. and Higaki, D, 2004. Landslides, Handbook for Master Programme in

Natural Disaster Management, GMU.

5. SNI 03-1962-1990: Tata cara perencanaan penanggulangan longsor dan SKBI-2.3.1987:

Lampiran A dan Lampiran B.

Learning methods: classical (face to face), discussion, and practice.

Assessment methods: examinations.

3

4. Waves and Tsunami

Credits: 2

a. Waves

Linear wave and long wave theory, non linear wave. Long wave length, particle velocity and

propagation and deformation. Tsunami wave propagation velocity, tsunami speed, tsunami

behavior in various shoreline forms. Long wave forces on building.

b. Tsunami

History of tsunami events in the world and in Indonesia, statistics of tsunami events. Distribution

of tsunami prone areas in Indonesia. Run up, run down, reflect, and focus of tsunami waves.

c. Tsunami generation mechanism

Tsunami generation by earthquakes, avalanches and volcanic eruptions. Models and simulations

of tsunami wave generation and propagation.

d. Tsunami forces and effects on land

Tsunami force on vertical walls, tsunami force on a pillar, tsunami force in a porous building,

tsunami force in a protected building, effectiveness of forest barriers to tsunamis, tsunami force

with debris.

e. Tsunami mitigation

The concept of tsunami disaster mitigation (in terms of structure-building, building layout and

tsunami safe neighborhood), evacuation routes and evacuation sites, early warning system.

f. Tsunami preparedness

Factors influencing tsunami preparedness, tsunami disaster preparedness development model,

tsunami disaster risk calculation.

References

1. Bozorgnia, Y. and Bertero, V. V., 2004. Earthquake Engineering from Engineering

Seismology to Performance – Based Engineering, CRC Press Inc.

2. CERC, 2006. Coastal Engineering Manual, US Army.

3. Dean, R. G. and Robert, A.D., 2001. Coastal Processes with Engineering Applications,

Cambridge University Press.Triatmadja (2010), Tsunami, Pembangkitan, Penjalaran,

Daya rusak dan Mitigasinya, Gadjah Mada University Press.

4. Gadallah, M. R. and Fisher, R. L., 2004. Applied Seismology, A Comprehensive Guide

to Seismic Theory and Application, Pennwell Corp.

4

5. Veitch. N., Jaffray.G., 2008. Tsunamis, Causes, Characteristics, Warnings and Protection,

Nova.

Learning methods: classical (face to face), discussion, tutorial and field visit.

Assessment methods: assignments and examinations.

5. Volcanology

Credits: (2 credits)

Definition of volcanoes, spatial distribution of volcanoes. Volcanoes in Indonesia and the world.

Tectonics and volcanism, magma formation, physical properties of magma. Volcano seismicity.

Eruption classification, effusive and explosive eruption processes and products. Hazard and risk

volcanology. Monitoring and mitigation techniques. Control and construction of infrastructure in

the volcano area. Sabo system and mix design. Monitoring technique and evacuation

mobilization.

References

1. Institute of Seismological Research, 2008. Earthquake Monitoring and Seismicity

Patterns, Department of Science & Technolo.y, Government of Gujarat, Annual Report.

2. Marty, J., dan Ernst, G., 2005. Volcanoes and The Environment, Cambridge University

Press 0521592542.

3. SNVT Merapi, 2005. Manual on Soil Cement Sabo Dam, Yogyakarta.

Learning methods: classical (face to face), discussion, and field visit.

Assessment methods: examinations

6. Applied Hydrology and Hydraulics

Credits: 3

Hydrology and hydraulic analysis are the first steps in planning and operating infrastructure for

natural disaster management. Hydrology analysis includes analysis of the elements of the

hydrologic cycle and the rainfall-runoff transformation process starting from rainfall data until

flood design. The rainfall-runoff transformation analysis includes: rainfall analysis, abstraction

analysis / loss / runoff volume, transform analysis of effective rainfall into direct runoff

hydrograph using measured and synthetic unit hydrograph method, baseflow and flood routing

and flood design analysis.

Understand open channel flow. Use of flow equations in flow analysis through hydraulic

buildings, specific energy, momentum and uniform flow. Effect of channel roughness, channel

slope, hydraulic building on flow profiles in channels / rivers, non uniform flow. References to

this course still use reference points 1. (English version).

5

References

1. Rosalina, E.V.N., Sianipar, Y. (Penerjemah), 1992. Hidrolika Saluran Terbuka (Chow, V.

T., 1973. Open-channel Hydraulics, McGraw-Hill, New York), Terjemahan Bahasa

Indonesia, Erlangga.

2. Chow, V. T., Maidment, D. R. and Mays, L. W., 2013. Apllied Hydrology, 2nd Ed.,

McGraw-Hill.

3. Mimikou, M.A., Baltas, E.A., Tsihrintzis, V.A., 2016. Hydrology and Water Resources

Systems Analysis, CRC Press.

4. Sri Harto, B., 2000. Hidrologi: Teori, Masalah, Penyelesaian, Nafiri, Yogyakarta.

Learning methods: classical (face to face), discussion, and software exercise on hydrological

and hydraulic simulation (Easyfit, ANGGREK, HEC-HMS, HEC-RAS).

Assessment methods: examinations

7. Information System on Natural Disaster

Credits: 2

Introduction to disaster information systems. Types of disaster information systems related to

each stage of the natural disaster cycle.

Types of basic maps, acquisition, and the understanding (satellite / image maps, topographic

maps), basic mapping (implementation and processing techniques), spatial information

presentation (types, scale, usage), risk modelling, preparation and presentation of hazard

mapping (hazard map) and risk mapping (risk map), and other spatial informations (especially

vulnerability map; population density, disaster management infrastructure, public facility, etc).

Regional information system (incuding spatial information system and natural resources), e.g.

Province and Regency profile, matery and types of information, relationship between

information and disaster management, comprehensive watershed information, potency of

identified sectors, master plan for developing various sectors and their integration, information

about regional action plans on integrated disaster risk management and GIS application

(desktop/Web/Mobile application) on supporting activities before and after disaster (evacuation

information system, early warning, disaster risk visualization, damage and losses reporting

through web technology).

References

1. ESRI, 2006. GIS and Emergency Management in Indian Ocean Earthquake/Tsunami

Disaster, ESRI, Redlands, CA.

2. Laituri, M., and Kodrich, K., 2008. On Line Disaster Response Community: People as

Sensors of High Magnitude Disasters Internet GIS, Sensors, 8, 3037-3055.

3. Longley, P. A., Goodchild, M. F., Maguire, D. J., and Rhind, D. W., 2005. Geographic

Information Systems and Science, John Wiley & Sons., Sussex.

4. McDonald, B., and Gordon, P., 2008. United Nations’ Efforts to Strengthen Information

Management for Disaster Preparedness and Response, Data Against Natural Disasters, S.

Amin and M. Goldstein, eds., World Bank, Washington, 59-82.

6

5. Rao, R.R.; Eisenberg, J. and Schmitt, T. (eds)., 2007. Improving Disaster Management:

The Role of IT in Mitigation, Preparadness, Response, and Recovery, The National

Academic Press, Washington DC.

Learning methods: classical (face to face), discussion, exercise, and presentation.

Assessment methods: assignments and examinations

8. Assessment of Damage and Loss in Natural Disaster

Credits: 3

Vulnerability and susceptibility is the main factor on risk level assessment of a building towards

natural disaster, hazard level, rapid visual screening of vulnerability and susceptibility and detail

evaluation. Components of infrastructure and application of vulnerability and susceptibility

analysis for both visual screening and detail evaluation by using available guidelines.

References

1. FEMA-154, 2002, Rapid Visual Screening of Building for Potential Seismic Hazards: A

Handbook, Second Edition, Applied Technology Council, 555 Twin Dolpin Drive, Suite

550 Redwood City, California 94065.

2. FEMA-310, 1998. Handbook for the Seismic Evaluation of Buildings, Federal

Emergency Management Agency, USA.

3. IBRD, 2010. Damage, Loss and Needs Assessment, Guidance Notes Vol. 1, 2, 3.

4. Kelly, T. E., 2001. Performance Based Evaluation of Buildings, Reference Manual

Holmes Consulting Group, Ltd.

5. Perka BNPB Nomor 15 Tahun 2011 Tentang Pedoman Pengkajian Kebutuhan Pasca

Bencana.

6. Robinson, J., Phillips, W., 2014. Assessment of strategies for linking the damage and loss

assessment methodology to the post-disaster needs assessment, UN-ECLAC.

Learning methods: classical (face to face), discussion, exercise, and field visit trying to evaluate

infrastructure by using rapid visual screening method.

Assessment methods: quiz, assignments and examinations.

9. Flood and Debris Flow

Credits: 3

Understanding of process and perception of stakeholders related to flood. Basic principal of

integrated flood management, conventional flood control, comprehensive-multisector of

structural and non-structural flood measures. Flood monitoring, flood management, flood risk,

flood modelling, flood forecasting and early warning system, flood mapping by GIS, institutional

aspects, evaluation and analisys, software application (HEC-HMS, HEC-RAS, FDA).

7

Type, magnitude, and location of sediment, sediment transport mechanism, positif and negatif

impact of sediment supply phenomenon, Sabo Dam, legal aspect of sediment mitigation and

utilization, strategies and operational of integrated sediment mitigation, community development

about activities related to land use and river resources management, river quality management,

practice of sediment transport monitoring and evaluation both naturally and due to human

intervention, analysis or river sediment balance based on mass konservation concept.

Hydrodynamic of sedimentary liquid, properties of sediment material, debris-flow initial motion,

transpor mechanism, bed-load, suspended-load, total-load, stable channel, scour, sediment

measurement, dam sedimentation, debris-flow types, debris flow distribution, debris flow

deposit, degradation and agradation, debris-flow transport, rough material movement, structures

of debris-flow wave, debris flow prediction, disaster prevention due to debris-flow, flood control

due to debris-flow, sediment balance, monitoring system and data acquition of debris flow, and

flood monitoring.

References:

1. Anonim, 2007. Pedoman Penanggulangan Bencana Banjir, BAKORNAS PB, Jakarta.

2. ASTM, 2002. Erosion and Sediment Control Technology Standard, ASTM Standard.

3. Carlos E.M. Tucci, 2007. Urban Flood Management, Cap-Net.

4. Kourgialas, N.N., KaratZas, G.P., Flood management and a GIS modelling method to

assess flood-hazard areas—a case study, 2011, Hydrological Sciences Journal, Vol. 56 –

Issue 2, Taylor & Francis On-line.

5. Nakatani, K., Wada, T., Matsumoto, N., Satofuka, Y., Mizuyama, T., 2011. Development

and Application of GUI Equipped 1-D And 2-D Debris Flow Simulator, Applied to

Mixed-Size Grains, Padua, Italy. Proc. of 5th International Conference on Debris-Flow

Hazards Mitigation: Mechanics, Prediction and Assessment, pp. 735-744.

6. Stancalie, G, Alecu, C., Catana, S., 2000. Flood Hazard Assessment and Monitoring

using Geographic Information, Remotely Sensed Data, International Archives of

Photogrammetry and Remote Sensing, Vol. XXXIII, Part B7, Amsterdam.

7. Takahashi, T, 2007. Debris Flow, Mechanics, Prediction and Countermeasures, Taylor &

Francis.

Learning methods: classical (face to face),tutorial, discussion, exercise, and field visit.

Assessment methods: Assigenments and case studies of floods and lava flows by using rainfall-

runoff models and hydraulic models that are suitable for lava flow analysis, exams.

10. Flood Early Warning System

Credits: 3

Flood early warning system development concept, vulnerable system, flood risk (inundation,

errotion, levee break), flood disaster prediction, flood parameter, mitigation action, early warning

system objective, early warning system instrumentation, method and instrument of early warning

system, censor typical, transformation and distribution system of flood early warning system

8

information, urban drainage system and flood area, example of development, application and

evaluation result of early warning system: Code and Bengawan Solo River Basin.

References:

1. Adiel, P.W., 2014. Pembuatan Perangkat Lunak Untuk Mendukung Pengendalian Banjir

DAS Bengawan Solo Hulu. Tesis Program Magister Pengelolaan Bencana Alam UGM,

Yogyakarta.Zschau, J. and Kuppers, A.N., 2003. Early Warning Systems for Natural

Disaster Reduction, Springer-Verlag Heidelberg New York.

2. Australian Emergency Manual Series Manual 21, 2009. Flood Warning.

3. Feldman, A.D., 2000. Technical Reference Manual of Hydrologic Modeling System

HEC-HMS. HQ US Army Corps of Engineers, Washington DC.

4. Gemala Suzanti, 2011. SOP Penanganan Banjir Wilayah Sungai Bengawan Solo.

5. ISDR Platform for The Promotion of Early Warning, 2006.

6. Nayak, S. and Zlatanova, S., 2008. Remote Sensing and GIS Technologies for

Monitoring and Prediction of Disasters, Springer-Verlag Berlin Heidelberg.

7. Scharffenberg, W.A., 2013. Hydrologic Modeling System HEC-HMS: User’s Manual,

U.S. Army Corps of Engineers, HEC, Davis, CA.

Learning methods: classical (face to face), tutorial, discussion, exercise, and field study.

Assessment methods: quiz, assignment, exams.

11. Drought, Flood, and Debris Flow Risk Mitigation

Credits: 3

Characteristic, caused, risk and impact of drought disaster, flood and debris flow. Analysis of

drought index/magnitude assesment. Structural and non-structural mitigation plan of drought,

flood disaster and debris flow (contingency plan, organization-constitutional-coordination and

action plan).

References

1. Buku Teknik Sabo, Ditjen SDA, 2011, Jakarta.

2. Donald W. Knight, Assad Y. Shamseldin, 2005. River Basin Modelling for Flood Risk

Mitigation, Taylor & Francis Group, Singapore.

3. Giuseppe Rossi, Theodoro Vega, Brunella Bonaccorso, 2007. Methods and Tools for

Drought Analysis and Management, Springer, Dordrecht, The Netherland.

4. Pedoman Penanggulangan Banjir, 2007, Bakornas Penanggulangan Bencana, Jakarta.

5. Peraturan Kepala BNPB Noor 4 Tahun 2008 Tentang Pedoman Penyusunan Rencana

Penanggulangan Bencana.

Learning methods: classical (face to face), discussion, exercise, and field study.

Assessment methods: assignment, exams.

9

12. Earthquake Dynamic

Credits: 3

Earthquake definition, earthquake intensity, magnitude, seismicity, atenuation, earthquake-zone.

Earthquake mechanism, tectonic-plate theory, earthquake centre distribution. Seismic waves,

type of seismic waves. Reflection and refraction of earthquake waves. Ground vibrations:

ground-vibrations theory, soil-structure interaction. Earthquake magnitude, seismic wave

distribution, seismic wave acceleration, velocity and energy of seismic waves. Earthquakes in the

world and in indonesia, earthquake zone worldwide and in Indonesia, earthquake history, impact,

and measurement. Building structural vibration, impact of ground acceleration to the building.

Earthquake disaster mapping, failure due to earthquake, evaluation of level and failure type,

distribution and area, definition of earthquake scale and the interpretation. Liquifaction theory

and structural strengthening and retrofitting to liquifaction.

Design concept of earthquake-resistant structure, dynamic structure response, introduction to

material characteristic, strength, stiffness, and dactility, caused and impact of earthquake to the

structure, type of buildings structural system (bearing & shear wall, rigid fram, F+SW), concept

earthquake-resistant building (concept of “strong colum-weak beam”, soft-story, short column

effect, tortion, mechanism of structural failure), failure and caused of buidling collapse due to

earthquake, non-engineered structures and engineered structures building, structure dactility for

earthquke-resistant building, strengthening and retrofitting of building collapse due to

earthquake.

References

1. Chen, W. F. and Scawthorn, C., 2002. Earthquake Engineering Handbook (New

Directions in Civil Engineering), CRC Press Inc.

2. Chen, W. F., 2005. Earthquake Engineering for Structural Design, CRC Press Inc.

3. Departemen PU, 2002. Standar Perencanaan Ketahanan Gempa untuk Struktur Bangunan

Gedung SNI-1726, Dep. PU.

4. Stein, S. And Wysession, M., 2003. An Introduction to Seismology, Earthquake, and

Earth Structure, Black Well Publishing.

5. William, H.K.L., Kanamori, H., Jennings, P.C., and Kisslinger, C., 2002, International

Handbook of Earthquake and Engineering Seismology, Part A, Academic Press, London,

UK.

Learning methods: classical (face to face), discussion, tutorial, exercise, and field study.

Assessment methods: assignment and exams.

13. Landslide Early Warning System

Credits: 3

Introduction to risk reduction of land slide which includes technically effort and management

(prediction and prevention, monitoring system, early warning system and data acquisition, and

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slope stability improvement), landslide and ground movement monitoring technology,

monitoring design and landslide early warning on ground movement types, warning criteria

(impact of geomorphology, rainfall,, groundwater fluctuation, geology-geotechnic condition to

the landslide initiation), hazard mapping and prediction of landslide disaster, monitoring system

and data acquisition for lanslide and ground movement.

References:

1. Cornforth, D. H., 2005. Landslide in Practice: Investigation, Analysis, and

Remedial/Preventative Options in Soils, John Wiley & Sons.

2. Lee, E. M., 2005. Landslide Risk Assessment, Thomas Telford Ltd.

3. Nakamura, H. and Higaki, D, 2004. Landslides, Handbook for Master Programme in

Natural Disaster Management, GMU.

4. Sassa, K. and Canuti, P, 2008. Landslides: disaster risk reduction, Springer.

Learning methods: classical (face to face).

Assessment methods: exams.

14. Earthquake Risk Mitigation

Credits: 3

Many infrastructure failure and fatalities have been caused by earthquake disaster. The history of

earthquake disasters in Indonesia and in the worldwide could become lesson learnt for risk

mitigation of earthquake disaster in the future. Disaster risk could be explained by threat and

vulnerability. Earthquake mitigation processes could be done by understanding these two factor.

Basically, every disaster have lifecycle that is divided into four step; disaster reduction,

preparedness, emergency response, and rehabilitation and reconstruction. Success of earthquake

disaster mitigation program depends on application process of every program in every step.

References

1. BNPB, 2008. Peraturan Kepala Badan Nasional Penanggulangan Bencana Nomer 4

Tahun 2008 Tentang Pedoman Penyusunan Rencana Penanggulangan Bencana, Badan

Penanggulangan Bencana (BNPB).

2. Chen, W. F. and Scawthorn, C., 2002. Earthquake Engineering Handbook (New

Directions in Civil Engineering), CRC Press Inc.

3. FEMA 172, 1992. NEHRP Handbook of Techniques for the Seismic Rehabilitation of

Existing building, Building Seismic.

4. FEMA 310, 1998. Handbook for the Seismic Evaluation of Buildings, Federal

Emergency Management Agency, USA.

5. FEMA 154, 2002. Rapid Visual Screening of Building for Potential Seismic Hazards: A

Handbook, Second Edition, Applied Technology Council, 555 Twin Dolpin Drive, Suite

550 Redwood City, California 94065.

6. Hunt, R.E., 2007, Geologic Hazard: A Field Guide for Geotechnical Engineers, CRC

Press, Taylor and Francis Group.

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7. SNI-1726, 2002. Standar Perencanaan Ketahanan Gempa untuk Struktur Bangunan

Gedung SNI-1726, Dep. PU.

8. Wyss, M. and Snroder, J.F., 2014, Earthquake Hazard, Risk, and Disasters, Elesevier Inc.

USA.

Learning methods: classical (face to face), discussion, presentation

Assessment methods: assignment and exams.

15. Volcanic Eruption and Sedimentology

Credits: 3

Volcanic eruption and deposit forming around it, I of eruption activity to hydrothermal

phenomennon or air heating around also initial flora and fauna life, volcanic material influence

toward formation of field surface around, volcanic material production and industry, volcano and

economic benefit, deposit variability and influence of social and culture people around it.

References

1. Institute of Seismological Research, 2008. Earthquake Monitoring and Seismicity

Patterns, Department of Science & Technology, Government of Gujarat, Annual Report.

2. Marty, J., dan Ernst, G., 2005. Volcanoes and The Environment, Cambridge University

Press 0521592542.

Assessment method: Practice

Tutorial and workshop

16. Volcanic Disaster Early Warning System

Credits: 3

Magma movement indentification, tectonic activity, summit surface deformation and lava dome

forming, pyroclastic heap stability, material rainfall phenomenon (rock, sand and volcanic ash),

volcanic material characteristic, volcanic material mechanism migration, eruption coloumn

dynamic (magma pipe forming, growth and magma filling), basaltic flow dynamic characteristic,

volcanic processes model on earth, interaction between volcanic and techtonic phenomenon.

Related research topic: consequences of volcanic activity and spatial-temporal activity of the

volcanic system also the aplication to the risk handling and model of infrastructure response,

physical proces related to the basaltic material behaviour (pyroclastic cloud formation, material

rainfall, etc), eruption modelling.

References

1. Early Warning Sub-committee of the IMC ICDR Govt. of Japan, 2006. Japan’s Natural

Disaster Early Warning Systems and International Cooperative Effort.

2. Lopes, R., 2005. The Volcano Adventure Guide, Cambidge University Press.

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3. Van Geffen, J., van Roozendael, M., di Nicolantonio, W., Tampellini, L., Valks, P.,

Erbetseder, Th., and van der A, R., 2007. Monitoring of Volcanic Activity from Satellite

as Part of GSE Promote, Proceedings of the ENVISAT Symposium, 23–27 April 2007,

Montreux, Switserland, ESA publication SP-636.

4. http://www.geology.buffalo.edu/research/volcanostudies.shtml#1



17. Volcanic Disaster Risk Mitigation

Credits: 3

Magma movement indentification, tectonic activity, summit surface deformation and lava dome

forming, pyroclastic heap stability, material rainfall phenomenon (rock, sand and volcanic

ash),vulcanic material characteristic, vulcanic material mechanism migration, eruption coloumn

dynamic (magma pipe forming, growth and magma filling), basaltic flow dynamic characteristic,

volcanic processes model on earth.

References

1. Conway, A., 2013, Hazard: The Extinction Protocol Guide to Risk Mitigation, Lulu

Publishing, Morrisville.

2. Dietr Rickenmann and Cheng-ling Chen, 2003. Debris Flow Hazard Mitigation:

Mechanism, Prediction, and Assessment, Vol. 1, Millpress Rotterdam Netherlands.

3. Wang, F., Miyajima, M., Li. T., Shan, W., and Fathani, T.F., 2012, Progress of Geo-

Disaster Mitigation Technology in Asia, Springer Science & Business Media.

4. Tassi, F., Vaselli, O., and Caselli A.T., 2015, Copahue Volcano, Springer.



18. Pyroclastic Flow Model

Credits: 2

Pyroclastic flow hydraulic concept, pyroclastic flow dynamic equation development, pyroclastic

flow model.

References

1. Branney, M.J. and Kokelaar, B.P., 2002, Pyroclastic Density Currents and The

Sedimentation of Ignimbrites, Geological Society of London.

2. Dietr Rickenmann and Cheng-ling Chen, 2003. Debris Flow Hazard Mitigation:

Mechanism, Prediction, and Assessment, Vol. 1, Millpress Rotterdam Netherlands.

3. Fagents, S.A., Gregg, T.K.P., and Lopes, R.M.C., 2013, Modeling Volcanic Processes:

The Physics and Mathematics of Volcanism, Cambridge University Press.

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19. Natural Disaster Emergency Management

Credits: 2

Coordination and comunication technique among instantions, evacuation hierarchy and early

warning facillities, applied decission support system (PiC, Key person and group leader),

refugees management (logistic, health, and information flow), applied decision support system.

References

1. Anonim, 2008. Standar Sistem Manajemen Keadaan Darurat, Panduan Instruktur,

Kepolisian Republik Indonesia, Departemen Luar Negeri A.S., Departemen Kehakiman

A.S., International Criminal Investigative Training Assistance Program (ICITAP),

Jakarta.

2. Brassard, C., Giles, D.W., and Howitt, A.M., 2014, Natural Disaster Management in the

Asia-Pacific: Policy and Governance, Springer.

3. Collins, L.R., 2000, Disaster Management and Preparedness, CRC Press.

4. Farazmand, A., 2001, Handbook of Crisis and Emergency Management, CRC Press.

5. Pinkowski, J., 2008, Disaster Management Handbook, CRC Press.

Practice work

Workshop on Standard System Management of Emergency for Disaster Management

20. Disaster Risk Mitigation Community Development Base

Credits: 2

Community development and empowerment in water and disaster management, collective

authority policy, social problem resolve trough organizational, authority and community

development, encouraging and defending community activity, social action model, social

product model, community modernization, community management, community education

(informal education), community awareness and willingness building, community confidence

and participation building. Develop new tradition: living harmony with natural

disaster/environment, planning and strategy on natural disaster anticipation.

Students are provided with knowledge and practice to have ability to educate community through

community development and/or writing ability on the public media mass related to disaster

mitigation.

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References

1. Davis, I., 2014, Disaster Risk Management in Asia and the Pacific, Routledge.

2. Herbert J. Rubin, 2000. Community Organizing and Development, Allyn&Bacon.

3. Ledwith, M., 2005. Community Development: A Critical Approach, Policy Pr.

4. Shaw, R., 2012, Community-Based Disaster Risk Reduction, Emerald Group Publishing.



21. Integrated Coastal Area on Disaster Management

Credits: 2

1. Introduction

Coastal area definition, and coastal area disaster, wind wave theory and tidal wave, coastal

currents, sediment transport, errotion, accretion and abration, pollutants difusion (oil, sediment,

urban waste, etc), wind set up, wave set up.

2. Coastal area management

Definition of coastal management, protection and development, reclamation, dredging and its

impact.

Coastal management concept, coastal management aspect. Case study (Jakarta Giant Sea Wall).

Tsunami, sea level and tropical storm, natural defense damage (bakau, dunes) and conservation,

early warning system, Public Work mitigation plan.

3. Erosion, Abration, Accretion

Erosion, abration, accretion protection

Wave protection,

Silting estuary

Appropriate solution

4. Inundation (Rob)

Protection from estuary flood

Protection from Sea Level Rise (SLR)

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5. Environment

Wave and tides prediction by using software, protection form pollution and damage to the

coastal environment, protection from negative impact of coastal development, protection from

sea water intrusion.

6. Tsunami and tides near the coastal

Protection from tsunami and tides near the coastal.

References

1. Beatley. T., Brower. D.J., Schawab. A.K., 2002. An Introduction to Coastal Zone

Management, 2nd Edition, Island Press.

2. CERC, 2006. Coastal Engineering Manual, US Army

3. Dean, R. G. and Robert, A.D., 2001. Coastal Processes with Engineering Applications,

Cambridge University Press.

4. Reeve, C., 2004. Coastal Engineering: Processes, Theory and Design Practice, Taylor &

Francis.

5. Zimmermann, Dean.R.G., Penchev. V., Verhagen. H.J., 2004. Environmentally Friendly

Coastal Protection, Springer.

Learning methods: classical (face to face), tutorial, exercise, and field study

Assessment methods: assignment, presentation and exams.

22. Field Training

Credits: 3

Introduction of policy definition and questionnaire preparation. Multi variable analysis,

qualification analysis, regression analysis. Field study case object is decided before, splitted into

several groups, field understading, field investigation, related to grand road map research,

integrated report preparedness which is presentated in seminar or workshop forum.

Students are expected to learn by doing in some of the institution that is related to disaster, e.g.

construction company, consultant, and government institution.

The position in which the student work should be as assisstent manager or decision maker level

related to disaster or technical officer responsible for designing and analyzing complex work.

Students are expected to learn from the experient of solving the problems by some consideration

based on scientific analysis and includes all aspects encountered in the field.

Field training should be done equal to 3 credits or about 4 working hours during 30 working

days.

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23. Thesis

Credits: 8

Giving provision to students on reviewing academic experience like action research related to

natural disaster which is oriented to comprehensive problem solving. Emphasizing in case study

with analysis procedure and structural and systematic review with theory provision which is

gained during lectures. Metodology development in thesis research action can be laboratory

facillities utillizing for physically model or indoor model (indoor laboratory or outdoor

laboratory works) mathematic (software application oriented) or field survey, depends on interest

and topics which already decided with advisor.

Documents

SYLLABI - tsipil.ugm.ac.idtsipil.ugm.ac.id/wp-content/uploads/2019/04/Tsipil-UGM-Syllabi.pdf · Bibliography : 1) Ditjen Dikti Depdiknas, 2001, Kapita Selekta Pendidikan Pancasila