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Val id through June 2004 Volume 71
ATICOURSES APPLIED TECHNOLOGY INSTITUTE
TECHNICALTRAINING(public & onsite)
SINCE 1984
Acoustic & Sonar Engineering Engineering & Data Analysis Radar, Missiles, Defense
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Hello Technical Professionals,
Applied Technology Institute (ATI) has been a premier independent provider of acoustic &sonar engineering, communication, defense, and space systems short coursessince 1984. Wedeliver the highest quality professional development training courses to NASA, DOD and
numerous commercial companies and contractors. Hands-on experts emphasize the bigpicture systems engineering perspective, illustrated with engineering design data and numericalexamples.
ATI seminars cover the latest methods, providing in-depth, comprehensive knowledgeand skills needed to advance your career. Our instructors are world-classdesign experts,carefully selected for their ability to explain advanced technology in a readily understandable
manner. They love to teach! Twenty-five are authors of leading textbooks, includingUnderwater Acoustic Modeling, A Friendly Guide to Wavelets, Applied Measurement Engineering,
GPS Technology, Fundamentals of Statistical Signal Processing, andMicrowave Remote Sensing.
This catalog includes upcoming open enrollment dates for many courses. The inside backcover shows the full range of topics we can teach at your location. Courses taught at your siteare economical when 8 or more people are interested in the subject. Our instructors average25years of industry experience and are able to tailor the presentation to your audience and theirspecific applications - in essence, customizing the course for you -at no added cost.
May I suggest - peruse our website (www.ATIcourses.com) for topics of interest. Then,
call us. We would welcome the opportunity to discuss your requirements and objectives. We candiscuss in detail how ATI can tailor a course (or several) for your organization. Our training trulyhelps you remain competitive in this changing world!
Very truly yours,
P.S. We would love to teach a course at YOUR SITE and tailor it to your audience at NOadditional cost to you. Please call us to discuss!
Applied Technology Institute12960 Linden Church Road
Clarksville, Maryland 21029
Tel 410-531-6034 Fax 410-531-1013
Toll Free 1-888-501-2100
www.ATIcourses.com
James W. Jenkins, Executive Director
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Table of Contents
Additional courses & dates listed at www.aticourses.com Vol. 71 3
Sonar & Acoustic EngineeringADVANCED UNDERSEA WARFARE . . . . . . . . . . . . . . . . . . . . . . . . Feb 9-12, 2004 . . . . . . . . . .Middletown, Rhode Island . . . . . . . . . .4
Mar 8-11, 2004 . . . . . . . . . .Silverdale, WashingtonDEVELOPMENTS IN MINE WARFARE . . . . . . . . . . . . . . . . . . . . . . Mar 8-11, 2004 . . . . . . . . . .Panama City, Florida . . . . . . . . . . . . .5
May 3-6, 2004 . . . . . . . . . . .Middletown, Rhode IslandMECHANICS OF UNDERWATER NOISE . . . . . . . . . . . . . . . . . . . . . June 22-24, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .6PRACTICAL SONAR SYSTEMS ENGINEERING . . . . . . . . . . . . . . . . Apr 5-8, 2004 . . . . . . . . . . .Middletown, Rhode Island . . . . . . . . . .7
SONAR PRINCIPLES & ASW ANALYSIS . . . . . . . . . . . . . . . . . . . Mar 8-11, 2004 . . . . . . . . . .Middletown, Rhode Island . . . . . . . . . .8June 7-10, 2004 . . . . . . . . .Silverdale, WashingtonSTRUCTURAL ACOUSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Apr 20-22, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . . .9SUBMARINES & THEIR COMBAT SYSTEMS . . . . . . . . . . . . . . . . . . Mar 22-24, 2004 . . . . . . . . .Middletown, Rhode Island . . . . . . . . .10UNDERWATER ACOUSTIC MODELING & SIMULATION . . . . . . . . . . . Apr 26-29, 2004 . . . . . . . . . .Middletown, Rhode Island . . . . . . . . .11VIBRATION & NOISE CONTROL . . . . . . . . . . . . . . . . . . . . . . . . . Feb 23-26, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .12
Radar/EW/Combat/GPS SystemsC4ISR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Apr 28-30, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .13ELECTRONIC WARFARE OVERVIEW . . . . . . . . . . . . . . . . . . . . . . . Mar 25-26, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .14FUNDAMENTALS OF RADAR TECHNOLOGY . . . . . . . . . . . . . . . . . . Jan 27-29, 2004 . . . . . . . . .Colorado Springs, Colorado . . . . . . . .15
May 26-28, 2004 . . . . . . . . .Solomons Island, MDFUNDAMENTALS OF ROCKETS & MISSILES . . . . . . . . . . . . . . . . . Dec 9-11, 2003 . . . . . . . . . .Dayton, Ohio . . . . . . . . . . . . . . . . . . .16
May 4-6, 2004 . . . . . . . . . . .Huntsville, AlabamaGPS TECHNOLOGY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Dec 8-11, 2003 . . . . . . . . . .Arlington, Virginia . . . . . . . . . . . . . . .17
May 24-27, 2004 . . . . . . . . .Cape Canaveral, FloridaIFF AND SSR BEACON IDENTIFICATION SYSTEMS . . . . . . . . . . . . Apr 13-15, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .18INTEGRATED COMBAT SYSTEMS . . . . . . . . . . . . . . . . . . . . . . . . . Apr 20-22, 2004 . . . . . . . . . .Middletown, Rhode Island . . . . . . . . .19INTRODUCTION TO EMI NEW! . . . . . . . . . . . . . . . . . . . . . . . . . Apr 27-29, 2004 . . . . . . . . . .Reston, Virginia . . . . . . . . . . . . . . . . .20MICROWAVE & RF CIRCUIT & COMPONENT MODELING . . . . . . . . . Nov 17-20, 2003 . . . . . . . . .Dayton, Ohio . . . . . . . . . . . . . . . . . . .21
Mar 9-12, 2004 . . . . . . . . . .Washington DC/MDMICROWAVE & RF CIRCUIT DESIGN & ANALYSIS . . . . . . . . . . . . . Dec 16-19, 2003 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .22MISSILE AUTOPILOTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Feb 3-6, 2004 . . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .23MODERN MISSILE ANALYSIS . . . . . . . . . . . . . . . . . . . . . . . . . . . Dec 1-4, 2003 . . . . . . . . . . .Arlington, Virginia . . . . . . . . . . . . . . .24
Feb 23-26, 2004 . . . . . . . . .Washington DC/MDPROPAGATION EFFECTS FOR RADAR & COMMUNICATION SYSTEMS . Apr 13-15, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .25RADAR SYSTEMS DESIGN & ENGINEERING . . . . . . . . . . . . . . . . . Mar 1-4, 2004 . . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .26RADAR TRACKING, KF & DATA FUSION . . . . . . . . . . . . . . . . . . . Feb 9-11, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .27SYNTHETIC APERTURE RADAR - FUNDAMENTALS . . . . . . . . . . . . Nov 17-18, 2003 . . . . . . . . .Dulles, Virginia . . . . . . . . . . . . . . . . .28
Mar 1-2, 2004 . . . . . . . . . . .Washington DC/MD
SYNTHETIC
APERTURE
RADAR
ADVANCED
. . . . . . . . . . . . . . . . Nov 19-20, 2003 . . . . . . . . .Dulles, Virginia . . . . . . . . . . . . . . . . .28Mar 3-4, 2004 . . . . . . . . . . .Washington DC/MDCommunications & NetworkingBROADBAND COMMUNICATION & NETWORKING . . . . . . . . . . . . . . Mar 29-30, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .29IMPLEMENTING TCP/IP AND IPV6 NETWORKS . . . . . . . . . . . . . . . Mar 29-30, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .30IP NETWORKING OVER SATELLITE . . . . . . . . . . . . . . . . . . . . . . . Jan 20-22, 2004 . . . . . . . . .Arlington, Virginia . . . . . . . . . . . . . . .31
May 18-20, 2004 . . . . . . . . .Washington DC/MDSATELLITE COMMUNICATION AN INTRODUCTION . . . . . . . . . . . . . Dec 4-5, 2003 . . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .32
Apr 27-28, 2004 . . . . . . . . . .Baltimore, MDSATELLITE LASER COMMUNICATIONS . . . . . . . . . . . . . . . . . . . . . Apr 5-7, 2004 . . . . . . . . . . .Arlington, Virginia . . . . . . . . . . . . . . .33WIRELESS & SPREAD SPECTRUM DESIGN . . . . . . . . . . . . . . . . . . Mar 31-Apr 2, 2004 . . . . . . .Washington DC/MD . . . . . . . . . . . . . .34
Engineering & Data Analysis
ADVANCED TOPICS IN DIGITAL SIGNAL PROCESSING . . . . . . . . . . . June 21-24, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .35APPLICATIONS ORIENTED KALMAN FILTERING . . . . . . . . . . . . . . . Feb 23-25, 2004 . . . . . . . . .Arlington, Virginia . . . . . . . . . . . . . . .36
MATLAB INTRODUCTION & APPLICATIONS . . . . . . . . . . . . . . . . . Apr 21-23, 2004 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .37May 17-19, 2004 . . . . . . . . .Middletown, Rhode Island
MULTI-SENSOR DATA FUSION & KALMAN FILTERING . . . . . . . . . . . . . . . Mar 23-26, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .38PRACTICAL SIGNAL PROCESSING USING MATLAB . . . . . . . . . . . Mar 15-18, 2004 . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .39
June 7-10, 2004 . . . . . . . . .Middletown, Rhode IslandTOTAL SYSTEMS ENGINEERING DEVELOPMENT . . . . . . . . . . . . . . . Dec 9-11, 2003 . . . . . . . . . .Washington DC/MD . . . . . . . . . . . . . .40
Apr 20-22, 2004 . . . . . . . . . .Houston, TexasVIBRATION & SHOCK MEASUREMENT & TESTING . . . . . . . . . . . . . Nov 19-21, 2003 . . . . . . . . .Los Angeles, California . . . . . . . . . . .41
Feb 24-26, 2004 . . . . . . . . .San Jose, CaliforniaMar 9-11, 2004 . . . . . . . . . .Huntsville, Alabama
SIMULATION OF HUMAN INTERACTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 42TOPICS WE CAN TEACH AT YOUR SITE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 43
COURSE REGISTRATION FORM AND/OR ADD A CO-WORKER TO OUR MAILING LIST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .44
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4 Vol. 71 Register online a t www.aticourses.com or ca ll ATI a t 888.501.2100 or 410.531.6034
A d va nc e d Unde rse a Wa rfa reSub m a rine s in Sha llow Wa te r a nd Re g iona l C onflic ts
InstructorsCapt. James Patton (USN ret.) is President of
Submarine Tactics and Technology, Inc. and isconsidered a leading innovator of pro- and anti-submarine warfare and naval tactical doctrine. His 30years of experience includes actively consulting onsubmarine weapons, advanced combat systems, andother stealth warfare related issues to over 30 industrialand government entities. While at OPNAV, Capt. Pattonactively participated in submarine weapon and sensor
research and development, and wasinstrumental in the development of thetowed array. As Chief Staff Officer atSubmarine Development SquadronTwelve (SUB-DEVRON 12), and as
Head of the Advanced TacticsDepartment at the Naval Submarine
School, he was instrumental in thedevelopment of much of thecurrent tactical doctrine.
Commodore Bhim Uppal, former Director of
Submarines for the Indian Navy, is now a consultantwith American Systems Corporation. He will discussthe performance and tactics of diesel submarines inlittoral waters. He has direct experience onboard
FOXTROT, KILO, and Type 1500 dieselelectric submarines. He has over 25 yearsof experience in diesel submarines withthe Indian Navy and can provide aunique insight into the thinking,strategies, and tactics of foreign
submarines. He helped purchase andevaluate Type 1500 and KILOdiesel submarines.
SummaryAdvanced Undersea Warfare (USW) covers the latest
information about submarine employment in futureconflicts. The course is taught by a leading innovator in
submarine tactics. The roles, capabilities and futuredevelopments of submarines in littoral warfare areemphasized.
The technology and tactics of modern nuclear anddiesel submarines are discussed. The importance ofstealth, mobility, and firepower for submarine missionsare illustrated by historical and projected roles ofsubmarines. Differences between nuclear and dieselsubmarines are reviewed. Submarine sensors (sonar,ELINT, visual) and weapons (torpedoes, missiles, mines,special forces) are presented.
Advanced USW gives you a wealth of practicalknowledge about the latest issues and tactics in submarinewarfare. The course provides the necessary background tounderstand the employment of submarines in the current
world environment.Advanced USW is valuable to engineers and scientists
who are working in R&D, or in testing of submarinesystems. It provides the knowledge and perspective tounderstand advanced USW in shallow water and regionalconflicts.
What You Will Learn Changing doctrinal "truths" of Undersea Warfare in Littoral Warfare.
Traditional and emergent tactical concepts of Undersea Warfare.
The forcing functions for required developments in platforms, sensors, weapons,and C-cubed capabilities.
The roles, missions, and counters to "Rest of the World" (ROW) mines and non-nuclear submarines.
Current thinking in support of optimizing the U.S. submarine for coordinated andjoint operations under tactical control of the Joint Task Force Commander orCINC.
February 9-12, 20048:30am - 4:00pm
Middletown, Rhode Island
March 8-11, 20048:30am - 4:00pm
Silverdale, Washington$1495
Course Outline
1. Mechanics and Physics of Submarines.Stealth, mobility, firepower, andendurance. The hull - tradeoffs between speed, depth, and payload. The"Operating Envelope". The "Guts" - energy, electricity, air, andhydraulics.
2. Submarine Sensors. Passive sonar. Active sonar. Radio frequencysensors. Visual sensors. Communications and connectivityconsiderations. Tactical considerations of employment.
3. Submarine Weapons and Off-Board Devices.Torpedoes. Missiles.Mines. Countermeasures. Tactical considerations of employment. SpecialForces.
4. Historical Employment of Submarines. Coastal defense. Fleet scouts.Commerce raiders. Intelligence and warning. Reconnaissance andsurveillance. Tactical considerations of employment.
5. Cold War Employment of Submarines. The maritime strategy. Forwardoffense. Strategic anti-submarine warfare. Tactical considerations ofemployment.
6. Submarine Employment in Littoral Warfare. Overt and covert
"presence". Battle group and joint operations support. Covert minedetection, localization and neutralization. Injection and recovery ofSpecial Forces. Targeting and bomb damage assessment. Tacticalconsiderations of employment. Results of recent out-year wargaming.
7. Littoral Warfare Threats. Types and fuzing options of mines.Vulnerability of submarines compared to surface ships. The diesel-electric or air-independent propulsion submarine "threat". The "Brown-water" acoustic environment. Sensor and weapon performance. Non-acoustic anti-submarine warfare. Tactical considerations of employment.
8. Advanced Sensor, Weapon & Operational Concepts. Strike, anti-air,and anti-theater Ballistic Missile weapons. Autonomous underwatervehicles and deployed off-board systems. Improved C-cubed. The blue-green laser and other enabling technology. Some unsolved issues ofjointness.
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Instructors
Bud Volberg received his B.S. in ElectricalEngineering from the University of California. He is
the president of Invotron, Inc. His pastexperience includes president ofAcoustic Systems, Inc., chief scientist
of Integrated Sciences Corp. SeniorScientist for the Naval Ocean SystemsCenter, founder of AMETEK
Electronics Division, and head ofsolid-state research for Stromberg-Carlson.
Throughout his career, he has been a consultant tomajor corporations and government. He hasparticipated in the design and development of ASWsonars and MCM sidelooking, forward looking, andbathymetric sonar systems. Other work has involvedthe design of mine neutralizers, undersea worksystems, waterside security, and under-ice sonars.
Garry A. Kozak attended Wayne State University,Detroit, majoring in Electrical Engineering. He has
over 30 years of service to theoceanographic community, including28 years in search and surveyoperations with side scan sonar. Forthe past 25 years he has been
employed by Klein Associates, one ofthe leading manufacturers of side scan
sonar systems. He has specialized inM.C.M. and C.O.O.P application of side
scan sonar and has over 24 years of hands-onexperience in detecting mine-like objects.
Summary
The key essentials and system concepts of minewarfare are presented in this 4-day course. Thiscourse reviews mine threat, mine countermeasures,and mine neutralization, emphasizing sonar andunmanned vehicles.
The course will summarize various minehuntingsonar detection and classification techniquesranging from CTFM sonars to broadband systems.Methods of navigation associated with underwatervehicles and minehunting will be introduced.Techniques utilized for mine neutralization will bepresented, including new approaches usingunmanned vehicles.
The course is designed to provide a practicalunderstanding of the theory and current state-of-the-art technology in mine countermeasures. Acomplete set of notes will be supplied to allattendees.
March 8-11, 20048:30 am - 4:00 pm
Panama City, Florida
May 3-6, 20048:30 am - 4:00 pm
Middletown, Rhode Island
$1495
Course Outline
1. Minehunting Environment and Non-Acoustic Sensors. Mine
countermeasures doctrine. Where are the mines? What else should be
measured? Review of the oceanic environment as it relates to magnetic,optic, and acoustic sensors: ambient noise, bottom backscattering,
absorption, and simple propagation. Non-acoustic sensors utilizing various
magnetic methods. Sensing using cameras, scanning lasers and lidar.
Examples of hardware.
2. Acoustical Relationships. Fundamentals of various sonar techniques
including side looking, forward looking, nonlinear, bathymetric, CTFM,
and mammal sonars. Echo, passive, shadow and sub-bottom modes.
Transducer relationships, near-field and farfield, single scanning beam and
multiple beamforming methods. Design considerations for side looking
sonar and synthetic aperture sonar. Nonlinear sonar. Sub-bottom detection
systems.
3. Target Characteristics. Characteristics of various targets. Formation of
echo structure. Extracting target information.4. Platform Noise and Domes. Platform noise. Individual component noise.
Vehicle noise. Helicopter noise in the ocean. Dome use and materials.
5. Signal Processing. Detection threshold and the ambiguity function. Using
the target echo structure to detect shape parameters. Human aural signal
processing using a dolphin-like signal.
6. Navigation. Pingers, markers, localized transponders. Long and ultra-short
baseline methods. Doppler navigation sonar. Electromagnetic methods such
as parabolic, range-range, azimuthal systems. GPS.
7. Neutralization. Mine neutralization and removal techniques. Approach
methods using divers with hand-held sonars, ROVs, tethered and untethered
vehicles. Supercavitating projectiles.
8. Minehunting Sonar Systems. Conventional U.S. surface MCM systems
and systems. The U.S. Mine Countermeasures Marine Mammal Systems.Examples of newly developed MCM systems including a newly integrated
MCM/Stealth system.
9. Estimating Sonar Performance with the sonar equation.
10. Side-Scan Sonar. Principles of side-scan operations. Examples illustrating
the interpretation of sonar records: target and shadows, surface effects,
sidelobes, design-related effects, towing effects, correction of distortions.
11. Application of Side-Scan Sonar to Minehunting. Detection of mine size
objects and sonar parameter effects. Choice of frequency and
range/resolution issues. Search tactics and patterns. Comparison of mine
sonar systems. Positioning. Q-routes. State-of-the-art and future trends.
Single Beam vs. Multi-Beam focused side scan sonars.
De ve lop m e nts in M ine Wa rfa reSona r, Lida r a nd Unm a nned Ve h ic le s
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6 Vol. 71 Register online a t www.aticourses.com or ca ll ATI a t 888.501.2100 or 410.531.6034
M e c ha nic s o f Und e rwa te r N oiseFunda m e nta ls a nd A d va nc e s in Ac oustic Q uie ting
InstructorsJoel Garrelick has extensive experience in the
general area of structural acoustics and specifically,underwater acoustics applications. As a PrincipalScientist for Cambridge Acoustical Associates, Inc.,CAA/Anteon, Inc. and currently Applied PhysicalSciences, Inc., he has thirty plus years experienceworking on various ship/submarine silencing R&Dprojects for Naval Sea Systems Command, theApplied Physics Laboratory of Johns HopkinsUniversity, Office of Naval Research, Naval SurfaceWarfare Center and Naval Research Laboratory. Hehas also performed aircraft noise research for the Air
Force Research Laboratory and NASA and is theauthor of a number of articles in technical journals.Joel received his B.C.E. and M.E. from the CityCollege of New York and his Ph.D in EngineeringMechanics from the City University of New York.
Paul Arveson served as a civilian employee of theNaval Surface Warfare Center (NSWC), CarderockDivision. With a BS degree in Physics, he ledteams in ship acoustic signature measurement andanalysis, facility calibration, and characterizationprojects. He designed and constructed specializedanalog and digital electronic measurement systemsand their sensors and interfaces, including thesystem used to calibrate all the US Navy's ship noise
measurement facilities. He managed developmentof the Target Strength Predictive Model for theNavy. He conducted experimental and theoreticalstudies of acoustic and oceanographic phenomenafor the Office of Naval Research. He has publishednumerous technical reports and papers in thesefields. In 1999 Arveson received a Master's degreein Computer Systems Management. He establishedthe Balanced Scorecard Institute, as an effort topromote the use of this management concept amonggovernmental and nonprofit organizations. He isactive in various technical organizations, and is aFellow in the Washington Academy of Sciences.
Summary
The course describes the essential mechanisms
of underwater noise as it relates to ship/submarinesilencing applications. The fundamental principlesof noise sources, water-borne and structure-bornenoise propagation, and noise controlmethodologies are explained. Illustrative exampleswill be presented. The course will be geared tothose desiring a basic understanding of underwaternoise and ship/submarine silencing with necessarymathematics presented as gently as possible.
A full set of notes will be given to participants aswell as a copy of the text, Mechanics ofUnderwater Noise, by Donald Ross.
Course Outline
1. Fundamentals. Definitions, units, sources, spectral andtemporal properties, wave equation, radiation andpropagation, reflection, absorption and scattering,structure-borne noise, interaction of sound and structures.
2. Noise Sources in Marine Applications. Rotating andreciprocating machinery, pumps and fans, gears, pipingsystems.
3. Noise Models for Design and Prediction. Source-path-
receiver models, source characterization, structuralresponse and vibration transmission, deterministic (FE)and statistical (SEA) analyses.
4. Noise Control. Principles of machinery quieting, vibrationisolation, structural damping, structural transmission loss,acoustic absorption, acoustic mufflers.
5. Fluid Mechanics and Flow Induced Noise. Turbulentboundary layers, wakes, vortex shedding, cavity resonance,fluid-structure interactions, propeller noise mechanisms,cavitation noise.
6. Hull Vibration and Radiation. Flexural and membrane
modes of vibration, hull structure resonances, resonanceavoidance, ribbed-plates, thin shells, anti-radiationcoatings, bubble screens.
7. Sonar Self Noise and Reduction. On board and towedarrays, noise models, noise control for habitability, sonardomes.
8. Ship/Submarine Scattering. Rigid body and elasticscattering mechanisms, target strength of structuralcomponents, false targets, methods for echo reduction,anechoic coatings.
June 22-24, 20048:30am - 4:00pm
Washington DC/MD
$1390
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InstructorsMark A. Chramiec retired from Raytheon's
Submarine Signal Division after 34 years of developing,testing and improving various types of military andoceanographic sonars for the US and numerous
international navies. These included activeand passive submarine and surface shipASW sonars, bathymetric and sub-bottom profiling sonars, sonars used forremote control of offshore oilinstallations and the first operational
sonar using non-linear acoustics. Mr.Chramiec, who has MS degrees in
Physics and Ocean Engineering,holds five patents and has published twenty paperscovering various underwater acoustic devices. He servedseven years in the US Navy as a Fire Control Technician.
Robert B. Delisle is an Engineering Fellow atRaytheon NM & IS. He has helped design, develop, and
evaluate surface ship sonar systems formore than two decades and hasparticipated in numerous at-sea sonarevaluations for the U.S. Navy and otherallied navies. He has been involved inthe design, development, and testing of
mine hunting and classification sonars atRaytheon. Mr. Delisle holds an M.S.degree in electrical engineering from
Renssalaer Polytechnic Institute.
SummaryThe key essentials and system issues of configuring
practical sonar systems are highlighted in this course.
The course provides a step-by-step guide tounderstanding and designing modern sonar systems. It
addresses the fundamental concepts applicable to sonar
systems including sound propagation, design and use of
transducers, beamforming, signal processing and
displays. Design examples of surface ship
active/passive sonar, variable depth sonar, and mine
hunting and localization sonars are presented to
illustrate the current state of the art in sonar.
Performance prediction and analysis will be discussed.
You will acquire the knowledge, perspective, and
practical skills needed to understand modern sonar
technology.
The course is valuable to government and industry
engineers, managers, and others who need a practicalworking knowledge of the theory and applications of
modern sonar. You'll benefit from the more than 50
years of combined hands-on experience of the
instructors and their case studies. The course examines
the design trade offs and potential performance of
modern sonar. Current issues, such as shallow water
performance, and future trends are discussed. A
complete set of notes and the text Principles of
Underwater Sound by Robert Urick (McGraw-Hill)
will be supplied to all attendees.
April 5-8, 20048:30am - 4:00pm
Middletown, Rhode IslandCourtyard by Marriott
401.849.8000
$1495
Course Outline
1. Sonar Systems and Equations. Active, passive, communication,and navigation sonars. The basic application of sonar equations toeach type.
2. Sound Propagation. The propagation of sound in the ocean.Refractions and Reflections. Resulting operational considerations.
3. Transmission and Reception. Terms of the sonar equations andtheir relationship to sonar arrays, transmitters, beam-formers,receivers, and displays.
4. Sonar System Requirements and Operations. Operationalrequirements of sonar detection, classification, and tracking.Methods for implementing sonar requirements.
5. Performance Prediction. Absolute and comparative performanceprediction using simple and complex prediction methods.
6. Active and Passive Sonar Arrays. Projector, hydrophone, andtransducer arrays used in current passive and active sonars. Sonartransmission and reception. Tuning and data transmissionfunctions.
7. Transmitters, Receivers, and Beam-Formers. Linear and
switch mode transmitters. Analog and digital receivers.Transmitter and receiver beam-formers.
8. Displays. Current active and passive sonar displays.
9. Signal Processing. Detection threshold. Recognitionsdifferential. Noise- and reverberational-limited conditions.Practical limits.
10. Signal Processors. Processing gain. Coherent, semicoherent, andspatial processors.
11. Surface Ship Sonar Systems. Typical operating modes.Performance analysis.
12. Mine Hunting Sonar. Design of detection and localization sonarsfor mine warfare. Performance potential and limitations.
13. Future Developments and Challenges. Performance in littoralwaters. The diesel submarine threat. New technologies.
Pra c tic a l So na r Sy ste m s Eng ine e ring
What You Will Learn
Trade-offs and comparisons among different sonars.
How to calculate sonar performance.
How to select waveforms.
How to optimize shallow water performance.
Minehunting in shallow water.
The latest developments in new technology.
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So na r Princ ip le s & A SW A na ly sis
Instructor
Dr. Nicholas Nicholas received a B. S. degree
from Carnegie-Mellon University, an M. S. degreefrom Drexel University, and a PhD degree in physics
from the Catholic University ofAmerica. His dissertation was on thepropagation of sound in the deepocean. He has been teachingunderwater acoustics courses since
1977 and has been visiting lecturer atthe U.S. Naval War College andseveral universities. Dr. Nicholas
has more than 25 years experience in underwateracoustics and submarine related work. He is workingfor Penn States Applied Research Laboratory (ARL).
Dr. Robert Jennette received a PhD degree in
Physics from New York University in 1971. He hasworked in sonar system design with particular
emphasis on long-range passivesystems, especially their interactionwith ambient noise. He held theNAVSEA Chair in UnderwaterAcoustics at the US Naval Academywhere he initiated a radiated noise
measurement program. CurrentlyDr. Jennette is a consultant
specializing in radiated noise and the use of acousticmonitoring.
Summary
This course provides an excellent introduction to
underwater sound and highlights how sonar
principles are employed in ASW analyses. Thecourse provides a solid understanding of the sonar
equation and discusses in-depth propagation loss,
target strength, reverberation, arrays, array gain, and
detection of signals.
Physical insight and typical results are provided to
help understand each term of the sonar equation. The
instructors then show how the sonar equation can be
used to perform ASW analysis and predict the
performance of passive and active sonar systems.
The course also reviews the rationale behind current
weapons and sensor systems and discusses directions
for research in response to the quieting of submarine
signatures.The course is valuable to engineers and scientists
who are entering the field or as a review for
employees who want a system level overview. The
lectures provide the knowledge and perspective
needed to understand recent developments in
underwater acoustics and in ASW. A comprehensive
set of notes and the textbook Principles of
Underwater Soundwill be provided to all attendees.
What You Will Learn
Sonar parameters and their utility in ASW Analysis.
Sonar equation as it applies to active and passive systems.
Fundamentals of array configurations, beamforming, and signal detectability.
Rationale behind the design of passive and active sonar systems.
Theory and applications of current weapons and sensors, plus future
directions.
The implications and counters to the quieting of the targets signature.
March 8-11, 20048:30am - 4:00pm
Middletown, Rhode IslandCourtyard by Marriott 401.849.8000
June 7-10, 20048:30am - 4:00pm
Silverdale, WashingtonWest Coast Silverdale Hotel 360.698.1000
$1595
Course Outline1. Sonar Equation & Signal Detection. Sonar concepts and units. The sonar
equation. Typical active and passive sonar parameters. Signal detection,probability of detection/false alarm. ROC curves and detection threshold.
2. Propagation of Sound in the Sea. Oceanographic basis of propagation,convergence zones, surface ducts, sound channels, surface and bottomlosses.
3. Target Strength and Reverberation. Scattering phenomena and submarinestrength. Bottom, surface, and volume reverberation mechanisms. Methodsfor modeling reverberations.
4. Elements of ASW Analysis. Fundamentals of ASW analysis. Sonarprinciples and ASW analysis, illustrative sonobuoy barrier model. The useof operations research to improve ASW.
5. Arrays and Beamforming. Directivity and array gain; sidelobe control,array patterns and beamforming for passive bottom, hull mounted, and
sonobuoy sensors; calculation of array gain in directional noise.
6. Passive Sonar. Illustrations of passive sonars including sonobuoys, towedarray systems, and submarine sonar. Considerations for passive sonarsystems, including radiated source level, sources of background noise, andself noise.
7. Active Sonar. Design factors for active sonar systems including transducer,waveform selection, and optimum frequency; examples include ASW sonar,sidescan sonar, and torpedo sonar.
8. Theory and Applications of Current Weapons and Sensor Systems. Anunclassified exposition of the rationale behind the design of current Navyacoustic systems. How the choice of particular parameter values in the sonarequation produces sensor designs optimized to particular militaryrequirements. Generic sonars examined vary from short-range active minehunting sonars to long-range passive systems.
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Struc tura l A c o ustic sFu n d a m e n ta ls & M o d e rn C o m p u ta tio n a l M e th o d s
SummaryThe purpose of this course is two fold: (1) to introduce
the fundamental physics underlying the creation of sound
from vibrating structures, and (2) to introduce moderncomputational methods for predicting and controlling thesound field. The physics of sound generation arepresented. The emphasis is on understanding and basicprinciples, with a modest amount of theoreticaldevelopment. Important concepts such as coincidence,radiation efficiency, intensity and directivity arediscussed and applied to a variety of structures (e.g.planar sources, plates and cylindrical shells). Soundpropagation inside pipes is also presented along withmethods of attenuating and reflecting acoustic energy.
Numerical techniques for predicting and controllingsound constitute the second half of the course. For planarstructures the Rayleigh integral equation is presented andapplied to a variety of problems. Transfer and
Impedance matrix techniques can be used to calculateplane wave sound propagation in rigid and elastic pipingsystems (including fluid-elastic coupling.) At highfrequencies the method of Statistical Energy Analysis isvery useful for identifying dominant sound transmissionpaths from vibrating structures. SEA is also anextremely easy analysis tool for evaluating the effect ofdesign modifications on radiated power. At lowfrequency where individual modes control radiated soundthe Helmholtz integral can be utilized. A recentcomputational method that utilizes the capabilities offinite elements is an infinite fluid element. This elementcaptures the physics of both the near field and far field.More importantly, the infinite element avoids thetraditional inside eigenvalue problem associated with the
HIE method and is very computationally efficient sincethe matrices are well banded. Use of this element in theSARA finite element code is discussed.
Who Should Attend
The material presented in this course is very well suited for engineers
who wish to obtain both a good understanding of the physics of soundgeneration and knowledge of computational tools for predicting andcontrolling radiated sound.
April 20-22, 20048:30am - 4:00pm
Washington DC/MD$1290
Course Outline1. Fundamentals of Wave Propagation. Flexural, compressional and torsional
waves in beams, flexural waves in plates and compressional waves in fluids.Concept of wave number and dispersion curves.
2. Acoustic Waves. ntensity, impedance and power in acoustic waves, far fieldand near field pressure from a sphere, concept of a point source, method ofimages, directivity.
3. Rayleighs Equation and Applications. Far field pressure and intensity fromplanar sources such as dipoles, multipoles, arrays, circular and rectangular
plates.4. Structural Acoustics of Plates. Radiation from finite and infinite plates,
coincidence frequency, Fourier integral transform with applications, methodsof stationary phase, concept of radiation efficiency, fluid loading on plates, andsound transmission through plates.
5. Structural Acoustics of Shells. Vibration and wave propagation in isotropicand orthotropic cylindrical shells, fluid loading, acoustic radiation andradiation efficiency. Influence of complicating effects on radiation.
6. Sound Propagation in Pipes. Plane waves and higher order cut-on waves instraight pipes, influence of pipe wall impedance and liners on wavepropagation. Methods of analyzing piping systems such transfer andimpedance techniques, and methods of reducing noise, such as the use ofHelmholtz resonators, side branches and damping.
7. Fluid Loading Approximations. Incompressible fluid, rho-c fluid and first
and second order doubly asymptotic approximations, DAA with applications.Simple interpretations of DAA in frequency domain.
8. Statistical Energy Analysis. Overview of SEA with emphasis on soundtransmission and radiation problems. Brief discussion of capabilities ofAutoSEA computer program along with several examples.
9. Helmholtz Integral Equation. Basic theory of two and three-dimensionalHIE with coupling to finite elements. Use of HIE in far field pressurecalculations using near field analytical or experimental data.
10. Infinite Fluid Elements. Basic theory of infinite element with coupling tofinite elements. Discussion of SARA (Structural Acoustic Radiation Analyzer)computer program along with several examples, such as calculation of modalradiation efficiency of complex three-dimensional structures and radiation fromshells.
InstructorDr. Robert C. Haberman is a Principal Engineer at
Bolt Beranek and Newman and an Adjunct AssociateProfessor (Mechanical Engineering) for the RenssalaerPolytechnic Institute. He has over 25 years of R& D
experience in noise, vibration, acousticsand shock analysis of naval structures.Examples include, use of StatisticalEnergy Analysis to study noisetransmission in submarine internal
structures, use of Fuzzy Structures todetermine submarine hull damping, andapplication of classical continuum
mechanics along with moderncomputational methods to study problems in acousticradiation. He is an author of numerous publications, afrequent speaker at noise and vibration conferences, andhas written over 100 technical reports.
In 1983, Dr. Haberman and Dr. Henno Allik of BBNpresented a paper On the Use of Infinite Elements inStructural Acoustics. Since then the element has beenincorporated into the SARA computer program that isnow used by many government laboratories anduniversities.
This course covers both fundamental physics
and modern computational methods.
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Sub m a rine s a nd The ir C om b a t Syste m s
InstructorCaptain Ray Wellborn, USN (retired), served over
13 years of his 30-year Navy career in submarines. Hehas a BSEE degree from the US Naval Academy, anMSEE degree from the Naval Postgraduate School. andalso has an MA from the Naval War College. He had twomajor commands at sea and one ashore. USS Mount
Baker (AE 34), USS Detroit (AOE 4), and theNaval Electronics Systems Engineering
Center, Charleston. He was ProgramManager for Tactical Towed Array
Sonar Systems and Program Directorfor Surface Ship and Helicopter ASW
Systems for the Naval Sea Command inWashington, DC. After retirement, he
was the Director of Programs,Argotec, Inc., overseeing the construction of advanced
R&D models for large underwater acoustic projectors.From 1992 until 1996, he was a Senior Lecturer in theMarine Engineering Department of Texas A&M,Galveston. Since 1996, he has been an independentconsultant for International Maritime Affairs.
Summary
This course is a comprehensive introduction tosubmarines. It will provide you with a detailed
understanding of submarine design and submarine
construction, as well as an historical perspective of how
the modern submarine evolved to its present design. It
will also summarize the mission, functions, tasks, and
roles assigned to US submarines. A detailed review of
naval submarine forces in the world today will be
presented. This course will enable you to identify and
better understand the submarine threat and its
characteristics.
Submarine combat systems will be highlighted, as
will submarine command and control systems.
Submarine operations and operational concepts will be
reviewed for the Hunter and the Hunted. An
antisubmarine warfare (ASW) perspective will cover
ASW air and surface force capabilities and the combined
arms effect when coordinated with and against
submarines. The standard submarine organization, daily
routine and battle station assignments will be discussed
along with why submarine people go through special
rigors to become qualified in submarines.
You will understand how and why a specific system
contributes to the overall submarine performance. A
comprehensive set of notes will be provided to all
attendees. This will include a summary of unclassified
design characteristics of US submarines, and a threat
assessment of submarine forces around the world.
March 22-24, 20048:30 am - 4:00 pm
Middletown, Rhode IslandCourtyard by Marriott
401.849.8000
$1290
Course Outline
1. Submarine Missions and an Historic Perspective of Submarine
Operations. Review of the submarine mission related to US Maritime
Strategy and a brief history of submarine operations with performance
results.
2. Submarine Design and Construction. Basic principles of the form, fit and
function of how a submarine is built and how it operates, including a
synoptic history of submarine evolution.3. Submarine Forces of the Super Powers and the Third World. Overview
of submarine classes and their design characteristics, with an insight into the
effectiveness and limitations of their stealth and performance. Assessment of
supporting facilities and the quality of the training necessary to perform
submarine warfare tasks effectively and decisively.
4. Submarine Combat Systems and Command and Control Systems. A
familiarization of these systems will be presented from an operational
perspective with a synopsis of the Nuts and Bolts of the major elements
that compose submarine combat systems.
5. Submariners. Who are these people and why must they undergo such
rigorous training and qualifications? Standard submarine organizations,
watch routines, and battle station assignments. The psyche and disposition
required to become qualified in submarines and wear the distinctivedolphins.
6. Antisubmarine Warfare. Hunter or Hunted. Overview of the US
Navys number one priority: ASW. The air and surface force perspective and
approach to ASW will be presented, including the effort and equipment
necessary to coordinate their combined arms effect. In the closing session,
the new Virginia class as a follow-on alternative to SEAWOLF will be
discussed. The submarine threat for the 21st century also will be discussed
along with questions, such as: Will diesel electric submarines still be cost-
effective for strangling an adversarys economy for whom, where, how? Is
shallow-water ASW a mission-essential need for the future? Will it still be
best to sink a submarine while it is in port? Where do we go from here?
This course is valuable to:
Engineers & scientists in R&D or testing of
submarine systems.
Newcomers to the field.
Those who specialize in just one subsystem& want an overview.
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InstructorPaul C. Etter has worked in the fields of ocean-
atmosphere physics and environmental acoustics for the
past thirty years supporting federal and state agencies,
academia and private industry. He received his BS degree
in Physics and his MS degree in Oceanography at Texas
A&M University. Mr. Etter served on active
duty in the U.S. Navy as an Anti-Submarine
Warfare (ASW) Officer aboard frigates.
He is the author or co-author of more than
140 technical reports and professional
papers addressing environmental
measurement technology, underwater
acoustics and physical oceanography.
Mr. Etter is the author of the
textbookUnderwater Acoustic Modeling and Simulation.
SummaryThe subject of underwater acoustic modeling deals with
the translation of our physical understanding of sound in
the sea into mathematical formulas solvable by computers.
This course provides a comprehensive treatment of all
types of underwater acoustic models including
environmental, propagation, noise, reverberation and sonar
performance models. Specific examples of each type of
model are discussed to illustrate model formulations,
assumptions and algorithm efficiency. Guidelines for
selecting and using available propagation, noise and
reverberation models are highlighted. Problem sessions
allow students to exercise PC-based propagation and active
sonar models.
Each student will receive a copy of Underwater
Acoustic Modeling and Simulation by Paul C. Etter, in
addition to a complete set of lecture notes.
What You Will Learn What models are available to support sonar
engineering and oceanographic research.
How to select the most appropriate models based onuser requirements.
Where to obtain the latest models and databases.
How to operate models and generate reliable results.
How to evaluate model accuracy.
How to solve sonar equations and simulate sonarperformance.
Where the most promising international research isbeing performed.
April 26-29, 20048:30am - 4:00pm
Middletown, Rhode Island
Courtyard by Marriott401.849.8000$1595
Course Outline
1. Introduction. Nature of acoustical measurements and prediction. Modern
developments in physical and mathematical modeling. Diagnostic versus prognostic
applications. Latest developments in acoustic sensing of the oceans.
2. The Ocean as an Acoustic Medium. Distribution of physical and chemical
properties in the oceans. Sound-speed calculation, measurement and distribution.
Surface and bottom boundary conditions. Effects of circulation patterns, fronts,eddies and fine-scale features on acoustics. Biological effects.
3. Propagation. Observations and Physical Models. Basic concepts, boundary
interactions, attenuation and absorption. Shear-wave effects in the sea floor and ice
cover. Ducting phenomena including surface ducts, sound channels, convergence
zones, shallow-water ducts and Arctic half-channels. Spatial and temporal
coherence. Mathematical Models. Theoretical basis for propagation modeling.
Frequency-domain wave equation formulations including ray theory, normal mode,
multipath expansion, fast field and parabolic approximation techniques. New
developments in shallow-water and under-ice models. Domains of applicability.
Model summary tables. Data support requirements. Specific examples (PE and
RAYMODE). References. Demonstrations.
4. Noise. Observations and Physical Models. Noise sources and spectra. Depth
dependence and directionality. Slope-conversion effects. Mathematical Models.
Theoretical basis for noise modeling. Ambient noise and beam-noise statisticsmodels. Pathological features arising from inappropriate assumptions. Model
summary tables. Data support requirements. Specific example (RANDI-III).
References.
5. Reverberation. Observations and Physical Models. Volume and boundary scattering.
Shallow-water and under-ice reverberation features. Mathematical Models.
Theoretical basis for reverberation modeling. Cell scattering and point scattering
techniques. Bistatic reverberation formulations and operational restrictions. Data
support requirements. Specific examples (REVMOD and Bistatic Acoustic Model).
References.
6. Sonar Performance Models. Sonar equations. Model operating systems. Model
summary tables. Data support requirements. Sources of oceanographic and acoustic
data. Specific examples (NISSM and Generic Sonar Model). References.
7. Modeling and Simulation. Review of simulation theory including advanced
methodologies and infrastructure tools. Overview of engineering, engagement,
mission and theater level models. Discussion of applications in concept evaluation,
training and resource allocation.
8. Modern Applications in Shallow Water and Inverse Acoustic Sensing. Stochastic
modeling, broadband and time-domain modeling techniques, matched field
processing, acoustic tomography, coupled ocean-acoustic modeling, 3D modeling,
and chaotic metrics.
9. Model Evaluation. Guidelines for model evaluation and documentation. Analytical
benchmark solutions. Theoretical and operational limitations. Verification,
validation and accreditation. Examples.
10. Demonstrations and Problem Sessions. Demonstration of PC-based propagation
and active sonar models. Hands-on problem sessions and discussion of results.
Und e rwa te r A c o ustic M od e ling a nd Sim ula tion
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V ib ra tio n a nd N o ise C o ntro lNe w Insights a nd Deve lop m e nts
Summary
This course is intended for engineers and scientists
concerned with the vibration reduction and quieting of
machinery and of other mechanical devices and
equipment. The course will provide guidance relevant to
design, problem solving, and development of
improvements. It will emphasize understanding of the
relevant phenomena and concepts in order to enable the
participants to address a wide range of practical
problems insightfully. The instructors will draw on their
extensive experience to illustrate the subject matter with
examples related to the participants specific areas of
interest. Although the course will begin with a review
and will include some demonstrations, participants
ideally should have some prior acquaintance with
vibration or noise fields. Each participant will receive a
complete set of course notes and the text Noise and
Vibration Control Engineering.
What You Will Learn How to attack vibration and noise problems.
What means are available for vibration and noise control.
How to make vibration isolation, damping, and absorbers work.
How noise is generated and radiated, and how it can be reduced.
InstructorsDr. James Moore has, for the past twenty years,
concentrated on the transmission of noise andvibration in complex structures, on improvements ofnoise and vibration control methods, and on the
enhancement of sound quality. He hasdeveloped Statistical Energy Analysismodels for the investigation ofvibrations and noise complexstructures such as submarines,helicopters, and automobiles. He has
been instrumental in the acquisition ofcorresponding data bases. He has
participated in the development ofactive noise control systems, noise
reduction coating and signal conditioning means, aswell as in the presentation of numerous short coursesand industrial training programs.
Dr. Eric Ungar has specialized in research andconsulting in vibration and noise for 38 years,published over 100 technical papers, and translatedand revised Structure-Borne Sound. He has led shortcourses at the Pennsylvania State University for thepast 25 years and has presented numerous seminarsworldwide. Dr. Ungar has served as President of theAcoustical Society of America, as President of theInstitute of Noise Control Engineering, and asChairman of the Design Engineering Division of the
American Society of MechanicalEngineers. ASME honored him with itsTrent-Crede Medal in Shock andVibration. ASA recently awarded himthe Per Bruel Gold Medal for Noise
Control and Acoustics for his work onvibrations of complex structures,
structural damping, and isolation.
February 23-26, 20048:30am - 4:00pm
Washington DC/MDHoliday Inn
College Park, MD 301.345.6700
$1595
Course Outline
1. Review of Vibration Fundamentals from a Practical Perspective. Theroles of energy and force balances. When to add mass, stiffeners, anddamping. General strategy for attacking practical problems. Comprehensive
checklist of vibration control means.2. Structural Damping Demystified. Where damping can and cannot help.How damping is measured. Overview of important damping mechanisms.Application principles. Dynamic behavior of plastic and elastomericmaterials. Straightforward design of treatments employing viscoelasticmaterials in shear and extension.
3. Expanded Understanding of Vibration Isolation. Where transmissibility isand is not useful. Some common misconceptions regarding inertia bases,damping, and machine speed. Accounting for support and machine frameflexibility, isolator mass and wave effects, source reaction. Benefits andpitfalls of two-stage isolation. The role of active isolation systems.
4. The Power of Vibration Absorbers. How tuned dampers work. Effects oftuning, mass, damping. Optimization. How waveguide energy absorbers areuseful.
5. Structure-borne Sound and High Frequency Vibration. Where modal andfinite-element analyses cannot work. Simple response estimation fromtabulated infinite system results. What is Statistical Energy Analysis and howdoes it work? How waves propagate along structures and radiate sound.
6. No-Nonsense Basics of Noise and its Control. Review of levels, decibels,sound pressure, power, intensity, directivity. Frequency bands, filters, andmeasures of noisiness. Radiation efficiency. Overview of common noisesources. Noise control strategies and means.
7. Intelligent Measurement and Analysis. Diagnostic strategy. Selecting theright transducers; how and where to place them. The power of spectrumanalyzers. Identifying and characterizing sources and paths.
8. Coping with Noise in Rooms. Where sound absorption can and cannot help.Practical sound absorbers and absorptive materials. Effects of full and partialenclosures. Sound transmission to adjacent areas. Designing enclosures,wrappings, and barriers.
9. Ducts and Mufflers. Sound propagation in ducts. Duct linings. Reactivemufflers and side-branch resonators. Introduction to current developments inactive attenuation.
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April 28-30, 20048:30 am - 4:30 pm
Washington DC/MD$1290
C 4ISR Re q uire m e nts, Princ ip le s, a nd Syste m sAn O ve rvie w of Und e rsta nd ing a nd Build ing a Suc c e ssful C4 ISR Arc hite c ture
InstructorWilliam J. Geckle, M.S., has been working for 24 yearsas a scientist in defense technology. He is currently a
principal staff physicist in the Air DefenseSystems Department, Applied PhysicsLaboratory, Johns Hopkins University, and apart-time faculty member of the WhitingSchool of Engineering, JHU. He led the Fires
and Targeting team for the ONR 'Extending theLittoral Battlespace' ACTD, served as
technical lead for several Real TimeInto / Out of the Cockpit(RTIC/RTOC) programs, has
extensive experience in the development of solutions forJoint TADIL communications, and was a designer of theJoint Strike Fighter (JSF) C4ISR architecture. He iscurrently leading the C4ISR architecture development forboth the Global Network Centric Targeting (GNCST)
program that will provide tailored products in support oftime critical targeting around the world and for LongRange Strike (LRS), the Air Force future strike platformfor penetration of denied air space. He brings a wealth oftechnical experience in C4ISR forAir Force, Navy,Marine, Army and national agency operations.
Michael E. Pafford, M.S., has 30 years of experience inthe design, development, operation, and management ofintelligence-related systems. He is currently a SeniorSystems Engineer in the Intelligence Systems Group ofthe Applied Physics Laboratory, Johns HopkinsUniversity. He led the APL technical team in thedevelopment of Operational, System, and TechnicalC4ISR Architecture products in support of ASN/R&D
Time-Critical Targeting (TCT) and Tasking, Collecting,Processing, Exploitation, and Dissemination (TCPED)acquisition-related Mission Capability Packages (MCPs).He began his career as an Air Force voice processingspecialist operating and later as a Navy CryptologicOfficer helping to design state-of-the-art C4ISR systems.He held technical positions with ITT, General Dynamics,and Harris Corporation designing and developing C4ISRsystems. His current projects involve Signals Intelligence(SIGINT) data mining, SIGINT process modeling &simulation, and SIGINT Enterprise-Level PerformanceAssessment. He brings a wealth of technical experience inDoD and other Government C4ISR systems.
SummaryThis course is a valuable tool for the engineer, scientist or
manager working with DoD information technology whowishes to improve their understanding of C4ISR systems and
the new requirements to demonstrate interoperability. Learnabout the current systems that populate the DoD C4ISRarchitecture and the process established by the DoD to insuretheir interoperability. Learn why a well crafted C4ISRarchitecture is important in network-centric warfare and howto build one using the latest techniques and software tools.Apply this new information to current C4ISR systems andgain an understanding of the technology and principles thatunderlie their operation. Learn how to save time followingsuccessful strategies while avoiding costly pitfalls whenmeeting C4ISR requirements.
Course Outline
Part I: C4ISR Architecture Requirements and Principles
1. C4ISR. Definitions and Overview. Linking Successful Warfighting,
Interoperability and Well Crafted Architectures.
2. DoD C4ISR Requirements. DoD's Roadmap to Interoperability: New 5000 and
3000 series instructions.
3. C4ISR Architectures and the Interoperability Problem. Foundations of
Architecture Development: Structured Analysis, Static and Executable Models.
DoD Architecture Definition - Operational, Systems, Technical Views. In classdemonstration of software tools for building architectures.
4. Building the Required DoD C4ISR products. The Operational Concept
Matrix - framework for crafting C4ISR products. Information Exchange
Requirements (IERs) - required fields, level of detail, and roll-ups. Key
Performance Parameters (KPPs) - isolating a new system's performance and
defining MOP's and MOE's. C4I Support Plan - what it is and how is it used.
Field Exercises, Simulations, and Architecture Development.
Part II: C4ISR Systems and Technology
5. Command and Control. Battle Management. C2 Hierarchy: Systems and
Commands. Sensor-to-Shooter, Time Critical Targeting (TCT) Approaches and
Lessons Learned.
6. Computers. The Global Information Grid (GIG), Net-Centric Warfare, and The
Distributed Common Ground Station (DCGS). Software/HardwareInteroperability : JTA/ DII/ COE . Image Dissemination and Compression.
7. Communications Overview: Fundamentals and definitions, networks,
jamming and Low Probability of Intercept / Detection (LPI/LPD) techniques.
8. Military Communication Channels - TADILs (Tactical Data and
Information Links): Link 11, Link-16. Challenges: Interoperability,
Bandwidth, Coordinate Alignment, Coordination in Theater. Next generation
TADIL systems and the Single Integrated Air Picture (SIAP).
9. Satellite Communications Overview: Definitions, Benefits, Trade-offs, Link
Analysis. SATCOM Systems: Current and Future. The 2020 Transformational
Communications Architecture (TCA). SATCOM and C4ISR Architecture
Evolution.
10. Observables and Sensors. Fundamentals, Current and Future Systems.
Electronics Intelligence (ELINT), Signals Intelligence (SIGINT), Image
Intelligence (IMINT), and Sensor Fusion. Passive Sensors: Antennas, Signals
Intercept, Direction Finding. Active sensors: High Range Resolution (HRR),
Air Moving Target Indicator (AMTI), Ground Moving Target Indicator (GMTI),
Synthetic Aperture Radar (SAR), I(Inverse)SAR, InterFerometric (IFSAR).
11. Platforms and Sensors: National. Services. Space Based Radar (SBR) and
Infrared (SBIR), UAVs, Net-Centric Operations.
12. Precision Targeting: FTarget Location. Methods of geolocation. Errors in
Target Location. Implications for Battle Management.
13. Wrap-Up. Designing a C4ISR System: Explore the process and trades of
developing a system to meet interoperability and user requirements. Construct
an Operational Concept Matrix, Operational View, System View, KPPs, and
IERs.
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Instructor
John C. Kirk is a Systems Engineer in Radar
and Electronic Warfare for Goleta Engineering.
Mr. Kirk has been involved in Radar and EW since
1956 when he performed flight line maintenance
of the B-52 Radar and ECM Systems. He holds a
patent on the F-16/APG-66 Medium PRF Receiver
and designed the first system to demonstrate real
time digitally correlated SAR from an
intentionally maneuvering platform. Airborneradar experience includes work on the F-4, F-15,
F-16, A-6F, B-1B, B-52 and JSTARS radars. EW
credits include work on the SLQ-32, ALQ-99 and
ALQ-142. He developed a broadband
multifunction surface to air defense system, which
demonstrated simultaneous radar, ECM and
illumination for tracking by Sparrow and Hawk
missile seekers. He has been involved in all
aspects of Radar and EW, from surface to space,
from concept to maintenance.
Summary
This two-day course presents the depth and
breadth of modern Electronic Warfare, covering
Ground, Sea, Air and Space applications, with
simple, easy-to-grasp intuitive principles. Complex
mathematics will be eliminated, while the tradeoffs
and complexities of current and advanced EW andELINT systems will be explored. The fundamental
principles will be established first and then the
many varied applications will be discussed. The
attendee will leave this course with an
understanding of both the principles and the
practical applications of current and evolving
electronic warfare technology. This course is
designed as an introduction for managers and
engineers who need an understanding of the basics.
It will provide you with the ability to understand
and communicate with others working in the field.
A detailed set of notes used in the class will be
provided.
March 25-26, 20048:30am - 4:00pm
Washington DC/MD
$1390
Course Outline
1. Introduction to Electronic Combat. Radar-ESM-ECM-ECCM-LPI-Stealth (EC-ES-EA-EP). Overview of the Threat. RadarTechnology Evolution. EW Technology Evolution. Radar RangeEquation. RCS Reduction. Counter-Low Observable (CLO).
2. Vulnerability of Radar Modes. Air Search Radar. Fire ControlRadar. Ground Search Radar. Pulse Doppler, MTI, DPCA. Pulse
Compression. Range Track. Angle Track. SAR, TF/TA.
3. Vulnerability/Susceptibility of Weapon Systems. Semi ActiveMissiles. Command Guided Missiles. Active Missiles. TVM.Surface-to-air, air-to-air, air-to-surface.
4. ESM (ES). ESM/ELINT/RWR. Typical ESM Systems. Probabilityof Intercept. ESM Range Equation. ESM Sensitivity. ESMReceivers. DOA/AOA Measurement. MUSIC / ESPRIT. PassiveRanging.
5. ECM Techniques (EA). Principals of Electronic Attack (EA).Noise Jamming vs. Deception. Repeater vs. Transponder. SidelobeJamming vs. Mainlobe Jamming. Synthetic Clutter. VGPO andRGPO. TB and Cross Pol. Chaff and Active Expendables. Decoys.Bistatic Jamming. Power Management, DRFM, high ERP.
6. ECCM (EP). EP Techniques Overview. Offensive vs DefensiveECCM. Leading Edge Tracker. HOJ/AOJ. Adaptive SidelobeCanceling. STAP. Example Radar-ES-EA-EP Engagement.
7. EW Systems. Airborne Self Protect Jammer. Airborne TacticalJamming System. Shipboard Self-Defense System.
8. EW Design Illustration. Walk-thru Design of a Typical ESM/ECMSystem from an RFP.
9. EW Technology. EW Technology Evolution. Transmitters.Antennas. Receiver / Processing. Advanced EW.
10. Time-Frequency Processing. Short Time Fourier Transform(STFT). Wavelets.
11. Time-Frequency Transforms. Wigner-Ville, Choi-Williams, FastGabor. Time-Frequency Cube. Examples of Time-FrequencyProcessing.
12. ISAR Design Exercise. In-class design of an ISAR including
determining transmitter power and the ISAR processor.
13. System Design Issues. Automatic Target Recognition (ATR),Speckle and Multilook, ECM & ECCM, IFSAR, Bistatic SAR,Multi-Frequency SAR, Polarametric SAR, Moving Target Imaging,Technology Trends, Future System Requirements.
Ele c tro nic Wa rfa re O ve rvie w
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Fund a m e nta ls o f Ra d a r Te c hnolo g y
Summary
This fast-moving three-day course is designed
for managers and engineers who need an
understanding of the basics of advanced radar
technology. The principles of the various radar
systems are presented and the system design
tradeoffs are discussed in the context of different
mission requirements. This course will provide
the ability to understand and communicate with
radar engineers and project personnel. This
course has also been designed as an introductory
course for higher level and specialized radartopics.
Attendees will receive a copy of the textbook
Introduction to Airborne Radar.
What You Will Learn
Basic math and physics underlying radar
technology
The fundamental concepts of the various radar
systems
The working language of the radar community
The major tradeoffs in radar system
performance
Instructor
Dr. Patrick W. Johnson is a former Navy
Commander and founder and former President
of American Electronics. He is now Sr. VP for
R&D at ZAI, Inc. He received a BS from the
U.S. Naval Academy, an MSEE from the NavalPostgraduate School in Monterey, California,
and his PhD from Queens University in
Kingston, Ontario, Canada. While in the Navy,
he was the OPNAV sponsor for shipboard radar
and target identification systems.
At Amelex, he was the Principal
Investigator for a continuing
series of radar and IFF/ID
programs and projects for the
Army, Navy, Air Force, FAA,
NASA and DARPA.
January 27-29, 2004Colorado Springs, Colorado
May 26-28, 2004Solomons Island, MD
$1390 (8:30am - 4:00pm)
An engaging instructor with extensiveknowledge!
-Recent attendee
Onsite at your convenience
Course Outline
1. Introduction. Definitions, background, course objectives.
2. Radar Basics. Description and functions of radar systemcomponents. Functional block diagrams. Radar phenomena,multipath, radar horizon.
3. Radar Range Equation. Description and interaction of primaryvariables. Major trade-off considerations. Frequency vs. aperture.Mission considerations.
4. Surveillance Radar. Maximum/minimum range selection. Rangeambiguities. Pulse Repetition Frequency (PRF) selection. Pulseduration, Pulse interval.
5. Radar System Considerations. Noise. Probability of Detection(Pd), Probability of False Alarm (Pfa), Signal to Noise Ratio (SNR).
Sensitivity vs. Time (STC) space clutter reduction.
6. Antennas. Antenna gain and directivity. Sidelobe jammervulnerabilities. Sidelobe suppression. Frequency scan, phasescanned antennas. Phase array aperture thinning for sidelobesuppression. Coherent sidelobe cancellation.
7. Tracking Radar. Sequential lobing, conical scan, conical scan onreceive only (COSRO), monopulse. Fire control countermeasures.
8. Radar Detection Theory and Criteria. Binomial approach. M outof N algorithms. Integration, receiver processor gain. Dynamicthresholding.
9. Radar Cross Section. RCS considerations, reduction techniques.Polarization.
10. Modern Radar Systems. Doppler radar, Pulse Compression, Pulse-Doppler waveforms. Blind speeds, ranges. Coherent vs. noncoherentsystems. Moving Target Indicator (MTI).
11. New Technology. Microwave monolithic integrated circuit(MMIC). Conformal arrays, impulse radar, synthetic aperture radar(SAR), inverse synthetic aperture radar (ISAR). Active apertures.
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Fund a m e nta ls o f Ro c ke ts a nd M issile s
SummaryThe seminar is designed for engineers, decision makers
and managers of current and future projects needing a morecomplete understanding of the complex issues of rocket andmissile technology. This course is also relevant forgovernment and industry officials who need anunderstanding of rocket and missile technology. It providesa foundation in the use, regulation and development ofrocket systems of the future. You will learn a wide spectrum
of problems, solutions and choices in the technology ofrockets and missile used for military and civil purposes.
The seminar is taught to the point-of-view of a decisionmaker needing the technical knowledge to make betterinformed choices. How rockets and missiles work, why theyare built the way they are, what they are used for and howthey differ. How rockets and missiles differ when used asweapons, as launch vehicles, and in spacecraft or satellites.
Attendees will receive a complete set of printed notes.These notes will be an excellent future reference for currenttrends in state-of-the-art rocket and missile technology anddecision making.
What You Will Learn Fundamentals of rocket and missile systems.
The spectrum of rocket uses and technologies.
Differences in technology between foreign and domestic rocket systems.
Fundamentals and uses of solid and liquid rocket systems.
Differences between systems built as weapons and those built for commerce.
December 9-11, 2003Dayton, Ohio
May 4-6, 2004
Huntsville, Alabama$1290 (8:30am - 4:00pm)
Course Outline1. Introduction to Rockets and Missiles Introduction to the practical uses of rocket
systems as weapons of war, commerce and the peaceful exploration of space.Classifications of guided, and unguided, missile systems.
2. Rocket Propulsion made Simple. How rocket motors and engines operate to achieve
thrust. Use of the rocket equation and staging theory for rockets and missiles.Introduction to rocket efficiency metrics. Propellant tanks. Introduction to MassProperties.
3. Introduction to Propellant Performance, Utility and Applications. Propellantperformance and mixture ratio issues.Propellant density and specific impulsetheory.Hypergolic propellants.Propellant storability cryogenic propellants.
4. Introducing Solid Rocket Motor Technology. Advantages and disadvantages of solidrocket motors.Solid rocket motor materials, propellant grains and construction.Applications for solid rocket motors as weapons and as cost-effective space systems.
5. Liquid Rocket System Technology. Cryogenic and non cryogenic liquid rocketsystems. Turbo pumps vs pressure-fed rocket engines. Propellant tanks.
6. Foreign vs. American Rocket Technology. Examination of the strengths, andweaknesses, of Domestic, and foreign, rocket technology, and the value of import orexport of technology. How the former Soviet aerospace diverged from Americansystems. Discussion of the issue of developing a space program to disguise a weaponsprogram.
7. Rockets in Spacecraft Propulsion. Examination of the differences between launchvehicle booster systems and that found on spacecraft, satellites and transfer stages.The use of storable and hypergolic propellants. Operations of rocket systems inmicrogravity.
8. Rockets and Missiles as Weapons. Surface to surface, surface to air, ABM and air tosurface weapons. Technology for short, intermediate and long-range weapons.Examination of lethality, probability of kill and accuracy. Active and passiveguidance strategies. Technologies supporting delivery systems for weapons of massdestruction.
9. Rockets and Missiles as Commerce. Civil uses for rockets and missiles, and howthey differ from systems designed as weapons. Uses for satellites in communications,navigation, and imaging.
10. Rockets Systems for Space Exploration and Exploitation. SIssues of expendable
and reusable launch vehicles for future space missions. Missions beyond earth fromthe USA and other nations.
11. Useful Orbits and Trajectories Made Simple. Introduction to simplified orbitalmechanics. Orbital coordinate elements of Inclination, Apogee, Perigee, xxx. Specialorbits; geostationary, sun synchronous and Molnya.
12. Reliability and Safety of Rocket Systems. Introduction to the issues of safety andreliability of rocket and missile systems. A study of the hazards of rocket operations.The causes of failures in rocket systems and strategies to improve reliability isdiscussed.
13. Expendable Launch Vehicle Theory, Selection, Performance and Uses.Understanding the continued dominance of expendable launch vehicles in the field oftransportation from earth to low earth orbit.
14. Reusable Launch Vehicle Theory and Performance. Provide an appreciation andunderstanding of why Reusable Launch Vehicles have had difficulty replacing
expendable launch vehicles since the first operational space shuttle began service, andhow the performance of Reusable Vehicles differs from Expendable systems.
15. The Direction of Technology. A final open discussion regarding the direction of rockettechnology, science, usage and regulations of rockets and missiles is conducted toclose out the class study.
Instructor
Edward L. Keith is a multi-discipline Launch VehicleSystem Engineer, specializing in integration of launchvehicle technology, design, modeling and business
strategies. He is an independent consultant,writer and teacher of rocket systemtechnology. He is experienced in launchvehicle operations, design, testing, businessanalysis, risk reduction, modeling, safetyand reliability. Mr. Keiths experience
extends to both reusable and expendablelaunch vehicles, as well as to both solidand liquid rocket systems. Mr. Keith hasdesigned complete rocket engines, rocket
vehicles, small propulsion systems, and compositepropellant tank systems, especially designed for low cost.Mr. Keith has worked the Space Launch Initiative and the
Liquid Fly-Back Booster programs. He also has 13-years ofgovernment experience including five years working launchoperations at Vandenberg AFB. Mr. Keith has written 18technical papers on various aspects of low cost spacetransportation over the last decade.
Who Should Attend Aerospace Industry Managers.
Government Regulators & Administrators.
Engineers supporting rocket and missile projects.
Contractors or investors involved in missiledevelopment.
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Instructor
For more than 30 years, Thomas S. Logsdon,M. S., has worked on the Navstar GPS and otherrelated technologies at McDonnell Douglas,Lockheed Martin, Boeing Aerospace, andRockwell International. His research projects and
consulting assignments have included the TransitNavigation Satellites, the Tartar and Talosshipboard missiles, and the Navstar GPS. Inaddition, he has helped put astronauts on the moonand guide their colleagues on rendezvous missionsheaded toward the Skylab capsule.
Some of his more challenging assignments havecentered around constellation coverage studies,GPS performance enhancement, militaryapplications, data distribution for differentialnavigation, booster rocket guidance using the GPSsignals and shipboard attitude determination.
Tom Logsdon has taught short courses and
lectured in 24 different countries. He has writtenand published 40 technical papers and journalarticles, a dozen of which have dealt withradionavigation techniques. He is also the author
of 29 technical books on variousengineering and scientific subjects.These include Understanding theNavstar, Orbital Mechanics:
Theory and Applications, Mobile
Communication Satellites, and TheNavstar Global Positioning
System.
G PS Te c hno lo g yG PS Solutio ns on the Ea rth a nd in O ute r Sp a c e
Summary
International authority Thomas Logsdon hasdesigned this popular 4-day short course to meet
the needs of the broadest possible spectrum of
engineers, scientists, technicians, and managers
who are involved in the design, management and
applications of the Global Positioning System.
Each student will receive a new personal GPS
Navigator with a multi-channel capability.
Through practical demonstration you will learn
how the receiver works, how to operate it in various
situations, and how to interpret the positioning
solutions it provides.
Topics are reinforced with practical numericalexamples that include published data.
December 8-11, 2003Arlington, Virginia
May 24-27, 2004Cape Canaveral, Florida
$1495 (8:30am - 4:00pm)
Course Outline1. Radionavigation Principles. Active and passive radionavigation systems.
Spherical and hyperbolic lines of position. Position and velocity solutions.Spaceborne atomic clocks. Websites and other sources of information. Buildinga $104 billion business in space
2. The Three Major Segments of the GPS. Signal structure and psuedorandom
codes. Modulation techniques. Ionospheric and tropospheric corrections.Relativistic time dilations. Inverted navigation solutions.
3. Navigation Solutions and Kalman Filtering Techniques. Taylor seriesexpansions solved by numerical iteration. Doppler shift solutions. Satelliteselection algorithms. Kalman filters.
4. Designing an Effective GPS Receiver. Annotated block diagrams. Antennadesign features. Code tracking and carrier tracking loops. Software modules.Commercial chipsets. Handheld receivers. Shuttle and space station receivers.
5. Military Applications. The world wide common grid. Translator concepts.Elliptical lines of position. Tactical and strategic applications. Autonomy andsurvivability enhancements. Precision guided munitions. Smart bombs andartillery projectiles.
6. Integrated Navigation Systems. Mechanical and Strapdown implementations.Ring lasers and fiber-optic gyros. Integrated navigation. Chassis-level
integration. Key features of the C-MIGITS integrated nav system.7. Differential Navigation and Pseudosatellites. Special committee 104s dataexchange protocols. Global data distribution. Wide-area differential navigation.Psuedosatellite concepts and test results. Indoor GPS systems.
8. Carrier-Aided Solutions. The interferometry concept. Double differencingtechniques. Attitude determination receivers. Navigating the Topex and NASA'stwin Grace satellites. Dynamic and Kinematic orbit determination techniques.Motorolas Spaceborne Monarch receiver. Relativistic time dilation derivations.
9. The Navstar Satellites. Subsystem descriptions. On-orbit test results. TheBlock I, II, IIR and IIF satellites, Block III concepts. Orbital perturbations andmodeling techniques. Stationkeeping maneuvers. Earth shadowingcharacteristics. Repeating ground-trace geometry.
10. Russias Glonass Constellation. Performance comparisons between the GPSand Glonass. Orbital mechanics considerations. Repeating ground-tracegeometry. Spacecraft subsystems. Russias SL-12 Proton booster. Buildingdual-capability GPS/Glonass receivers.
11. Precise Time Synchronization. John Harrisons marine chronometer. Timesynchronization methodologies. Test results. Tomorrows ultra precisespaceborne arrays. Time sync for the International Space Station.
12. Digital Avionics and Air Traffic Control. The FAAs response to the GPS.Dependent surveillance techniques. 3D video displays. The wide-areaaugmentation system. Local area augmentation. Test results. Europe's Galileoconstellation.
13. Using the GPS for Satellite Orbit Determination. Today's spacebornereceivers. Designing satellites to cover the geosynchronous flight regime.Positioning the International Space Station. Precise attitude determination.Space shuttle navigation.
Students
re c e ive afre e G PS
Navigator!
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Id e ntific a tio n, Frie nd o r Fo e (IFF)Se c ond a ry Surve illa nc e Ra d a r (SSR) Be a c on Id e ntific a tion Syste m s
Instructor
Dr. Patrick W. Johnson is a former Navy
Commander and founder and former President
of American Electronics. He is now
Sr. VP for R&D at ZAI, Inc. He
received a BS from the U.S. Naval
Academy, an MSEE from the
Naval Postgraduate School inMonterey, California, and his PhD
from Queens University in
Kingston, Ontario, Canada. While in the Navy,
he was the OPNAV sponsor for shipboard radar
and target identification systems. At Amelex, he
was the Principal Investigator for a continuing
series of radar and IFF/ID programs and
projects for the Army, Navy, Air Force, FAA,
NASA and DARPA.
SummaryThis fast moving three-day course is designed
for managers, engineers and technicians who
need an understanding of the basics of IFF/SSR
radar beacon technology and systems. The
principles of the various IFF/SSR systems are
presented. The system design tradeoffs are
discussed in the context of the different target
identification and air traffic control mission
requirements. This course will provide the ability
to understand and communicate with IFF/SSR
engineers and project personnel.
April 13-15, 20048:30 a.m. - 4:00 p.m.
Washington DC/MD
$1290
Course Outline1. Introduction to Radar Beacon. Identification Systems.Overview of background and course objectives. History ofradar beacon systems.
2. Principles of Operation. Basics of IFF/SSR system. Antennacharacteristics, interrogation and reply signals. Monopulseprinciples. Typical equipment specifications and standards.
3. Ground Antenna Systems. Horizontal and verticalcharacteristics. Backlobes. T/R switch, rotating joint, cablecomponents. Radar colocation.
4. Interrogators. Mode Generator. Transmitters and receivers.Monopulse receivers.
5.Sliding Window Plot Extraction.
Reply decoder. Defruiting.Target detection.6. Monopulse Plot Extraction. Reply processing. Surveillance
processing. False target processing. SSR/PSR combination.7. Transponders. Airborne antenna patterns. Specifications and
conformance to specifications.8. Multipath and Interference.
9. System Design. Radar range equation. Power budgets. Replyand detection probabilities. Transmitter PRF. Bearing accuracy.Antenna height. SSR/PSR Cross coupling.
10. Performance Measurement and Monitoring. Measurement andmonitoring of IFF/SSR systems. Model of SSR environment.
11. Mode S. Reasons for Development. Interrogation and reply
formats. Parity and address. Interrogation and reply types. Datalink applications.
What You Will Learn
Basic math and physics underlying IFF/SSR technology and systems.
The fundamental concepts of the various IFF/SSR radar beacon systems.
The working language of the IFF/SSR community.
The major trade-offs in radar beacon system performance.
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Instructor
Dr. Joseph C. Hassab has over 25 years of
experience in government and industry where he
has been President and Director and has overseen
the definition and development of large and
complex systems. He has published over 100
journal papers in various aspects of systems
analysis and synthesis, sonar/radar signal and data
processing, wave propagation, electromagnetic
scattering, ocean channel modeling, contactlocalization and motion analysis, weapon
targeting, numerical analysis, and expert systems.
Dr. Hassab is the author of two books, Underwater
Signal and Data Processing, and Systems
Management: People, Computers, Machines,
Materials. He has been a referee for several
technical journals and taught courses on radar,
sonar, signal/data processing, and control systems
at several universities and sponsored seminars in
the U.S., Canada, and Europe.
Summary
Widespread availability of top-line military
technologies make the development of actually
integrated combat systems a top priority. Existing
system solutio