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2. A premier university in CALABARZON, offering academic programs and related services designed to respond to the requirements of the Philippines and the global economy, particularly in Asian Countries. VISIONnext back contents 3. The University shall primarily provide advanced education, professional, technological and vocational instruction in agriculture, fisheries, forestry, science, engineering, industrial technologies, teacher education, medicine, law, arts and sciences, information technologies and other related fields. It shall also undertake research and extension services and provide progressive leadership in its areas of specialization.MISSION back next contents 4. In pursuit of the college vision/mission the College of Education is committed to develop the full potentials of the individuals and equip them with knowledge, skills and attitudes in Teacher Education allied fields to effectively respond to the increasing demands, challenges and opportunities of changing time for global competitiveness . GOALS back next contents 5. OBJECTIVES OF BSED Produce graduate who can demonstrate and practice the professional and ethical requirement for the Bachelor of Secondary Education such as: 1.To serve as positive and powerful role models in the pursuit of the learning thereby maintaining high regards to professional growth. 2. Focus on the significance of providing wholesome and desirable learning environment. 3. Facilitate learning process in diverse type of learners. 4. Used varied learning approaches and activities, instructional materials and learning resources. 5. Used assessment data, plan and revise teaching learning plans. 6. Direct and strengthen the links between school and community activities. 7. Conduct research and development in Teacher Education and other related activities. back next contents 6. This Teachers MODULE IN SOLVING QUADRATIC EQUATIONis part of the requirements in Educational Technology 2 under the revised curriculum based on CHED Memorandum Order (CMO)-30, Series of 2004. Educational Technology 2 is a three (3)-unit course designed to introduce both traditional and innovative technologies to facilitate and foster meaningful and effective learning where students are expected to demonstrate a sound understanding of the nature, application and production of the various types of educational technologies.Students are provided with guidance and assistance of selected faculty The members of the College on the selection, production and utilization of appropriate technology tools in developing technology-based teacher support materials. Through the role and functions of computers especially the Internet, the student researchers and the advisers are able to design and develop various types of alternative delivery systems.These kinds of activities offer a remarkable learning experience for the education students as future mentors especially in the preparationand utilization of instructional materials. The output of the groups effort may serveasa contribution to the existing body instructional materials that the institution may utilize in order to provide effective and quality education. The lessons and evaluations presented in this module may also function as a supplementary reference for secondary teachers and students.reference for secondary teachers and students. Aleli M. Ariola Module Developer Shane Maureen D. Atendido Module Developer FOREWORD back next contents 7. This Teachers MODULE IN SOLVING QUADRATIC EQUATIONis part of the requirements in Educational Technology 2 under the revised curriculum based on CHED Memorandum Order (CMO)-30, Series of 2004. Educational Technology 2 is a three (3)-unit course designed to introduce both traditional and innovative technologies to facilitate and foster meaningful and effective learning where students are expected to demonstrate a sound understanding of the nature, application and production of the various types of educational technologies.Students are provided with guidance and assistance of selected faculty The members of the College through the selection, production and utilization of appropriate technology tools in developing technology-based teacher support materials. Through the role and functions of computers especially the Internet, the student researchers and the advisers are able to design and develop various types of alternative delivery systems.These kinds of activities offer a remarkable learning experience for the education students as future mentors especially in the preparation and utilization of instructional materials. The output of the groups effort may serveasa contribution to the existing body instructional materials that the institution may utilize in order to provide effective and quality education. The lessons and evaluations presented in this module may also function as a supplementary reference for secondary teachers and students.reference for secondary teachers and students. FOR-IAN V. SANDOVAL Computer Instructor / Adviser Educational Technology 2 DELIA F. MERCADO Module Consultant / Instructor 3 Principal of Laboratory High School LYDIA R. CHAVEZ Dean College of Education FOREWORD back next contents 8. The authors would like to acknowledge with deep appreciation and gratitude the invaluable help of the following persons: Mr. For-Ian V. Sandoval our module adviser, Computer Instructor / Adviser Educational Technology 2 for giving us opportunity to participate on this project, and for guiding us and pursue us to finish this module. Mrs. Delia F. Mercado, Instructor III and Director of Laboratory High School, for being our Teacher Consultant for the completion of this modular workbook. Mrs. Corazon San Agustin, our instructor in Educational Technology I, for giving us guidance and encouragement us in completing the requirement.Mrs. Lydia Chavez, Dean of Education for the support and guidance. We also wish to thank our family and friends as an inspiration and understand us they were robbed of many precious moments as we looked ourselves in our rooms when our minds went prolific and our hands itched to write. And finally, we thank Almighty God, the source of all knowledge, understanding and wisdom. From him we owe all that we have and all that we are!Once again, we thank all those who have encourage and helped us in preparing this module for publication and who have extended us much understanding, patience, and support. THE AUTHORS Acknowledgement back next contents 9. Aquadratic equationis a second-order polynomial equatio nin a single variable x.Thegeneral form iswherexrepresents a variable, anda ,b , andc , represent coefficients and constants, witha 0. (Ifa= 0, the equation becomes a linear equation.) Among his many other talents, Major General Stanley in Gilbert and Sullivan's operettathe Pirates of Penzanceimpresses the pirates with his knowledge of quadratic equations in "The Major General's Song" as follows: "I am the very model of a modern Major-General, I've information vegetable, animal, and mineral, I know the kings of England, and I quote the fights historical, From Marathon to Waterloo, in order categorical; I'm very well acquainted too with matters mathematical, I understand equations, both the simple and quadratic, About binomial theorem I'm teeming with a lot o' news-- With many cheerful facts about the square of the hypotenuse."The constantsa ,b , andc , are called respectively, the quadratic coefficient, the linear coefficient and the constant term or free term. Quadratic comes fromquadratus , which is the Latin word for "square." Quadratic equations can be solved by factoring, completing the square, graphing, Newton's method, and using the quadratic formula. One common use of quadratic equations is computing trajectories in projectile motion. This module centers on the different ways of solving the quadratic equation by factoring, by finding square roots, by completing the square, and by using the quadratic formula. Students are given guides to determine the most appropriate method to use. Identifying the disciminant of the quadratic equation and finding the relationship between the coefficient and the root of the quadratic equation are also discussed.Introduction back next contents 10. General Objectives
back next contents 11. Table of Contents VMGO s of BSEdForewordAcknowledgement Introduction General Objective s Table of Contents Chapter I.Identify the Quadratic EquationLesson 1. Quadratic EquationChapter II.Complex Number Lesson 2. Defining Complex Number Lesson 3. Numberi Lesson 4. Complex Plane Lesson 5. Complex Arithmetic Chapter III.Solving Quadratic Equation Lesson 6. FactoringLesson 7. Completing the Square Lesson 8. Quadratic Formula Lesson 9. Solving by Graphing contents back next 12. Chapter IV.Solving Equation on QuadraticLesson 10. Equation in Quadratic Form Lesson 11. Equation Containing Radicals Lesson 12. Equation Reducible to Quadratic Equation Chapter V.The Discriminant, Roots and CoefficientLesson 13. Discriminant and the Roots of a Quadratic Equation Lesson 14. Relation between Roots and CoefficientChapter VI.Solving Quadratic Equation on a Calculator Lesson 15. Equation on a CalculatorReferences Demo (aleli) Demo (shane) Slide share (aleli) Slide share (shane) contents back next 13. Chapter I This chapter deals with equations which are classified according to the highest power of its variable. An equation in the variable x whose highest power is 2 is called a quadratic equation. It will be observed here that variable a, b and c are real numbers and a cannot be 0.
Definition of Quadratic Equation contents back next 14. Lesson 1 Identifying the quadratic equation
Polynomials are classified according to the highest power of its variable. A first degree polynomial, like 2x + 5 is linear; a second degree polynomial, like x 2+ 2 3 is quadratic; a third degree polynomial, like x 3+ 4x 2 3x + 12 is cubic. Similarly, equation and inequalities are classified according to the highest power of its variable. An equation in the variable x whose highest power is two is called a quadratic equation. Some examples are x 2 64, 4n 2= 25, 3x 2 4x + 1 = 0. An equation of the form ax 2+ bx + c = 0, where a, b and c are constant and a not equal to 0, a id a quadratic equation. to 0, a id a quadratic equation. Any quadratic equation can be written in the forma x 2+ bx + c = 0. This is also called the standard form of the quadratic equation. Here, a, b and c are real numbers and a cannot be 0. Example A. Express x 2= 8x in standard form x 2= 8x can be written as x 2- 8x = 0 where a=1, b= 8, and c=0. Example B. Express x 2= 64 in standard form next back contents 15.
next back contents 16. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: _______ Instruction : Write the following equations in the form ax 2+ bx + c = 0, and give the value of a, b, and c. 1. x 2= 6x _____________________________________________ 2. 2x 2= 32 _____________________________________________3. 3 x2= 5x 1_____________________________________________ 4. 10 = 3x x 2 _____________________________________________ 5. (x + 2) 2= 9 _____________________________________________ 6. 4x 2= 64 _____________________________________________ Activity 1.1 Identifying Quadratic Equation next back contents 17. _____________________________________________ 8x = x 2 _____________________________________________ 7. 8. 9. 10. 11. 12. 13. 14. 15. _____________________________________________ 2 = 6 _____________________________________________ x 2=x 2+_____________________________________________ (x + 1)(x-3) = 6 _____________________________________________ _____________________________________________ _____________________________________________ _____________________________________________ contents back next 18.
Chapter Test contents back next 19. Chapter II This chapter centers on the complex numbers which is a number comprising a real number and an imaginary number. Under this, we have the number i, the complex plane where the points are plotted and the 4 arithmetic operations such as addition and subtraction, multiplication and division of complex numbers. To round up the chapter, simple equation involving complex numbers will be studied and solved.
Complex Numbers contents back next 20. Lesson 2 Defining Complex Numbers
A complex number, in mathematics, is a number comprising a real number and an imaginary number; it can be written in the forma + bi , whereaandbare real numbers, andiis the standard imaginary unit, having the property thati 2= 1. The complex numbers contain the ordinary real numbers, but extend them by adding in extra numbers and correspondingly expanding the understanding of addition and multiplication. Equation 1: x 2- 1 = 0. Equation 1 has two solutions, x = -1 and x = 1. We know that solving an equation in x is equivalent to finding the x-intercepts of a graph; and, the graph of y = x 2- 1 crosses the x-axis at (-1,0) and (1,0). next back contents 21. Equation 2: x 2+ 1 = 0 Equation 2 has no solutions, and we can see this by looking at the graph of y = x 2+ 1. Since the graph has no x-intercepts, the equation has no solutions. When we define complex numbers, equation 2 will have two solutions. next back contents 22. Name: ___________________Section: _______ Instructor: ________________Date: ________ Rating: _______ Solve each equation and graph. 1. x + 4 = 0 _____________________________________________ 2. 2x + 18 = 0 _____________________________________________ 3. 2x + 14 = 0 _____________________________________________ 4. 3x + 27 = 0 _____________________________________________ 5. x - 3 = 0_____________________________________________ 6. x + 21 = 0 _____________________________________________ Activity 2.1 Defining Complex Number next back contents 23. 7. 3x - 5 = 0 _____________________________________________ 8. 5x + 30 = 0 _____________________________________________ 9. 2x + 3 = 0 _____________________________________________ 10. x + 50 = 0 _____________________________________________ 11. x - 2 = 0 _____________________________________________ 12. 3x - 50 = 0 _____________________________________________ 13. x - 3 = 0 _____________________________________________ 14. x + 4 = 0 _____________________________________________ 15. 2x + 14 = 0 _____________________________________________ contents back next 24. Lesson 3 The Number i
Consider Equations 1 and 2 again. Equation 1 has solutions because the number 1 has two square roots, 1 and -1. Equation 2 has no solutions because -1 does not have a square root. In other words, there isnonumber such that if we multiply it by itself we get -1. If Equation 2 is to be given solutions, then we must create a square root of -1. The imaginary unitiis defined by The definition ofitells us thati 2= -1. We can use this fact to find other powers ofi . Equation 1 Equation 2x 2- 1 = 0. x 2+ 1 = 0.x 2= 1. x 2= -1.contents back next 25. Example i 3=i 2*i= -1* i= - i. i 4=i 2*i 2= (-1) * (-1) = 1. Exercise: Simplifyi 8andi 11 .We treatilike other numbers in that we can multiply it by numbers, we can add it to other numbers, etc. The difference is that many of these quantities cannot be simplified to a pure real number. For example, 3 ijust means 3 timesi , but we cannot rewrite this product in a simpler form, because it is not arealnumber. The quantity 5 + 3 ialso cannot be simplified to a real number. However, (- i ) 2can be simplified. (- i ) 2= (-1* i ) 2= (-1) 2*i 2= 1 * (-1) = -1. Becausei 2and (- i ) 2are both equal to -1, they are both solutions for Equation 2 above. contents back next 26. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: ______ Instruction:Express each number in terms ofiand simplify. 1. 2. 3. 4. 5. ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ Activity 2.2 Number i next back contents 27. 6.7. 8. 9. 10. 11. 12. 13. ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ next back contents 28. Lesson 4 The Complex Plane
A complex number is one of the form a + b i , where a and b are real numbers. a is called thereal partof the complex number, and b is called theimaginary part . Two complex numbers are equal if and only if their real parts are equal and their imaginary parts are equal. I.e., a+bi = c+di if and only if a = c, and b = d. Example. 2 - 5i. 6 + 4i. 0 + 2i = 2i. 4 + 0i = 4. The last example above illustrates the fact that every real number is a complex number (with imaginary part 0). Another example: the real number -3.87 is equal to the complex number -3.87 + 0 i . It is often useful to think of real numbers as points on a number line. For example, you can define the order relation c < d, where c and d are real numbers, by saying that it means c is to the left of d on the number line. next back contents 29. We can visualize complex numbers by associating them with points in the plane. We do this by letting thenumbera + b icorrespond to thepoint(a,b), we use x for a and y for b.
contents back next 30. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: ______ Instruction:Represent each of the following Complex Numbers by a point in the plane. 1. 2. 3. 4.0 5.3 6. 7.1/2 8. ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ ______________________________________________________ Activity 2.3 Complex Plane contents back next 31. 9. 10. 11. 12. 13. 14. 15. _____________________________________________________ _____________________________________________________ _____________________________________________________ ____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ contents back next 32. Lesson 5 Complex Arithmetic
When a number system is extended the arithmetic operations must be defined for the new numbers, and the important properties of the operations should still hold. For example, addition of whole numbers is commutative. This means that we can change the order in which two whole numbers are added and the sum is the same: 3 + 5 = 8 and 5 + 3 = 8. We need to define the four arithmetic operations on complex numbers. Addition and Subtraction To add or subtract two complex numbers, you add or subtract the real parts and the imaginary parts. Example(3 - 5i) + (6 + 7i) = (3 + 6) + (-5 + 7)i = 9 + 2i. (3 - 5i) - (6 + 7i) = (3 - 6) + (-5 - 7)i = -3 - 12i. (a + bi) + (c + di) = (a + c) + (b + d)i. (a + bi) - (c + di) = (a - c) + (b - d)i. next back contents 33. Note These operations are the same as combining similar terms in expressions that have a variable. For example, if we were to simplify the expression (3 - 5x) + (6 + 7x) by combining similar terms, then the constants 3 and 6 would be combined, and the terms -5x and 7x would be combined to yield 9 + 2x. The Complex Arithmetic applet below demonstrates complex addition in the plane. You can also select the other arithmetic operations from the pull down list. The applet displays two complex numbers U and V, and shows their sum. You can drag either U or V to see the result of adding other complex numbers. As with other graphs in these pages, dragging a point other than U or V changes the viewing rectangle. Multiplication The formula for multiplying two complex numbers is (a + bi) * (c + di) = (ac - bd) + (ad + bc)i. You do not have to memorize this formula, because you can arrive at the same result by treating the complex numbers like expressions with a variable, multiply them as usual, then simplify. The only difference is that powers of i do simplify, while powers of x do not. Example(2 + 3i)(4 + 7i) = 2*4 + 2*7i + 4*3i + 3*7*i 2 = 8 + 14i + 12i + 21*(-1) = (8 - 21) + (14 + 12)i = -13 + 26i. next back contents 34. Notice that in the second line of the example, the i 2has been replaced by -1. Using the formula for multiplication, we would have gone directly to the third line. ExercisePerform the following operations. (a) (-3 + 4i) + (2 - 5i) (b) 3i - (2 - 4i) (c) (2 - 7i)(3 + 4i) (d) (1 + i)(2 - 3i) Division The conjugate (or complex conjugate) of the complex number a + bi is a - bi. Conjugates are important because of the fact that a complex number times its conjugate is real; i.e., its imaginary part is zero. (a + bi)(a - bi) = (a 2+ b 2 ) + 0i = a 2+ b 2 . ExampleNumber Conjugate Product 2 + 3i 2 - 3i 4 + 9 = 13 3 - 5i 3 + 5i 9 + 25 = 34 4i -4i 16 next back contents 35. Suppose we want to do the division problem (3 + 2i) (2 + 5i). First, we want to rewrite this as a fractional expression. Even though we have not defined division, it must satisfy the properties of ordinary division. So, a number divided by itself will be 1, where 1 is the multiplicative identity; i.e., 1 times any number is that number. So, when we multiplyby,, we are multiplying by 1 and the number is not changed. Notice that the quotient on the right consists of the conjugate of the denominator over itself. This choice was made so that when we multiply the two denominators, the result is a real number. Here is the complete division problem, with the result written in standard form. back next contents 36. Exercise: Write (2 - i) (3 + 2i) in standard form.We began this section by claiming that we were defining complex numbers so that some equations would have solutions. So far we have shown only one equation that has no real solutions but two complex solutions. In the next section we will see that complex numbers provide solutions for many equations. In fact, all polynomial equations have solutions in the set of complex numbers. This is an important fact that is used in many mathematical applications. Unfortunately, most of these applications are beyond the scope of this course. See your text (p. 195) for a discussion of the use of complex numbers in fractal geometry. back next contents 37. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction:Perform the indicated operations and express the result in the form. 1. 2. 3. 4. 5. 6. 7. _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ Activity 2.4 Complex Arithmetic back next contents 38. 8. 9. 10. 11. 12. 13. 14. 15. _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ next back contents 39.
Chapter Test next back contents 40.
next back contents 41. Chapter III In this chapter, the different ways of solvingthe quadratic equation are recalled. There are by using the factoring, completing the square, by quadratic formula and solving by graphing. Students are given guides to determine the most appropriate method to use.
Solving Quadratic Equation back next contents 42. Lesson 6 Solving by factoring
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next back contents 47. Name: ___________________Section: _______ Instructor: ________________Date: ________ Rating: _______ Instruction:Solve the following Quadratic Equation by Factoring Method. 1. x 2 36 = 0 _____________________________________________________ 2. x 2 = 25 _____________________________________________________ 3. x 2 12x + 35 = 0 _____________________________________________________ 4. x 2 3x 40 = 0 _____________________________________________________ 5. 2x 2 5x = 3 _____________________________________________________ 6. 3x 2+ 25x = 18 _____________________________________________________ 7. 15x 2 2x 8 = 0 _____________________________________________________ Activity3.1 Solving Quadratic Equation contents back next 48. 8. 3x 2 x = 10 _____________________________________________________ 9. x 2+ 6x 27 = 0 _____________________________________________________ 10. y 2 2y 3 = y 3 _____________________________________________________ 11. 4y 2+ 4y = 3 _____________________________________________________ 12. 3a 2+ 10a = -3 _____________________________________________________ 13. a 2 2a 15 = 0 _____________________________________________________ 14. r 2+ 6r 27 = 0 _____________________________________________________ 15. 2z 2 2 1 = 0 _____________________________________________________ next back contents 49. Lesson 7 Solving by Completing the Square
next back contents 50. The answer can also be written in rounded form asnext back contents 51.
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contents back next 53. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: ____ Instruction:Solve the following Quadratic Equation by Completing the Square. 1. x 2+ 3x = 4 _____________________________________________________ 2. x 2 2x = 24 _____________________________________________________ 3. x 2+ 4 = 4x _____________________________________________________ 4. 2x 2 6 = x _____________________________________________________ 5. 4a 2+ 12a + 9 = 0 _____________________________________________________ 6. 3a 2 5 = 14a _____________________________________________________ 7. 16b 2+ 1 = 16b _____________________________________________________ Activity 3.2 Completing the Square contents back next 54. 9. 9z 2+ 30z + 20 = 0 _____________________________________________________ 10. 2a 2+ a = 10a _____________________________________________________ 11. 2x 2+ 17 = 10x _____________________________________________________ 12. 2a 2+ 6a + 9 = 0 _____________________________________________________ 13. 5x 2 2x + 1 = 0 _____________________________________________________ 14. 3x 2+ 2x + 1= 0 _____________________________________________________ 15. 2y 2+ 5y = 42 _____________________________________________________ 8. 9b 2 6b 1 = 0 _____________________________________________________ next back contents 55. Lesson 8 Quadratic Formula
The following steps will serve as guide in solving this method. Step 1. First subtractcfrom both sides of the equation and then, divide both sides by(a # 0 by hypothesis) to obtain the equivalent equation, x 2+=Step 2. Complete the left-hand side in to the perfect square. x 2+ bx/a + (b/2a) 2= (b/2a) 2 c/a or (x+b/2a) 2= (b 2 -4ac)/4a 2 Step 3. Take the square roots of both sides of the last equation. (x+b/2a) = (/2a next back contents 56. Step 4. Solve for x. x = orLet a, b and c be real constant, where a 0. Then the roots of ax 2+ bx + c = 0 are x =The above formula is referred to as the quadratic formula. Example: Solvea. 3x 2 x 5/2 = 0 Solutions: Here a=3, b= 1, c= 5/2 Substituting these values in the quadratic formula we obtain x = = = ==The roots areand.
next back contents 57. Here a=2, b= 5 c=2. By the quadratic formula x ==The roots are 2and.. Note that the expression 2x 2 5x + 2 can be factored as 2x 2 5x + 2 = (2x 1) (x 2)
contents back next 58. Name: ___________________Section: _______ Instructor: ________________Date: ________ Rating: ______ Instruction:Solve the following equations by the Quadratic Formula. 1. 2a 2 10 = 9 _____________________________________________________ 2. 6b 2 b = 12 _____________________________________________________ 3. 3x 2+ x = 14 _____________________________________________________ 4. 10a 2+ 3 = 11a _____________________________________________________ 5. 2x 2+ 5x = 12 _____________________________________________________ 6. 4x 2+ 5x = 21 _____________________________________________________ Activity 3.3 Quadratic Formula contents back next 59. 7. 2x 2 7x + 3 = 0 _____________________________________________________ 8. 3a 2 6a + 2 = 0 _____________________________________________________ 9. 3b 2 2b 4 = 0 _____________________________________________________ 10 a 2 3a 40 = 0 _____________________________________________________ 11. 3y 2 11y + 10 = 0 _____________________________________________________ 12. 3w 2= 9 + 2w _____________________________________________________ 13. 15z 2+ 22z = 48 _____________________________________________________ 14. 9a 2+ 14 = 24a _____________________________________________________ 15. 16m 2= 24m + 19 _____________________________________________________ contents back next 60. Lesson 9 Solving "by Graphing
To be honest, solving "by graphing" is an achingly trendy but somewhat bogus topic. The basic idea behind solving by graphing is that, since the "solutions" to " ax 2+bx+c= 0" are thex -intercepts of " y=ax 2+bx+c ", you can look at thex -intercepts of the graph to find the solutions to the equation. There are difficulties with "solving" this way, though.... When you graph a straight line like " y= 2 x+ 3", you can find thex -intercept (to a certain degree of accuracy) by drawing a really neat axis system, plotting a couple points, grabbing your ruler and drawing a nice straight line, and reading the (approximate) answer from the graph with a fair degree of confidence.On the other hand, a quadratic graphs as a wiggly parabola. If you plot a few non- x -intercept points and then draw a curvy line through them, how do you know if you got thex -intercepts even close to being correct? You don't. The only way you can be sure of yourx -intercepts is to set the quadratic equal to zero and solve. But the whole point of this topic is that they don't want you to do the (exact) algebraic solving; they want you to guess from the pretty pictures. So "solving by graphing" tends to be neither "solving" nor "graphing". That is, you don't actually graph anything, and you don't actually do any of the "solving". Instead, you are told to punch some buttons on your graphing calculator and look at the pretty picture, and then you're told which other buttons to hit so the software can compute thecontents back next 61.
The graph is of the related quadratic,y=x 2 8 x+ 15, with thex -intercepts being wherey= 0. The point here is to look at the picture (hoping that the points really do cross at whole numbers, as it appears), and read thex -intercepts (and hence the solutions) from the picture. The solution isx= 3,Sincex 2 8 x+ 15 factors as ( x 3)( x 5), we know that our answer is correct.contents back next 62.
For this picture, they labeled a bunch of points. Partly, this was to be helpful, because thex -intercepts are messy (so I could not have guessed their values without the labels), but mostly this was in hopes of confusing me, in case I had forgotten that only thex -intercepts, not the vertices ory -intercepts, correspond to "solutions". Thex -values of the two points where the graph crosses thex -axis are the solutions to the equation. The solution isx =5 / 3 ,10 / 3
contents back next 63. They haven't given me the quadratic equation, so I can't check my work algebraically. (And, technically, they haven't even given me a quadratic to solve; they have only given me the picture of a parabola from which I am supposed to approximate thex -intercepts, which really is a different question....) I ignore the vertex and they -intercept, and pay attention only to thex -intercepts. The "solutions" are thex -values of the points where the pictured line crosses thex -axis: The solution isx = 5.39, 2.76 "Solving" quadratics by graphing is silly in "real life", and requires that the solutions be the simple factoring-type solutions such as " x= 3", rather than something like " x= 4 + sqrt(7)". In other words, they either have to "give" you the answers (by labeling the graph), or they have to ask you for solutions that you could have found easily by factoring. About the only thing you can gain from this topic is reinforcing your understanding of the connection between solutions andx -intercepts: the solutions to "(some polynomial) equals (zero)" correspond to thex -intercepts of " yequals (that same polynomial)". If you come away with an understanding of that concept, then you will knowwhen best to use your graphing calculator or other graphing software to help you solve general polynomials; namely, when they aren't factorable. contents back next 64. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: ______ Instruction:Solve each equation by graphing. 1. x 2 6x + 9 = 0 _____________________________________________________ 2. x 2 5x + 10 = 0 _____________________________________________________ 3. 2x 2 6x + 8 = 0 _____________________________________________________ 4. x 2 7x + 12 = 0 _____________________________________________________ 5. 2x 2 8x + 10 = 0_____________________________________________________ 6. 3x 2+ 6x 9 = 0 _____________________________________________________ 7. x 2 + 8x 12 = 0 _____________________________________________________ Activity 3.4 solving by graphing contents back next 65. 8.2+ 4x 3 = 0 _____________________________________________________ 9. x 2 2x 2 = 0 _____________________________________________________ 10. 2x 2 4x 2 = 0 _____________________________________________________ 11. 4x 2 8x 16 = 0 _____________________________________________________ 12. x 2 9x + 21 = 0 _____________________________________________________ 13. x 2+ 10x + 18 = 0 _____________________________________________________ 14. 2x 2 16x + 8 = 0 _____________________________________________________ 15. 3x 2 12x 9 = 0_____________________________________________________ contents back next 66.
Chapter Test contents back next 67. Chapter IV Much of the study in quadratic equation consist of different solving equation, we have equation in quadratic form, equation containing radicals and equation reducible to quadratic equation. They have their own steps and procedures to be followed in order to solve the given equation.
Solving Equation on Quadratic contents back next 68. Lesson 10 Equation in Quadratic Form
Quadratic in Form An equation is quadratic in form when it can be written in this standard form where the same expression is inside both ( )'s. In other words, if you have a times the square of the expression following b plus b times that same expression not squared plus c equal to 0, you have an equation that is quadratic in form.If we substitute what is in the ( ) with a variable like t, then the original equation will become a quadratic equation. contents back next 69. SolvingEquations that areQuadratic in Form Step 1: Write in Standard Form,, if needed. Step 2: Substitute a variable in for the expression that follows b in the second term.Step 3: Solve the quadratic equation created in step 2.Step 4: Find the value of the variable from the original equation.If it is not in standard form, move any term(s) to the appropriate side by using the addition/subtraction property of equality.Also, make sure that the squared term is written first left to right, the expression not squared is second and the constant is third and it is set equal to 0. In other words, substitute your variable for what is in the ( ) when it is in standard form, .Im going to use t for my substitution, but really you can use any variable as long as it is not the variable that is used in the original equation. You can use any method you want to solve the quadratic equation: factoring, completing the square or quadratic formula. Keep in mind that you are finding a solution to the original equation and that the variable you substituted in for in step 2 is not your original variable.Use the substitution that was used to set up step 2 and then solve for the original variable. contents back next 70. Step 5: Check your solutions.Example 1: Solve the equation that is quadratic in form: . In some cases, you will be working with rational exponents and square roots in your problems. Those types of equations can cause extraneous solutions. Recall that an extraneous solution is one that is a solution to an equation after doing something like raising both sides of an equation by an even power, but is not a solution to the original problem.Even though not all of the quadratic in form equations can cause extraneous solutions, it is better to be safe than sorry and just check them all. Standard Form,*Rewriting original equation to show it is quadratic in form*Note that (y squared) squared = y to the fourth*When in stand. form, let t = the expression following b. Next, we need to substitute t in for y squared in the original equation. *Original equation*Substitute t in for y squared next back contents 71. Note how we ended up with a quadratic equation when we did our substitution. From here, we need to solve the quadratic equation that we have created. Solve the quadratic equation: factoring, completing the square or quadratic formula.*Factor the trinomial*Use Zero-Product Principle*Set 1st factor = 0 and solve*Set 2nd factor = 0 and solve next back contents 72. Let's find the value(s) of y when t = -4: *Plug in - 4 for t*Use square root method to solve for y*First solution*Second solution Let's find the value(s) of y when t = 1: *Plug in 1 for t*Use square root method to solve for y*First solution*Second solution next back contents 73. Example 2: Solve the equation that is quadratic in form: . Standard Form,*Inverse of add. 3 is sub. 3*Equation in standard form Note how when you square x to the 1/3 power you get x to the 2/3 power, which is what you have in the first term. * Rewriting original equation to show it is quadratic in form*Note that (x to the 1/3 power) squared = x to the 2/3 power*When in stand. form, let t = the expression following b. Next, we need to substitute t in for x to the 1/3 power in the original equation. next back contents 74. *Original equation*Substitute t in for x to the 1/3 power You can use any method you want to solve the quadratic equation: factoring, completing the square or quadratic formula. *Factor the trinomial*Use Zero-Product Principle*Set 1st factor = 0 and solve*Set 2nd factor = 0 and solve next back contents 75. Let's find the value(s) of x when t = 3: *Plug in 3 for t*Solve the rational exponent equation*Inverse of taking it to the 1/3 power israising it to the 3rd power Let's find the value(s) of x when t = -1: *Plug in -1 for t*Solve the rational exponent equation*Inverse of taking it to the 1/3 power israising it to the 3rd power Let's double check to see if x = 27 is a solution to the original equation. *Plugging in 27 for x*True statement next back contents 76.
Since we got a true statement, x = 27 is a solution. Let's double check to see if x = -1 is a solution to the original equation. *Plugging in -1 for x*True statement Since we got a true statement, x = -1 is a solution. There are two solutions to this equation: x = 27 and x = -1. next back contents 77. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction:Solve the equation that is in quadratic form. 1. a 8+ 2a 4 8 = 0 _____________________________________________________ 2. l 2+ 4l 2 6 = 0 _____________________________________________________ 3. e 4 8e 2 3 = 0 _____________________________________________________ 4. l 6 10l 5 = 0 _____________________________________________________ 5. i 10 8i 5 4 = 0 _____________________________________________________ 6. s 6 5s 3 25 = 0 _____________________________________________________ Activity 4.1 Solving Equation on Quadratic next back contents 78. 7. h 2/4+ 8h 1/4 12 = 0 _____________________________________________________ 8. a 6 - 5a 4 15 = 0 _____________________________________________________ 9. n 8+ 12n 2 8 = 0 _____________________________________________________ 10. e 9 3n 3 10 = 0 _____________________________________________________ 11. x 2/3 2x1/3= 8 _____________________________________________________ 12. x 3/6 3x 1/2= 9 _____________________________________________________ 13. y 2 - 8y = 5 _____________________________________________________ 14. y 4+ 2y 2= 6 _____________________________________________________ 15. x 6 9x 2+ 8 = 0 _____________________________________________________ next back contents 79. Lesson 11 Equation Containing Radicals
In the radicalswhich is read the nth root of b, the positive integer n is called the index or order of the radical, and b is called its radicand. When n is 2, 2 is no longer written, just simply writeinstead ofto indicate the square root of b, thusis read as cube root of b;as 4 thof b.
next back contents 80. Example 1:First make a note of the fact that you cannot take the square root of a negative number. Therefore, theterm is valid only ifand the second termis valid ifIsolate thetermSquare both sides of the equation. IsolatethetermSquare both sides of the equation.Check the solution by substituting 9 in the original equation for x. If the left side of the equation equals the right side of the equation after the substitution, you have found the correct answer.next back contents 81.
.The graph represents the right side of the original equation minus the left side of the original equation.. The x-intercept(s) of this graph is (are) the solution(s). Since there are no x-intercepts, there are no solutions.Exercises:Solve each of the following equation. 1.= 3 2.= x + 1 3.= 4.= 5 5.= 10 = 5 contents back next 82. Name: ___________________Section: _______ Instructor: ________________Date: _______ Rating: ______ Instruction:Solve each of the following equation. 1. 2. 3. 4. 5. 6. _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ Activity 4.2 Equation Containing Radicals contents back next 83. 7. 8. 9. 10. 11. 12. 13. 14. 15. ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ ____________________________________________________ contents back next 84. Lesson 12 Equations Reducible to Quadratic Equations
A variety of equations can be transformed into quadratic equations and solved by methods that we have discussed in the previous section. We will consider fractional equations, equations involving radicals and equation that can be transformed into quadratic equations by appropriate substitutions. Since the transformation process may introduce extraneous roots which are not solutions of the original equation, we must always check the solution in the original equation. Example: Solve1 1 7 x+2 + x+3 = 12 Solution:First note that neither -2 nor -3 can be a solution since at either of these points the equation is meaningless. Multiplying by the LCD, 12(x+2) (x+3), we get 12(x+3) + 12(x+2) = 7(x+2) (x+3) 24x + 60 = 7(x 2+ 5x + 6) or 7x 2+ 11x 18 = 0 Factoring, we get, (7x + 18)(x 1) = 0 contents back next 85. x = 1 or-187 If x = 1, _ 1__ 1_ _ 1_ _ 1_ _ 7_ 1+2 1+3 = 3 +4 =12 Therefore x = 1 is a solution. If x =-18 ,__ 1__ +__ 1__ 7-18/7 + 2-18/7 + 3 = __ 7 __+__ 7 __ -18 + 14-18 + 21 = _ -7 _ + _ 7 _ = _ 7 _ 4312 Therefore, x =_-18 _ is a solution. 7 Example 2.=- 2Solution: squaring both sides of the equation, we obtain, =+ 4 2x 16 = 4 contents back next 86. Dividing both sides by 2 gives, x 8 = -2Squaring both sides of the equation we get(x - 8) =2 x 2- 16x + 64 = 4 (x +16) x 2 20x = 0x(x 20) =0 x = 0 or x = 20Check: if x = 0,= =8 = 6 28 4 Therefore x = 20 is not a solution of the original equation. Thus the only root ofMany equations are not quadratics equations. However, we can transform them by means of appropriate substitutions into quadratics equations and then solve these by techniques that we know. contents back next 87.
2
or x -1= 3, from which x = 2 or x = Check: if x = 2, 2(2 -2 ) 7(2 -1 ) + 3 =Thus x = 2 is solution If x = 1/3, 2(1/3) -2 7(1/3) -1+ 3 = 2(3) 2 7(3) + 3 So, x = 1/3 is a solution. b. Let u = x 2 . Then u 2= x 4and the given equation becomes a quadratic equation in u. u 2 2u 2 = 0 contents back next 88. u ==u = 1 +or u =Since u = x 2and u =< 0, we have to discard this solution. u = x 2=implies x = It is simple to verify that both values of x satisfy the original equation. The roots of x 4 x 2 2 = 0 areand -. c. Let u =.This substitution yields a quadratic equation in u. u 2 u 2 = 0(u 2)(u + 1) = 0u = 2 0r u = 1 u == 2impliesx = 2(4x + 1) orx =u == 1impliesx = 4x 1 orx =Again, it can easily be verified that both solutions check in the original equation. The roots areand. contents back next 89. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction:Solve the following equation. 1. 2. 3. 4. 5. 6. _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ Activity 4.3 Equation Riducible to Quadratic Equation contents back next 90. _____________________________________________________ 7. 8. 9. 10. 11. 12. 13. 14. 15. _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ _____________________________________________________ contents back next 91. Chapter Test A. Solve forx.1.= 42.- 5 = 0 3.= 4.= 5.= x + 2 B. Reduce to quadratic equation. 1. x 4 5x + 4 = 0 2. 4(x + 3) + 5= 21 3. x 2/3 5x 1/3 6 = 0 4. (x 2+ 4x) 2 (x 2+ 4x) = 20 5. 2x 4 9x 2+ 7 = 0 C. Solve for x. 1.+= 2.++= 0 3.+= 4.+= 2 5.+= next back contents 92. Chapter V The discriminant gives additional information on the nature of the roots beyond simply whether there are any repeated roots: it also gives information on whether the roots are real or complex, and rational or irrational. More formally, it gives information on whether the roots are in the field over which the polynomial is defined, or are in an extension field, and hence whether the polynomial factors over the field of coefficients. This is most transparent and easily stated for quadratic and cubic polynomials; for polynomials of degree 4 or higher this is more difficult to state.
The Discriminant, Roots and Coefficient next back contents 93. Lesson 13 The Discriminant and the roots of a Quadratic Equation
Example 1. Find the x-intercept of y = 3x - 6x + 4. Solution: As already mentioned, the values of x for which 3x - 6x + 4 = 0 give the x-intercepts of the function. We apply the quadratic formula in solving the equation. 3x - 6x + 4 = 0 x ==Sinceis not a real number, the equation 3x - 6x + 4 = 0 has no real root. This means that the parabola y = 3x - 6x + 4 does not intersect the x-axis. Let us write the equation in the form y = a(x h)+ k. y = 3(x 2x) + 4 = 3(x 1) + 1 next back contents 94. Example 2. Use the disciminant to determine the nature of the roots of thefollowing quadratic equation. a. x - x + = 0 a = 1, b = 1, c = b - 4ac = (1) - 4 (1)() = 1 1 = 0 There is only one solution, that is, a double root. Note that x - x = = (x - ), so that double root is b/2a = . b. 5x - 4x + 1 = 0 a = 5, b = 4, c = 1 b - 4ac = (4) - 4 (5)(1) = 16 20 = 4 < 0 There are no real roots since a negative number has no real square root. = b - 4ac Roots of ax + bx + c = 0 Positive Real and distinctr =s =Zero Real and equal r = s =Negative No real roots next back contents 95. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction: Use the Discriminant to determine the nature of the root of the following Quadratic Equations. 1.x 2 - 2x 3=0 _____________________________________________________ 2. 6x 2 x 1 = 0 _____________________________________________________ 3. 2x 2 50 = 0 _____________________________________________________ 4. x 2 8x + 12 = 0 _____________________________________________________ 5. x 2+ 5x 14 = 0 _____________________________________________________ 6. -4x 2 4x + 1 = 0 _____________________________________________________ 7. 7x 2+ 2x 1 = 0 _____________________________________________________ Activity 5.1 The Discriminant, Roots and Coefficient next back contents 96. 8.x 2+ 3x = 40 _____________________________________________________ 9. 3x 2 = 5x 1 _____________________________________________________ 10. 3x 2 + 12 1=0 _____________________________________________________ 11. (x-2)(x-3) = 4 _____________________________________________________ 12.2x 2+ 2x + 1 = 0 _____________________________________________________ 13. 7x 2+ 3 6x = 0 _____________________________________________________ 14. 5x 2 6x + 4 = 0 _____________________________________________________ 15. 3x 2+ 2x + 2 = 0 _____________________________________________________ next back contents 97. Lesson 14Relation between roots and coefficient
There are some interesting relations between the sum and the product of the roots of a quadratic equation. To discover these, consider the quadratic equation ax 2+ bx + c = 0, wherea 0. Multiply both sides of this equation by 1/a so that the coefficient of x 2is 1. (ax 2+ bx + c) =We obtain an equivalent quadratic equation in the form x 2++= 0If r and s are the roots of the quadratic equation ax 2+ bx + c = 0, then from the quadratic formula r =and s =next back contents 98. Adding the roots, we obtain r + s =+ ==Multiplying the roots, we obtain rs ==c / aObserve the coefficient in the quadratic equation x 2+ bx/a + c/a = 0. How do they compare with the sum and the product of the roots? Did you observe the following? 1. The sum of the roots is equal to the negative of the coefficient of x. r + s = -b / a 2. The product of the roots is equal to the constant term rs = c / a An alternate way of arriving at these relations is as follows Let r and s be the roots of x 2+ bx/a + c/a = 0. Thenx - r)(x s) = 0 Expanding gives, x 2 rx sx + rs = 0 orx 2 (r + s)x + rs = 0 next back contents 99. Comparing the coefficients of the corresponding terms, we obtain r + s =-b / a and rs c / aThe above relations between the roots and the coefficients provide a fast and convenient means of checking the solutions of a quadratic equation. Example: Solve and check. 2x 2+ x 6 = 0 Solutions: 2x 2+ x 6 = (2x 3)(x + 2) = 0 x = 3/2or x = 2The roots are 3/2 and 2.To check, we add the roots, 3/2 = (-2) = -1/2 = -b/a. and multiply them 3/2 = (-2) = -3 = c/a Example: Find the sum and the product of the roots of 3x 2 6x + 8 = 0 without having to first determine the roots. Solution: The sum of the roots is r + s = -c/a = -(-6)/3 = 2 and their product is rs = c/a = 8/3 next back contents 100. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction:Without solving the roots, find the sum and product of the roots of the following. 1. 6x 2 5x + 2 = 0 _____________________________________________________ 2. x 2+ x 182 = 0 _____________________________________________________ 3. x 2 5x 14 = 0 _____________________________________________________ 4. 2x 2 9x + 8 = 0 _____________________________________________________ 5. 3x 2- 5x 2 = 0 _____________________________________________________ 6. x 2 8x 9 = 0 _____________________________________________________ Activity 5.2 Relation between Roots and Coefficient next back contents 101. 7. 2x 2 3x 9 = 0 _____________________________________________________ 8. x 2+ x 2 -_____________________________________________________ 9. 3x 2+ 2x 8 = 0 _____________________________________________________ 10. 16x 2 24x + = 0 _____________________________________________________ 11. x 2 6x + 25 = 0 _____________________________________________________ 12. 3x 2+ x 2 = 0_____________________________________________________ 13. 5x 2+ 11x 8 = 0 _____________________________________________________ 14. x 2 8x + 16 = 0 _____________________________________________________ 15. 4x 2 16x + 10 = 0 _____________________________________________________ contents back next 102.
Chapter Test contents back next 103. Chapter VI In this chapter, students will be taught how to find solutions to quadratic equations. This lesson assumes students are already familiar with solving simple quadratic equations by hand, and that they have become relatively comfortable using their graphing calculator for solving arithmetic problems and simple algebra problems. Students will also be shown strategies on how to use the keys on the graphing calculator to show a complete graph.
Solving Quadratic Equation in a Calculatorcontents back next 104. Lesson 15 Equation on a Calculator
The simplest way to solve a quadratic equationon a calculator is to use the quadratic formula. x= -b
As we have seen, if d < 0, there are no real solutions. But f d 0, then we can use calculator to get the solutions. To solve 3x + 5x 7 = 0, first compute the discriminant. d = b - 4ac = 5 - 4(3)(-7). On an arithmetic calculator, the keystroke sequence for d is, [AC][MC] 4 [x] 3 [x] 7 [=][M+] 5 [x][=][+][MR][=] The display will show the value of the discriminant to be 109, and so the quadratic equation has two distinct roots. To compute the roots, proceed as follows: [AC][MC] 109 [][M+][MR][-] 5 [+] 2 [x] 3 [=] the first root andcontents back next 105. 0 [-][MR][-] 5 [+] 2 [ x] 3 [=] the second root. On an algebraic calculator, the keystroke sequence is easier. Recall that the actual roots are: x=-5 +2(3) x=-5 - 2(3)
contents back next 106. Name: ___________________Section: _______ Instructor: ________________Date: _______Rating: ______ Instruction:Find the roots of the following equations. 1. 5.3x 2+ 2.1v 2.3 = 0 _____________________________________________________ 2. 6.7 v - 2.2x 7.1x 2= 0 _____________________________________________________ 3. 5.2x 2+ 6.5x 5.13 = 0 _____________________________________________________ 4. x 2 50.001 + 33.2 = 0 _____________________________________________________ 5. x 7.73 + 2.3x 2= 0 _____________________________________________________ 6. 3.3x 2 1.9x 7.10 = 0 _____________________________________________________ Activity 6.1 Solving Quadratic Equations on a Calculator contents back next 107. 7. 3.1x 9.1x 2 7.10 = 0 _____________________________________________________ 8. 6.3x 2 + 8.5x = 9.5 _____________________________________________________ 9. 5.9x 9.5x 2= 8.03 _____________________________________________________ 10. 3.2x 2+ 2.3x = 23.32 _____________________________________________________ 11. 9.9x 7.7x 2 8.8 = 0 _____________________________________________________ 12. 6.3x + 5.3x 2 3.4 = 0 _____________________________________________________ 13. 6.3x 2 2.9x 8.10 = 0 _____________________________________________________ 14. 3.4x 8.1x 2 4.10 = 0 _____________________________________________________ 15. 6.2x 2+ 3.6v 3.7 = 0 _____________________________________________________ contents back next 108.
Chapter Test contents back next 109. References Salamat, Lorina G., College Algebra, National Book Store 1988 pg. 151 159. Coronel, Iluminada C. F.M.M, Mathematics 3 An Integrated Approach, Bookmark Inc. 1991 pg. 77 79, 134 158. Coronel, Iluminada C. F.M.M, Mathematics 4 An Integrated Approach, Bookmark Inc. 1992 pg. 276 297. Borwein, P. and Erdlyi, T. "Quadratic Equations." 1.1.E.1a inPolynomials and Polynomial Inequalities.New York: Springer-Verlag, p.4, 1995. URL Images http://www.mathwarehouse.com/algebra/complex-number/absolute-value-complex-number.php http://commons.wikimedia.org/wiki/File:Quadratic_equation_coefficients.png http://mathworld.wolfram.com/PolynomialRoots.html http://www.livephysics.com/shop/tools-and-gadgets.html contents back next 110. contents back