Partial Fractions. (x 1)(x 2 + 1)



Similar documents
The Method of Partial Fractions Math 121 Calculus II Spring 2015

1 Lecture: Integration of rational functions by decomposition

Integrals of Rational Functions

Partial Fractions. Combining fractions over a common denominator is a familiar operation from algebra:

1.7. Partial Fractions Rational Functions and Partial Fractions. A rational function is a quotient of two polynomials: R(x) = P (x) Q(x).

3.6. Partial Fractions. Introduction. Prerequisites. Learning Outcomes

Decomposing Rational Functions into Partial Fractions:

To add fractions we rewrite the fractions with a common denominator then add the numerators. = +

is identically equal to x 2 +3x +2

Partial Fractions Decomposition

a 1 x + a 0 =0. (3) ax 2 + bx + c =0. (4)

Partial Fractions. p(x) q(x)

Solving Quadratic Equations by Factoring

3.3. Solving Polynomial Equations. Introduction. Prerequisites. Learning Outcomes

1.3 Algebraic Expressions

Linear and quadratic Taylor polynomials for functions of several variables.

Partial Fractions Examples

Zeros of a Polynomial Function

Section 6.1 Factoring Expressions

is identically equal to x 2 +3x +2

Equations, Inequalities & Partial Fractions

Factoring Quadratic Expressions

Sample Problems. Practice Problems

SOLVING QUADRATIC EQUATIONS - COMPARE THE FACTORING ac METHOD AND THE NEW DIAGONAL SUM METHOD By Nghi H. Nguyen

1.5. Factorisation. Introduction. Prerequisites. Learning Outcomes. Learning Style

Algebra Practice Problems for Precalculus and Calculus

1.4. Arithmetic of Algebraic Fractions. Introduction. Prerequisites. Learning Outcomes

CM2202: Scientific Computing and Multimedia Applications General Maths: 2. Algebra - Factorisation

0.8 Rational Expressions and Equations

SOLVING POLYNOMIAL EQUATIONS

Solving Quadratic Equations

Partial Fractions: Undetermined Coefficients

0.4 FACTORING POLYNOMIALS

Factoring Polynomials

MATH 108 REVIEW TOPIC 10 Quadratic Equations. B. Solving Quadratics by Completing the Square

Vieta s Formulas and the Identity Theorem

Lagrange Interpolation is a method of fitting an equation to a set of points that functions well when there are few points given.

Second Order Linear Nonhomogeneous Differential Equations; Method of Undetermined Coefficients. y + p(t) y + q(t) y = g(t), g(t) 0.

SECTION 0.6: POLYNOMIAL, RATIONAL, AND ALGEBRAIC EXPRESSIONS

3.1. RATIONAL EXPRESSIONS

EAP/GWL Rev. 1/2011 Page 1 of 5. Factoring a polynomial is the process of writing it as the product of two or more polynomial factors.

Click on the links below to jump directly to the relevant section

Factoring Trinomials: The ac Method

Integrating algebraic fractions

FACTORING QUADRATICS and 8.1.2

2.6 Exponents and Order of Operations

PYTHAGOREAN TRIPLES KEITH CONRAD

6 EXTENDING ALGEBRA. 6.0 Introduction. 6.1 The cubic equation. Objectives

CAHSEE on Target UC Davis, School and University Partnerships

Copy in your notebook: Add an example of each term with the symbols used in algebra 2 if there are any.

3 1. Note that all cubes solve it; therefore, there are no more

SOLVING QUADRATIC EQUATIONS BY THE DIAGONAL SUM METHOD

Lesson 9: Radicals and Conjugates

Zeros of Polynomial Functions

Techniques of Integration

NSM100 Introduction to Algebra Chapter 5 Notes Factoring

Review of Fundamental Mathematics

Integration ALGEBRAIC FRACTIONS. Graham S McDonald and Silvia C Dalla

ALGEBRA REVIEW LEARNING SKILLS CENTER. Exponents & Radicals

Slope-Intercept Form of a Linear Equation Examples

Lesson 9: Radicals and Conjugates

Florida Math Correlation of the ALEKS course Florida Math 0028 to the Florida Mathematics Competencies - Upper

JUST THE MATHS UNIT NUMBER 1.8. ALGEBRA 8 (Polynomials) A.J.Hobson

Factoring Polynomials and Solving Quadratic Equations

This is a square root. The number under the radical is 9. (An asterisk * means multiply.)

Lecture 5 Rational functions and partial fraction expansion

SECTION 2.5: FINDING ZEROS OF POLYNOMIAL FUNCTIONS

FACTORING ax 2 bx c. Factoring Trinomials with Leading Coefficient 1

QUADRATIC EQUATIONS AND FUNCTIONS

Factoring and Applications

MATH Fundamental Mathematics IV

Factoring Guidelines. Greatest Common Factor Two Terms Three Terms Four Terms Shirley Radai

Solving Rational Equations

Balancing Chemical Equations

Determinants can be used to solve a linear system of equations using Cramer s Rule.

CHAPTER SIX IRREDUCIBILITY AND FACTORIZATION 1. BASIC DIVISIBILITY THEORY

Negative Integer Exponents

MSLC Workshop Series Math Workshop: Polynomial & Rational Functions

5.4 Solving Percent Problems Using the Percent Equation

Quotient Rings and Field Extensions

minimal polyonomial Example

Examples of Tasks from CCSS Edition Course 3, Unit 5

Answer Key for California State Standards: Algebra I

POLYNOMIAL FUNCTIONS

4.1. COMPLEX NUMBERS

it is easy to see that α = a

expression is written horizontally. The Last terms ((2)( 4)) because they are the last terms of the two polynomials. This is called the FOIL method.

FACTORISATION YEARS. A guide for teachers - Years 9 10 June The Improving Mathematics Education in Schools (TIMES) Project

Mathematics Placement

MATH 90 CHAPTER 6 Name:.

SIMPLIFYING SQUARE ROOTS

Chapter R.4 Factoring Polynomials

Factoring ax 2 + bx + c - Teacher Notes

2.3. Finding polynomial functions. An Introduction:

2.5 Zeros of a Polynomial Functions

Definitions 1. A factor of integer is an integer that will divide the given integer evenly (with no remainder).

( ) FACTORING. x In this polynomial the only variable in common to all is x.

5. Factoring by the QF method

A Quick Algebra Review

Transcription:

Partial Fractions Adding rational functions involves finding a common denominator, rewriting each fraction so that it has that denominator, then adding. For example, 3x x 1 3x(x 1) (x + 1)(x 1) + 1(x + 1) (x 1)(x + 1) (3x 3x) + (x + 1) (x + 1)(x 1) 4x 3x + 1 x 3 x + In calculus it is frequently easier to work with a sum of several simple fractions than it is to work with a single more complicated fraction, so it is important that we be able to undo the above process. This is commonly referred to as decomposing the fraction into partial fractions. In most cases, the first step in decomposing a fraction is to find the possible denominators of the summands (the simpler fractions). Since the common denominator we find when we add fractions is actually the product of all of the factors of the denominators of the summands, these factors will be the simplest possible denominators to use when we decompose. In order for the process to work correctly, we must factor the denominator as completely as possible (without using complex numbers). If you have factored completely, the factors you end up with should all be linear functions, irreducible quadratic functions (quadratics are irreducible if they have no real roots), or powers of these kinds of functions. The next step in the process is to write the original fraction as a sum of fractions with the denominators we found by factoring and with unknown numerators. If the denominator is a power of a linear function, then the numerator will be an unknown constant. If the denominator is a power of an irreducible quadratic, then the numerator will be an unknown linear function. The final step is to add the fractions with the unknown numerators, then set the numerator of the sum equal to the numerator of the original fraction (the denominators will already be equal if you did the previous steps correctly). This will result in a system of equations and unknowns that can be solved to find the numerators of the summands. Let s consider a simple example. Example 1. In order to decompose the fraction

you would first factor the denominator (x + 1)(x 1). Since the factors of the denominator are linear, the numerators of our partial fractions will be constants. Our goal then is to find constants A and B so that ( ) A x + 1 + B If we were to add the partial fractions on the right side of this equation, we would get A x + 1 + B A(x 1) + B(x + 1) x 1 (x + 1)(x 1) Ax A + Bx + B (A + B)x + (B A) x. 1 Since this is supposed to equal the original fraction, we want to find A and B so that (A + B)x + (B A) x. 1 These fractions have the same denominators, so they will be equal exactly when their numerators are equal. In other words, we want (A + B)x + (B A). Setting like terms equal and ignoring the powers of x, we obtain the following system of two equations and two unknowns: A + B A + B 0 Next use whatever method seems simplest to solve this system. You should end up with A 1 and B 1. Finally, plug these into ( ) to obtain 1 x + 1 + 1 You can check your work by adding the fractions we obtained to make sure that the sum is as desired. There are two things that you must watch out for that didn t occur in our simple example above. The first is that the above procedure only works if the degree of the numerator is less than the degree of the denominator in the original fraction. If this is not

the case, then you will have to use polynomial division to rewrite the rational function as the sum of a polynomial and a rational function before you begin. The second thing to be careful of concerns the potential denominators of the partial fractions. When your factors of the original denominator include a power of a linear or quadratic function, you must remember that all positive integer powers of the function less than that power are also factors of the denominator, even if they didn t show up explicitly. For example, the factors of (x 1)(x + 3) 3 are (x 1), (x + 3) 3, (x + 3), and (x + 3). Here s a more typical example. Make sure that you pay attention to both of the issues mentioned above as you work through it. Example. Decompose the fraction x5 4 + 6x 3 6x + 5x x 4 3 +. + 1 First note that the degree of the numerator is greater than the degree of the denominator. As noted above, we use polynomial division to rewrite the fraction. When you do so you should obtain 3 ( ) x 5 4 + 6x 3 6x + 5x x + 4x3 4x + 4x. We now use the procedure above to rewrite the remaining fraction in ( ). First factor the denominator as completely as possible, it will be helpful to notice that 1 is a root of the denominator: (x 1)(x 3 x + x 1) (x 1) (x + 1) Now we can see that the denominators for our partial fractions are (x + 1), (x 1), and (x 1). Remember that x 1 is a factor, even though it doesn t appear explicitly. Placing unknown constants in the numerator when the denominator is a power of a linear function and unknown linear functions in the numerator when the denominator is a power of an irreducible quadratic, we obtain ( ) 4x 3 4x + 4x Ax + B x + 1 + C (x 1) + D Next add the fractions on the right to obtain Ax + B x + 1 + C (x 1) + D x 1 (Ax + B)(x 1) + C(x + 1) + D(x + 1)(x 1) (x + 1)(x 1)

4 Ax 3 Ax + Ax + Bx Bx + B + Cx + C + Dx 3 Dx + Dx D (A + D)x 3 + ( A + B + C D)x + (A B + D)x + (B + C D) Setting the numerator equal to the numerator of the fraction on the left side of ( ) and collecting like terms, we obtain the following system: A +D 4 A +B +C D 4 A B +D 4 B +C D Solving the system above yields A 1, B 0, C 1, and D 3. We can plug these values into ( ) to obtain 4x 3 4x + 4x x (x 1) + 3 Remember though that doesn t complete the problem. We must now insert this into ( ) to obtain our final result: x 5 4 + 6x 3 6x + 5x x + x (x 1) + 3 x 1 Problems: Decompose each of the following fractions. 1. 5x + 7 x + 3. 3x 1 x x 3. 5x + 1 x 3 4. 3 x + 3x + 1 x 4 + + 1 5. 76x + 36 x 4 16 6. 4x 4 + 7x 3 + 4x 7x x 6 + x 4 7. x 4 + x 3 + + 1 x 3 + x 8. 3x 4 + 6x 3 + 4 x 3 + 9. x 4x + 3 x 3 10. 4x x 4 + 4 Hint: ( 1 + i) 4 4

5 Solutions 1. x + 3 + x 3 1 3. 5 x x + 1 x 3 5. 1 x + 4 x + 3 + x 1 7. x + 1 1 x 9. 1 x + 3 x 3

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information