Learning Objectives
In this section, you will:
- Decompose , where has only nonrepeated linear factors.
- Decompose , where has repeated linear factors.
- Decompose , where has a nonrepeated irreducible quadratic factor.
- Decompose , where has a repeated irreducible quadratic factor.
Corequisite Skills
Learning Objectives
- Find the least common denominator of rational expressions (IA 7.2.3)
- Solve a system of equations by elimination (IA 4.1.4)
Objective 1: Find the least common denominator of rational expressions (IA 7.2.3)
A rational expression is an expression of the form where p and q are polynomials and .
are examples of rational expressions.
Example 1
Find the least common denominator of the following rationals:
Solution
To find the LCD of the fractions, we factored 3, 12 and 18 into primes, lining up any common primes in columns. Then we “brought down” one prime from each column. Finally, we multiplied the factors to find the LCD.
Practice Makes Perfect
Find the least common denominator of the following rationals:
, , and
How To
To find the least common denominator of rational expressions, we will follow the same process:
- Step 1. List the factors of each denominator. Match factors vertically when possible.
- Step 2. Bring down the columns by including all factors, but do not include common factors twice.
- Step 3. Write the LCD as the product of the factors.
Example 2
Find the least common denominator of the following rational expressions:
and
Solution
Step 1. List the factors of each denominator. Match factors vertically when possible | |
Step 2. Bring down the columns by including all factors, but do not include common factors twice. | |
Step 3. Write the LCD as the product of the factors. | The LCD is |
Try It #1
, , and
Step 1. List the factors of each denominator. Match factors vertically when possible | ________________________________________ |
Step 2. Bring down the columns by including all factors, but do not include common factors twice. | ________________________________________ |
Step 3. Write the LCD as the product of the factors. | ________________________________________ |
Objective 2: Solve a system of equations by elimination (IA 4.1.4)
How To
Solve a system of linear equations by elimination
- Step 1. Write both equations in standard form. If any coefficients are fractions, clear them.
- Step 2.
Make sure the coefficients of one variable are opposites.
- Decide which variable you will eliminate.
- Multiply one or both equations so that the coefficients of that variable are opposites.
- Step 3. Add the equations resulting from Step 2 to eliminate one variable.
- Step 4. Solve for the remaining variable.
- Step 5. Substitute the solution from Step 4 into one of the original equations. Then solve for the other variable.
- Step 6. Write the solution as an ordered pair.
- Step 7. Check that the ordered pair is a solution to both original equations.
Example 3
Solve the system of equations by elimination.
Solution
Step 1 | Write the equations in standard form. If any coefficients are fractions, clear them. |
Step 2 | Let’s eliminate y |
Step 3 | |
Step 4 | |
Step 5 | Use the value of the variable found in Step 2 to find the second variable. Let’s substitute into |
Step 6 | Write the solution as an ordered pair: (2, -1) |
Step 7 | Check the solution into the original equations. |
Try It #2
Solve the system of equations by elimination.
Step 1 | Write the equations in standard form. If any coefficients are fractions, clear them. ________________________________________ |
Step 2 | Make sure the coefficients of one variable are opposites. ________________________________________ |
Step 3 | Add the equations resulting from Step 2 to eliminate one variable. ________________________________________ |
Step 4 | Solve for the remaining variable. ________________________________________ |
Step 5 | Substitute the solution from Step 4 into one of the original equations. Then solve for the other variable. ________________________________________ |
Step 6 | Write the solution as an ordered pair: ________ |
Step 7 | Check that the ordered pair is a solution to both original equations. ________________________________________ |
Partial Fraction Decomposition
When we add rational expressions with unlike denominators such as and , we first need to find the LCD, then rewrite each fraction with the common denominator, and finally add the two numerators.
Try It #3
Find the sum of the two rational expressions.
and
Find the LCD of and | LCD = ________________ |
Rewrite each rational as an equivalent rational expression with the LCD | |
Add the numerators and place the sum over the common denominator |
We want to do the opposite now.
Given a rational expression like, we would like to rewrite it as an addition of two simpler rational expressions and . Our goal is to find the values of A and B such that
Find the LCD of the denominators | |
Multiply both sides of the equation by the LCD. Distribute and cancel like terms | |
On the right side, we expand and collect terms with like terms | |
We compare the coefficients of both sides. This will give a system of two equations with two variables | |
Use solving by elimination to find the values of A and B. | |
Rewrite the original rational expression as the addition of two rational expressions with unlike denominators |
Earlier in this chapter, we studied systems of two equations in two variables, systems of three equations in three variables, and nonlinear systems. Here we introduce another way that systems of equations can be utilized—the decomposition of rational expressions.
Fractions can be complicated; adding a variable in the denominator makes them even more so. The methods studied in this section will help simplify the concept of a rational expression.
Decomposing Where Q(x) Has Only Nonrepeated Linear Factors
Recall the algebra regarding adding and subtracting rational expressions. These operations depend on finding a common denominator so that we can write the sum or difference as a single, simplified rational expression. In this section, we will look at partial fraction decomposition, which is the undoing of the procedure to add or subtract rational expressions. In other words, it is a return from the single simplified rational expression to the original expressions, called the partial fraction.
For example, suppose we add the following fractions:
We would first need to find a common denominator,
Next, we would write each expression with this common denominator and find the sum of the terms.
Partial fraction decomposition is the reverse of this procedure. We would start with the solution and rewrite (decompose) it as the sum of two fractions.
We will investigate rational expressions with linear factors and quadratic factors in the denominator where the degree of the numerator is less than the degree of the denominator. Regardless of the type of expression we are decomposing, the first and most important thing to do is factor the denominator.
When the denominator of the simplified expression contains distinct linear factors, it is likely that each of the original rational expressions, which were added or subtracted, had one of the linear factors as the denominator. In other words, using the example above, the factors of are the denominators of the decomposed rational expression. So we will rewrite the simplified form as the sum of individual fractions and use a variable for each numerator. Then, we will solve for each numerator using one of several methods available for partial fraction decomposition.
Partial Fraction Decomposition of Has Nonrepeated Linear Factors
The partial fraction decomposition of when has nonrepeated linear factors and the degree of is less than the degree of is
How To
Given a rational expression with distinct linear factors in the denominator, decompose it.
- Use a variable for the original numerators, usually or depending on the number of factors, placing each variable over a single factor. For the purpose of this definition, we use for each numerator
- Multiply both sides of the equation by the common denominator to eliminate fractions.
- Expand the right side of the equation and collect like terms.
- Set coefficients of like terms from the left side of the equation equal to those on the right side to create a system of equations to solve for the numerators.
Example 1
Decomposing a Rational Function with Distinct Linear Factors
Decompose the given rational expression with distinct linear factors.
Solution
We will separate the denominator factors and give each numerator a symbolic label, like or
Multiply both sides of the equation by the common denominator to eliminate the fractions:
The resulting equation is
Expand the right side of the equation and collect like terms.
Set up a system of equations associating corresponding coefficients.
Add the two equations and solve for
Substitute into one of the original equations in the system.
Thus, the partial fraction decomposition is
Another method to use to solve for or is by considering the equation that resulted from eliminating the fractions and substituting a value for that will make either the A- or B-term equal 0. If we let the
term becomes 0 and we can simply solve for
Next, either substitute into the equation and solve for or make the B-term 0 by substituting into the equation.
We obtain the same values for and using either method, so the decompositions are the same using either method.
Although this method is not seen very often in textbooks, we present it here as an alternative that may make some partial fraction decompositions easier. It is known as the Heaviside method, named after Charles Heaviside, a pioneer in the study of electronics.
Try It #4
Find the partial fraction decomposition of the following expression.
Decomposing Where Q(x) Has Repeated Linear Factors
Some fractions we may come across are special cases that we can decompose into partial fractions with repeated linear factors. We must remember that we account for repeated factors by writing each factor in increasing powers.
Partial Fraction Decomposition of Has Repeated Linear Factors
The partial fraction decomposition of when has a repeated linear factor occurring times and the degree of is less than the degree of is
Write the denominator powers in increasing order.
How To
Given a rational expression with repeated linear factors, decompose it.
- Use a variable like or for the numerators and account for increasing powers of the denominators.
- Multiply both sides of the equation by the common denominator to eliminate fractions.
- Expand the right side of the equation and collect like terms.
- Set coefficients of like terms from the left side of the equation equal to those on the right side to create a system of equations to solve for the numerators.
Example 2
Decomposing with Repeated Linear Factors
Decompose the given rational expression with repeated linear factors.
Solution
The denominator factors are To allow for the repeated factor of the decomposition will include three denominators: and Thus,
Next, we multiply both sides by the common denominator.
On the right side of the equation, we expand and collect like terms.
Next, we compare the coefficients of both sides. This will give the system of equations in three variables:
Solving for , we have
Substitute into equation (1).
Then, to solve for substitute the values for and into equation (2).
Thus,
Try It #5
Find the partial fraction decomposition of the expression with repeated linear factors.
Decomposing Where Q(x) Has a Nonrepeated Irreducible Quadratic Factor
So far, we have performed partial fraction decomposition with expressions that have had linear factors in the denominator, and we applied numerators or representing constants. Now we will look at an example where one of the factors in the denominator is a quadratic expression that does not factor. This is referred to as an irreducible quadratic factor. In cases like this, we use a linear numerator such as etc.
Decomposition of Has a Nonrepeated Irreducible Quadratic Factor
The partial fraction decomposition of such that has a nonrepeated irreducible quadratic factor and the degree of is less than the degree of is written as
The decomposition may contain more rational expressions if there are linear factors. Each linear factor will have a different constant numerator: and so on.
How To
Given a rational expression where the factors of the denominator are distinct, irreducible quadratic factors, decompose it.
- Use variables such as or for the constant numerators over linear factors, and linear expressions such as etc., for the numerators of each quadratic factor in the denominator.
- Multiply both sides of the equation by the common denominator to eliminate fractions.
- Expand the right side of the equation and collect like terms.
- Set coefficients of like terms from the left side of the equation equal to those on the right side to create a system of equations to solve for the numerators.
Example 3
Decomposing When Q(x) Contains a Nonrepeated Irreducible Quadratic Factor
Find a partial fraction decomposition of the given expression.
Solution
We have one linear factor and one irreducible quadratic factor in the denominator, so one numerator will be a constant and the other numerator will be a linear expression. Thus,
We follow the same steps as in previous problems. First, clear the fractions by multiplying both sides of the equation by the common denominator.
Notice we could easily solve for by choosing a value for that will make the term equal 0. Let and substitute it into the equation.
Now that we know the value of substitute it back into the equation. Then expand the right side and collect like terms.
Setting the coefficients of terms on the right side equal to the coefficients of terms on the left side gives the system of equations.
Solve for using equation (1) and solve for using equation (3).
Thus, the partial fraction decomposition of the expression is
Q&A
Could we have just set up a system of equations to solve Example 3?
Yes, we could have solved it by setting up a system of equations without solving for first. The expansion on the right would be:
So the system of equations would be:
Try It #6
Find the partial fraction decomposition of the expression with a nonrepeating irreducible quadratic factor.
Decomposing When Q(x) Has a Repeated Irreducible Quadratic Factor
Now that we can decompose a simplified rational expression with an irreducible quadratic factor, we will learn how to do partial fraction decomposition when the simplified rational expression has repeated irreducible quadratic factors. The decomposition will consist of partial fractions with linear numerators over each irreducible quadratic factor represented in increasing powers.
Decomposition of When Q(x) Has a Repeated Irreducible Quadratic Factor
The partial fraction decomposition of when has a repeated irreducible quadratic factor and the degree of is less than the degree of is
Write the denominators in increasing powers.
How To
Given a rational expression that has a repeated irreducible factor, decompose it.
- Use variables like or for the constant numerators over linear factors, and linear expressions such as etc., for the numerators of each quadratic factor in the denominator written in increasing powers, such as
- Multiply both sides of the equation by the common denominator to eliminate fractions.
- Expand the right side of the equation and collect like terms.
- Set coefficients of like terms from the left side of the equation equal to those on the right side to create a system of equations to solve for the numerators.
Example 4
Decomposing a Rational Function with a Repeated Irreducible Quadratic Factor in the Denominator
Decompose the given expression that has a repeated irreducible factor in the denominator.
Solution
The factors of the denominator are and Recall that, when a factor in the denominator is a quadratic that includes at least two terms, the numerator must be of the linear form So, let’s begin the decomposition.
We eliminate the denominators by multiplying each term by Thus,
Expand the right side.
Now we will collect like terms.
Set up the system of equations matching corresponding coefficients on each side of the equal sign.
We can use substitution from this point. Substitute into the first equation.
Substitute and into the third equation.
Substitute into the fourth equation.
Now we have solved for all of the unknowns on the right side of the equal sign. We have and We can write the decomposition as follows:
Try It #7
Find the partial fraction decomposition of the expression with a repeated irreducible quadratic factor.
Media
Access these online resources for additional instruction and practice with partial fractions.
7.4 Section Exercises
Verbal
Can any quotient of polynomials be decomposed into at least two partial fractions? If so, explain why, and if not, give an example of such a fraction
Can you explain why a partial fraction decomposition is unique? (Hint: Think about it as a system of equations.)
You are unsure if you correctly decomposed the partial fraction correctly. Explain how you could double-check your answer.
Once you have a system of equations generated by the partial fraction decomposition, can you explain another method to solve it? For example if you had , we eventually simplify to Explain how you could intelligently choose an -value that will eliminate either or and solve for and
Algebraic
For the following exercises, find the decomposition of the partial fraction for the nonrepeating linear factors.
For the following exercises, find the decomposition of the partial fraction for the repeating linear factors.
For the following exercises, find the decomposition of the partial fraction for the irreducible nonrepeating quadratic factor.
For the following exercises, find the decomposition of the partial fraction for the irreducible repeating quadratic factor.
Extensions
For the following exercises, find the partial fraction expansion.
For the following exercises, perform the operation and then find the partial fraction decomposition.