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# Partial Fraction Expansion

Summary: This module describes the method of partial fraction expansion, in which a ratio of polynomials can be split into a sum of small polynomials. The Heaviside cover-up method is discussed in detail with examples. Finding a partial fraction expansion in matlab is also discussed.

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Splitting up a ratio of large polynomials into a sum of ratios of small polynomials can be a useful tool, especially for many problems involving Laplace-like transforms. This technique is known as partial fraction expansion. Here's an example of one ratio being split into a sum of three simpler ratios:

8x2+3x21x37x6=1x+2+3x3+4x+1 8 x 2 3 x 21 x 3 7 x 6 1 x 2 3 x 3 4 x 1
(1)

There are several methods for expanding a rational function via partial fractions. These include the method of clearing fractions, the Heaviside "cover-up" method, and different combinations of these two. For many cases, the Heaviside "cover-up" method is the easiest, and is therefore the method that we will introduce here. For a more complete discussion, see Signal Processing and Linear Systems by B.P. Lathi, Berkeley-Cambridge Press, 1998, pp-24-33. Some of the material below is based upon this book.

## Heaviside "Cover-Up" Method

### No Repeated Roots

Let's say we have a proper function Gx=NxDx G x N x D x (by proper we mean that the degree m m of the numerator Nx N x is less than the degree p p of denominator Dx D x ). In this section we assume that there are no repeated roots of the polynomial Dx D x .

The first step is to factor the denominator Dx D x :

Gx=Nx(x a 1 )(x a 2 )(x a p ) G x N x x a 1 x a 2 x a p
(2)

where a 1 a p a 1 a p are the roots of Dx D x . We can then rewrite Gx G x as a sum of partial fractions:

Gx= α 1 x a 1 + α 2 x a 2 ++ α p x a p G x α 1 x a 1 α 2 x a 2 α p x a p
(3)

where α 1 α p α 1 α p are constants. Now, to complete the process, we must determine the values of these αα coefficients. Let's look at how to find α 1 α 1 . If we multiply both sides of Equation 3 by x a 1 x a 1 and then let x= a 1 x a 1 , all of the terms on the right-hand side will go to zero except for α 1 α 1 . Therefore, we'll be left over with:

α 1 =(x a 1 )Gx | x=a 1 α 1 x a 1 G x | x=a 1
(4)

We can easily generalize this to a solution for any one of the unknown coefficients:

α r =(x a r )Gx | x=a r α r x a r G x | x=a r
(5)

This method is called the "cover-up" method because multiplying both sides by x a r x a r can be thought of as simply using one's finger to cover up this term in the denominator of Gx G x . With a finger over the term that would be canceled by the multiplication, you can plug in the value x= a r x a r and find the solution for α r α r .

#### Example 1

In this example, we'll work through the partial fraction expansion of the ratio of polynomials introduced above. Before doing a partial fraction expansion, you must make sure that the ratio you are expanding is proper. If it is not, you should do long division to turn it into the sum of a proper fraction and a polynomial. Once this is done, the first step is to factor the denominator of the function:

8x2+3x21x37x6=8x2+3x21(x+2)(x3)(x+1) 8 x 2 3 x 21 x 3 7 x 6 8 x 2 3 x 21 x 2 x 3 x 1
(6)

Now, we set this factored function equal to a sum of smaller fractions, each of which has one of the factored terms for a denominator.

8x2+3x21(x+2)(x3)(x+1)= α 1 x+2+ α 2 x3+ α 3 x+1 8 x 2 3 x 21 x 2 x 3 x 1 α 1 x 2 α 2 x 3 α 3 x 1
(7)

To find the alpha terms, we just cover up the corresponding denominator terms in Gx G x and plug in the root associated with the alpha:

α 1 =(x+2)Gx | x=-2 =8x2+3x21(x3)(x+1) | x=-2 =1 α 1 x 2 G x | x=-2 8 x 2 3 x 21 x 3 x 1 | x=-2 1
(8)
α 2 =(x3)Gx | x=3 =8x2+3x21(x+2)(x+1) | x=3 =3 α 2 x 3 G x | x=3 8 x 2 3 x 21 x 2 x 1 | x=3 3
(9)
α 3 =(x+3)Gx | x=-1 =8x2+3x21(x+2)(x3) | x=-1 =4 α 3 x 3 G x | x=-1 8 x 2 3 x 21 x 2 x 3 | x=-1 4
(10)

We now have our completed partial fraction expansion:

8x2+3x21(x+2)(x3)(x+1)=1x+2+3x3+4x+1 8 x 2 3 x 21 x 2 x 3 x 1 1 x 2 3 x 3 4 x 1
(11)

### Repeated Roots

When the function Gx G x has a repeated root in its denominator, as in

Gx=Nxxbr(x a 1 )(x a 2 )(x a j ) G x N x x b r x a 1 x a 2 x a j
(12)

Somewhat more special care must be taken to find the partial fraction expansion. The non-repeated terms are expanded as before, but for the repeated root, an extra fraction is added for each instance of the repeated root:

Gx= β 0 xbr+ β 1 xbr1++ β r-1 xb+ α 1 x a 1 + α 2 x a 2 ++ α j x a j G x β 0 x b r β 1 x b r 1 β r-1 x b α 1 x a 1 α 2 x a 2 α j x a j
(13)

All of the alpha constants can be found using the non-repeated roots method above. Finding the beta coefficients (which are due to the repeated root) has the same Heaviside feel to it, except that this time we will add a twist by using the derivative to eliminate some unwanted terms.

Starting off directly with the cover-up method, we can find β 0 β 0 . By multiplying both sides by xbr x b r , we'll get:

xbrGx= β 0 + β 1 (xb)++ β r-1 xbr1+ α 1 xbrx a 1 + α 2 xbrx a 2 ++ α j xbrx a j x b r G x β 0 β 1 x b β r-1 x b r 1 α 1 x b r x a 1 α 2 x b r x a 2 α j x b r x a j
(14)

Now that we have "covered up" the xbr x b r term in the denominator of Gx G x , we plug in x=b x b to each side; this cancels every term on the right-hand side except for β 0 β 0 , leaving the formula

β 0 =xbrGx | x=b β 0 x b r G x | x=b
(15)

To find the other values of the beta coefficients, we can take advantage of the derivative. By taking the derivative of Equation 14 (with respect to xx), the right-hand side becomes β 1 β 1 plus terms containing an xb x b in the numerator. Again, plugging in x=b x b eliminates everything on the right-hand side except for β 1 β 1 , leaving us with a formula for β 1 β 1 :

β 1 =dxbrGxd x | x=b β 1 x x b r G x | x=b
(16)

Generalizing over this pattern, we can continue to take derivatives to find the other beta terms. The solution for all beta terms is

β k =1k!d k xbrGxd x k | x=b β k 1 k x k x b r G x | x=b
(17)

#### Hint:

To check if you've done the partial fraction expansion correctly, just add all of the partial fractions together to see if their sum equals the original ratio of polynomials.

## Finding Partial Fractions in Matlab

Matlab can be a useful tool in finding partial fraction expansions when the ratios become too unwieldy to expand by hand. It can handle symbolic variables. For example, if you type 'syms s', s will be treated as a symbolic variable. You can then use it as such when you make function assignments.

If you've done this and have then made a function, say H(s), which is a ratio of two polynomials in the symbolic variable s, there are two ways to get the partial fraction expansion of it. A trick way is to say 'diff(int(H))'. When you use these functions together, Matlab gives back H expanded into partial fractions. There's also a more formal way to do it using the 'residue' command. Type 'help residue' in Matlab for details.

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