Partial fraction decomposition

In algebra, the partial fraction decomposition or partial fraction expansion of a rational fraction is an operation that consists of expressing the fraction as a sum of a polynomial and one or several fractions with a simpler denominator.
The importance of the partial fraction decomposition lies in the fact that it provides algorithms for various computations with rational functions, including the explicit computation of antiderivatives, Taylor series expansions, inverse Z-transforms, and inverse Laplace transforms. The concept was discovered independently in 1702 by both Johann Bernoulli and Gottfried Leibniz.
In symbols, the partial fraction decomposition of a rational fraction of the form where and are polynomials, is the expression of the rational fraction as
where
is a polynomial, and, for each,
the denominator is a power of an irreducible polynomial, and
the numerator is a polynomial of a smaller degree than the degree of this irreducible polynomial.
When explicit computation is involved, a coarser decomposition is often preferred, which consists of replacing "irreducible polynomial" by "square-free polynomial" in the description of the outcome. This allows replacing polynomial factorization by the much easier-to-compute square-free factorization. This is sufficient for most applications, and avoids introducing irrational coefficients when the coefficients of the input polynomials are integers or rational numbers.

Basic principles

Let
be a rational fraction, where and are univariate polynomials in the indeterminate over a field. The existence of the partial fraction decomposition can be proved by applying inductively the following reduction steps.

Polynomial part

There exist two polynomials and such that
and
where denotes the degree of the polynomial.
This results immediately from the Euclidean division of by, which asserts the existence of and such that and
This allows supposing in the next steps that

Factors of the denominator

If and
where and are coprime polynomials, then there exist polynomials and such that
and
This can be proved as follows. Bézout's identity asserts the existence of polynomials and such that
.
Let with be the Euclidean division of by Setting one gets
It remains to show that By reducing the last sum of fractions to a common denominator, one gets
and thus

Powers in the denominator

Using the preceding decomposition inductively one gets fractions of the form with where is an irreducible polynomial. If, one can decompose further, by using that an irreducible polynomial is a square-free polynomial, that is, is a greatest common divisor of the polynomial and its derivative. If is the derivative of, Bézout's identity provides polynomials and such that and thus Euclidean division of by gives polynomials and such that and Setting one gets
with
Iterating this process with in place of leads eventually to the following theorem.

Statement

The uniqueness can be proved as follows. Let. All together, and the have coefficients. The shape of the decomposition defines a linear map from coefficient vectors to polynomials of degree less than. The existence proof means that this map is surjective. As the two vector spaces have the same dimension, the map is also injective, which means uniqueness of the decomposition. By the way, this proof induces an algorithm for computing the decomposition through linear algebra.
If is the field of complex numbers, the fundamental theorem of algebra implies that all have degree one, and all numerators are constants. When is the field of real numbers, some of the may be quadratic, so, in the partial fraction decomposition, quotients of linear polynomials by powers of quadratic polynomials may also occur.
In the preceding theorem, one may replace "distinct irreducible polynomials" by "pairwise coprime polynomials that are coprime with their derivative". For example, the may be the factors of the square-free factorization of. When is the field of rational numbers, as it is typically the case in computer algebra, this allows to replace factorization by greatest common divisor computation for computing a partial fraction decomposition.

[|Application to symbolic integration]

For the purpose of symbolic integration, the preceding result may be refined into
This reduces the computation of the antiderivative of a rational function to the integration of the last sum, which is called the logarithmic part, because its antiderivative is a linear combination of logarithms.
There are various methods to compute decomposition in the Theorem. One simple way is called Hermite's method. First, b is immediately computed by Euclidean division of f by g, reducing to the case where deg < deg. Next, one knows deg < deg, so one may write each c_ij as a polynomial with unknown coefficients. Reducing the sum of fractions in the Theorem to a common denominator, and equating the coefficients of each power of x in the two numerators, one gets a system of linear equations which can be solved to obtain the desired values for the unknown coefficients.

Procedure

Given two polynomials and, where the α_n are distinct constants and, explicit expressions for partial fractions can be obtained by supposing that
and solving for the c_i constants, by substitution, by equating the coefficients of terms involving the powers of x, or otherwise.
A more direct computation, which is strongly related to Lagrange interpolation, consists of writing
where is the derivative of the polynomial. The coefficients of are called the residues of f/g.
This approach does not account for several other cases, but can be modified accordingly:

If then it is necessary to perform the Euclidean division of P by Q, using polynomial long division, giving with. Dividing by Q this gives and then seek partial fractions for the remainder fraction.
If Q contains nonlinear factors which are irreducible over the given field, then the numerator N of each partial fraction with such a factor F in the denominator must be sought as a polynomial with, rather than as a constant. For example, take the following decomposition over R:
Suppose and, that is is a root of of multiplicity. In the partial fraction decomposition, the first powers of will occur as denominators of the partial fractions. For example, if the partial fraction decomposition has the form
Illustration

In an example application of this procedure, can be decomposed in the form
Clearing denominators shows that. Expanding and equating the coefficients of powers of gives
Solving this system of linear equations for and yields. Hence,

Residue method

Over the complex numbers, suppose f is a rational proper fraction, and can be decomposed into
Let
then according to the uniqueness of Laurent series, a_ij is the coefficient of the term in the Laurent expansion of g_ij about the point x_i, i.e., its residue
This is given directly by the formula
or in the special case when x_i is a simple root,
when

Over the reals

Partial fractions are used in real-variable integral calculus to find real-valued antiderivatives of rational functions. Partial fraction decomposition of real rational functions is also used to find their Inverse Laplace transforms. For applications of partial fraction decomposition over the reals, see

Application to symbolic integration, above
Partial fractions in Laplace transforms
General result

Let be any rational function over the real numbers. In other words, suppose there exist real polynomials functions and, such that
By dividing both the numerator and the denominator by the leading coefficient of, we may assume without loss of generality that is monic. By the fundamental theorem of algebra, we can write
where,, are real numbers with, and, are positive integers. The terms are the linear factors of which correspond to real roots of, and the terms are the irreducible quadratic factors of which correspond to pairs of complex conjugate roots of .
Then the partial fraction decomposition of is the following:
Here, P is a polynomial, and the A_ir, B_ir, and C_ir are real constants. There are a number of ways the constants can be found.
The most straightforward method is to multiply through by the common denominator q. We then obtain an equation of polynomials whose left-hand side is simply p and whose right-hand side has coefficients which are linear expressions of the constants A_ir, B_ir, and C_ir. Since two polynomials are equal if and only if their corresponding coefficients are equal, we can equate the coefficients of like terms. In this way, a system of linear equations is obtained which always has a unique solution. This solution can be found using any of the standard methods of linear algebra. It can also be found with limits.

Examples

Example 1

Here, the denominator splits into two distinct linear factors:
so we have the partial fraction decomposition
Multiplying through by the denominator on the left-hand side gives us the polynomial identity
Substituting x = −3 into this equation gives A = −1/4, and substituting x = 1 gives B = 1/4, so that

Example 2

After long division, we have
The factor is irreducible over the reals, as its discriminant is negative. Thus the partial fraction decomposition over the reals has the shape
Multiplying through by, we have the polynomial identity
Taking, we see that, so. Comparing the x² coefficients, we see that, so. Comparing linear coefficients, we see that, so. Altogether,
The fraction can be completely decomposed using complex numbers. According to the fundamental theorem of algebra every complex polynomial of degree n has n roots. The second fraction can be decomposed to:
Multiplying through by the denominator gives:
Equating the coefficients of and the constant coefficients of both sides of this equation, one gets a system of two linear equations in and, whose solution is
Thus we have a complete decomposition:
One may also compute directly and with the residue method.