Encyclopedia > Partial fraction

  Article Content

Partial fraction

In more traditional treatments of algebra, great emphasis has been placed on the computation of the partial fraction decomposition of a rational function[?]. The reason was an application: partial fractions in integration.

The basic principles involved are quite simple; it is the algorithmic aspects that require attention in particular cases.

Assume a rational function R(X) in one unknown has denominator that factorises as P(X)Q(X) over a field K (we can take this to be real numbers, or complex numbers). If P and Q have no common factor then R may be written as A/P + B/Q for some polynomials A(X) and B(X) over K. The existence of such a decomposition is a consequence of the fact that the polynomial ring[?] over K is a principal ideal domain, so that CP + DQ = 1 for some polynomial C(X) and D(X) (see Bézout's identity).

Using this idea inductively we can write R(X) as a sum with denominators powers of irreducible polynomials. To take this further, if required, write G(X)/F(X)n as a sum with denominators powers of F and numerators of degree less than F, plus a possible extra polynomial. This can be done by the Euclidean algorithm, polynomial case.

Therefore when K is the complex numbers and we can assume F has degree 1 (by the fundamental theorem of algebra) the numerators will be constant. When K is the real numbers we can have the case of degree F = 2, and a quotient of a linear polynomial by a power of a quadratic will occur. This therefore is a case that requires discussion, in the systematic theory of integration (for example in computer algebra).



All Wikipedia text is available under the terms of the GNU Free Documentation License

 
  Search Encyclopedia

Search over one million articles, find something about almost anything!
 
 
  
  Featured Article
Northwest Harbor, New York

... As of the census of 2000, there are 3,059 people, 1,181 households, and 818 families residing in the town. The population density is 81.3/km² (210.6/mi²). ...

 
 
 
This page was created in 28.3 ms