1.5 BINOMIAL EXPANSION
x=−1 gives respectively
52
24
=
C
6
−
D 1
2
+
2
4
,
36
7
=
B+C
7
−D 1 +2,
86
63
=
C−B
7
−
D 1
3
+
2
9
.
These equations reduce to
4 C− 12 D 1 =40,
B+C− 7 D 1 =22,
− 9 B+9C− 21 D 1 =72,
with solutionB=0,C=1,D 1 =−3.
Thus, finally, we may rewrite the original expressionF(x) in partial fractions as
F(x)=x+2+
1
x^2 +6
−
3
x− 2
+
2
(x−2)^2
.
1.5 Binomial expansion
Earlier in this chapter we were led to consider functions containing powers of
the sum or difference of two terms, e.g. (x−α)m. Later in this book we will find
numerous occasions on which we wish to write such a product of repeated factors
as a polynomial inxor, more generally, as a sum of terms each of which contains
powers ofxandαseparately, as opposed to a power of their sum or difference.
To make the discussion general and the result applicable to a wide variety of
situations, we will consider the general expansion off(x)=(x+y)n,wherexand
ymay stand for constants, variables or functions and, for the time being,nis a
positive integer. It may not be obvious what form the general expansion takes
but some idea can be obtained by carrying out the multiplication explicitly for
small values ofn. Thus we obtain successively
(x+y)^1 =x+y,
(x+y)^2 =(x+y)(x+y)=x^2 +2xy+y^2 ,
(x+y)^3 =(x+y)(x^2 +2xy+y^2 )=x^3 +3x^2 y+3xy^2 +y^3 ,
(x+y)^4 =(x+y)(x^3 +3x^2 y+3xy^2 +y^3 )=x^4 +4x^3 y+6x^2 y^2 +4xy^3 +y^4.
This does notestablisha general formula, but the regularity of the terms in
the expansions and the suggestion of a pattern in the coefficients indicate that a
general formula for powernwill haven+ 1 terms, that the powers ofxandyin
every term will add up tonand that the coefficients of the first and last terms
will be unity whilst those of the second and penultimate terms will ben.