Problem 14.15
Obtain the Maclaurins series for the functions (i)ex (ii) cosx
(i)exis the easy one – it just keeps repeating on differentiation and we have
f(r)(x)=ex for allr
so
f(r)( 0 )=e^0 = 1
So the series is
ex= 1 +x+
x^2
2!
+
x^3
3!
+···
(ii) cosxis almost as easy:
f( 0 )=cos 0= 1
f′( 0 )=−sin 0= 0
f′′( 0 )=−cos 0=− 1
f′′′( 0 )=sin 0= 0
f(iv)( 0 )=cos 0= 1
and so on, giving the series
cosx= 1 −
x^2
2!
+
x^4
4!
−···
So far as the convergence of power series is concerned we can use tests such as the
ratio test described in Section 14.10. The results of such tests will usually depend on
xand so the series may only converge for certain (if any) values ofx. The values
ofxfor which the series converges is usually called theradius of convergence.For
example, the binomial series for( 1 −x)−^1 only converges for|x|<1. Clearly, if a
series does not converge for a particular value ofx, then it cannot represent a sensible
function at that value.
Problem 14.16
Investigate the convergence of
(i) ex= 1 YxY
x^2
2!
Y
x^3
3!
Y
x^4
4!
Y··· (ii) x−
x^2
2
Y
x^3
3
−
x^4
4
Y···
(i) For 1+x+
x^2
2!
+
x^3
3!
+
x^4
4!
+···we haveun=
xn
n!
and so
lim
n→∞
∣
∣
∣
∣
un+ 1
un
∣
∣
∣
∣=nlim→∞
∣
∣
∣
∣
xn+^1
(n+ 1 )!
n!
xn
∣
∣
∣
∣=nlim→∞
∣
∣
∣
∣
x
n+ 1
∣
∣
∣
∣=0 for all finitex