Mathematical Methods for Physics and Engineering : A Comprehensive Guide

SERIES AND LIMITS

which is merely the series obtained by settingx= 1 in the Maclaurin expansion of expx
(see subsection 4.6.3), i.e.

exp(1) =e=1+

1

1!

+

1

2!

+

1

3!

+···.

Clearly this second series is convergent, since it consists of only positive terms and has a
finite sum. Thus, since each termunin the series (4.7) is less than the corresponding term
1 /n! in (4.8), we conclude from the comparison test that (4.7) is also convergent.

D’Alembert’s ratio test

The ratio test determines whether a series converges by comparing the relative

magnitude of successive terms. If we consider a series

∑

unand set

ρ= lim

n→∞

(

un+1

un

)

, (4.9)

then ifρ<1 the series is convergent; ifρ>1 the series is divergent; ifρ=1

then the behaviour of the series is undetermined by this test.

To prove this we observe that if the limit (4.9) is less than unity, i.e.ρ<1then

we can find a valuerin the rangeρ<r<1 and a valueNsuch that

un+1

un

<r,

for alln>N. Now the termsunof the series that followuNare

uN+1,uN+2,uN+3, ...,

and each of these is less than the corresponding term of

ruN,r^2 uN,r^3 uN, .... (4.10)

However, the terms of (4.10) are those of a geometric series with a common

ratiorthat is less than unity. This geometric series consequently converges and

therefore, by the comparison test discussed above, so must the original series
∑
un. An analogous argument may be used to prove the divergent case when

ρ>1.

Determine whether the following series converges:

∑∞

n=0

1

n!

=

1

0!

+

1

1!

+

1

2!

+

1

3!

+···=2+

1

2!

+

1

3!

+···.

As mentioned in the previous example, this series may be obtained by settingx=1inthe
Maclaurin expansion of expx, and hence we know already that it converges and has the
sum exp(1) =e. Nevertheless, we may use the ratio test to confirm that it converges.
Using (4.9), we have

ρ= lim

n→∞

[

n!

(n+1)!

]

= lim

n→∞

(

1

n+1

)

= 0 (4.11)

and sinceρ<1, the series converges, as expected.