Mathematical Methods for Physics and Engineering : A Comprehensive Guide

SERIES AND LIMITS

Sum the series

∑N

n=1

(n+1)(n+3).

Thenth term in this series is

un=(n+1)(n+3)=n^2 +4n+3,

and therefore we can write

∑N

n=1

(n+1)(n+3)=

∑N

n=1

(n^2 +4n+3)

=

∑N

n=1

n^2 +4

∑N

n=1

n+

∑N

n=1

3

=^16 N(N+ 1)(2N+1)+4×^12 N(N+1)+3N

=^16 N(2N^2 +15N+ 31).

4.2.6 Transformation of series

A complicated series may sometimes be summed by transforming it into a

familiar series for which we already know the sum, perhaps a geometric series

or the Maclaurin expansion of a simple function (see subsection 4.6.3). Various

techniques are useful, and deciding which one to use in any given case is a matter

of experience. We now discuss a few of the more common methods.

The differentiation or integration of a series is often useful in transforming an

apparently intractable series into a more familiar one. If we wish to differentiate

or integrate a series that already depends on some variable then we may do so

in a straightforward manner.

Sum the series

S(x)=

x^4

3(0!)

+

x^5

4(1!)

+

x^6

5(2!)

+···.

Dividing both sides byxwe obtain

S(x)

x

=

x^3

3(0!)

+

x^4

4(1!)

+

x^5

5(2!)

+···,

which is easily differentiated to give

d

dx

[

S(x)

x

]

=

x^2

0!

+

x^3

1!

+

x^4

2!

+

x^5

3!

+···.

Recalling the Maclaurin expansion of expxgiven in subsection 4.6.3, we recognise that
the RHS is equal tox^2 expx. Having done so, we can now integrate both sides to obtain

S(x)/x=

∫

x^2 expxdx.