SERIES SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS
is required, i.e.z= 0, is in fact an ordinary point of the ODE rather than a
regular singular point, then substitution of the Frobenius series (16.12) leads to
an indicial equation with rootsσ= 0 andσ= 1. Although these roots differ by
an integer (unity), the recurrence relations corresponding to the two roots yield
two linearly independent power series solutions (one for each root), as expected
from section 16.2.
16.4 Obtaining a second solutionWhilst attempting to construct solutions to an ODE in the form of Frobenius
series about a regular singular point, we found in the previous section that when
the indicial equation has a repeated root, or roots differing by an integer, we can
(in general) find only one solution of this form. In order to construct the general
solution to the ODE, however, we require two linearly independent solutionsy 1
andy 2. We now consider several methods for obtaining a second solution in this
case.
16.4.1 The Wronskian methodIfy 1 andy 2 are two linearly independent solutions of the standard equation
y′′+p(z)y′+q(z)y=0then the Wronskian of these two solutions is given byW(z)=y 1 y′ 2 −y 2 y′ 1.
Dividing the Wronskian byy^21 we obtain
W
y^21=y 2 ′
y 1−y′ 1
y^21y 2 =y′ 2
y 1+[
d
dz(
1
y 1)]
y 2 =d
dz(
y 2
y 1)
,which integrates to give
y 2 (z)=y 1 (z)∫z
W(u)
y 12 (u)du.Now using the alternative expression forW(z) given in (16.4) withC=1(since
we are not concerned with this normalising factor), we find
y 2 (z)=y 1 (z)∫z
1
y 12 (u)exp{
−∫u
p(v)dv}
du. (16.25)Hence, giveny 1 , we can in principle computey 2. Note that the lower limits of
integration have been omitted. If constant lower limits are included then they
merely lead to a constant times the first solution.
Find a second solution to (16.21) using the Wronskian method.For the ODE (16.21) we havep(z)=3/(z−1), and from (16.24) we see that one solution