SERIES SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS
(b) Find one series solution in powers ofz. Give a formal expression for a
second linearly independent solution.
(c) Deduce the values ofλfor which there is a polynomial solutionPN(z)of
degreeN. Evaluate the first four polynomials, normalised in such a way that
PN(0) = 1.16.11 Find the general power series solution aboutz=0oftheequation
zd^2 y
dz^2+(2z−3)dy
dz+
4
zy=0.16.12 Find the radius of convergence of a series solution about the origin for the
equation (z^2 +az+b)y′′+2y= 0 in the following cases:
(a)a=5,b=6; (b)a=5,b=7.Show that ifaandbare real and 4b>a^2 , then the radius of convergence is
always given byb^1 /^2.
16.13 For the equationy′′+z−^3 y= 0, show that the origin becomes a regular singular
point if the independent variable is changed fromztox=1/z. Hence find a
series solution of the formy 1 (z)=
∑∞
0 anz−n.Bysettingy 2 (z)=u(z)y 1 (z)and
expanding the resulting expression fordu/dzin powers ofz−^1 , show thaty 2 (z)
has the asymptotic formy 2 (z)=c[
z+lnz−^12 +O(
lnz
z)]
,
wherecis an arbitrary constant.
16.14 Prove that the Laguerre equation,
zd^2 y
dz^2+(1−z)dy
dz+λy=0,has polynomial solutionsLN(z)ifλis a non-negative integerN, and determine
the recurrence relationship for the polynomial coefficients. Hence show that an
expression forLN(z), normalised in such a way thatLN(0) =N!, isLN(z)=∑N
n=0(−1)n(N!)^2
(N−n)!(n!)^2zn.EvaluateL 3 (z) explicitly.
16.15 The origin is an ordinary point of the Chebyshev equation,
(1−z^2 )y′′−zy′+m^2 y=0,which therefore has series solutions of the formzσ∑∞
0 anznforσ=0andσ=1.(a) Find the recurrence relationships for theanin the two cases and show that
there exist polynomial solutionsTm(z):(i) forσ=0,whenmis an even integer, the polynomial having^12 (m+2)
terms;
(ii) forσ=1,whenmis an odd integer, the polynomial having^12 (m+1)
terms.(b)Tm(z) is normalised so as to haveTm(1) = 1. Find explicit forms forTm(z)
form=0, 1 , 2 ,3.