17.7 EXERCISES
We note that ifμ=λn,i.e.ifμequals one of the eigenvalues ofL,thenG(x, z)
becomes infinite and this method runs into difficulty. No solution then exists
unless the RHS of (17.53) satisfies the relation
∫bayˆ∗n(x)f(x)dx=0.If the spectrum of eigenvalues of the operatorLis anywhere continuous,the orthonormality and closure relationships of the normalised eigenfunctions
become
∫b
ayˆn∗(x)yˆm(x)ρ(x)dx=δ(n−m),
∫∞0yˆ∗n(z)yˆn(x)ρ(x)dn=δ(x−z).Repeating the above analysis we then find that the Green’s function is given by
G(x, z)=∫∞0yˆn(x)yˆ∗n(z)
λn−μdn.17.7 Exercises17.1 By considering〈h|h〉,whereh=f+λgwithλreal, prove that, for two functions
fandg,
〈f|f〉〈g|g〉≥^14 [〈f|g〉+〈g|f〉]^2.
The functiony(x) is real and positive for allx. Its Fourier cosine transform ̃yc(k)
is defined bỹyc(k)=∫∞
−∞y(x)cos(kx)dx,and it is given thaty ̃c(0) = 1. Prove that
̃yc(2k)≥2[y ̃c(k)]^2 − 1.17.2 Write the homogeneous Sturm-Liouville eigenvalue equation for whichy(a)=
y(b)=0as
L(y;λ)≡(py′)′+qy+λρy=0,
wherep(x),q(x)andρ(x) are continuously differentiable functions. Show that if
z(x)andF(x)satisfyL(z;λ)=F(x), withz(a)=z(b)=0,then
∫b
ay(x)F(x)dx=0.Demonstrate the validity of this general result by direct calculation for the
specific case in whichp(x)=ρ(x)=1,q(x)=0,a=−1,b=1andz(x)=1−x^2.
17.3 Consider the real eigenfunctionsyn(x) of a Sturm–Liouville equation,
(py′)′+qy+λρy=0,a≤x≤b,
in whichp(x),q(x)andρ(x) are continuously differentiable real functions and
p(x) does not change sign ina≤x≤b.Takep(x) as positive throughout the