17.3 PROPERTIES OF HERMITIAN OPERATORS
set and we can write
∫b
ayˆi∗yˆjρdx=δij, (17.27)which is valid for all pairs of valuesi, j.
17.3.3 Completeness of the eigenfunctionsAs noted earlier, the eigenfunctions of an Hermitian operator may be shown
to form a complete basis set over the relevant interval. One may thus expand
any (reasonable) functiony(x) obeying appropriate boundary conditions in an
eigenfunction series over the interval, as in (17.17). Working in terms of the
normalised eigenfunctionsyˆn(x), we may thus write
f(x)=∑nyˆn(x)∫bayˆn∗(z)f(z)ρ(z)dz=∫baf(z)ρ(z)∑nyˆn(x)yˆ∗n(z)dz.Since this is true for anyf(x), we must have that
ρ(z)∑nyˆn(x)yˆn∗(z)=δ(x−z). (17.28)This is called thecompletenessorclosureproperty of the eigenfunctions. It defines
a complete set. If the spectrum of eigenvalues ofLis anywhere continuous then
the eigenfunctionyn(x) must be treated asy(n, x) and an integration carried out
overn.
We also note that the RHS of (17.28) is aδ-function and so is only non-zerowhenz=x; thusρ(z) on the LHS can be replaced byρ(x) if required, i.e.
ρ(z)∑nyˆn(x)ˆy∗n(z)=ρ(x)∑nyˆn(x)yˆ∗n(z). (17.29)17.3.4 Construction of real eigenfunctionsRecall that the eigenfunctionyisatisfies
Lyi=λiρyi (17.30)and that the complex conjugate of this gives
Lyi∗=λ∗iρy∗i=λiρy∗i, (17.31)where the last equality follows because the eigenvalues are real, i.e.λi=λ∗i.
Thus,yiandyi∗are eigenfunctions corresponding to the same eigenvalue and
hence, because of the linearity ofL,atleastoneofy∗i+yiandi(y∗i−yi), which