User:Dnessett/Legendre/Associated Legendre Functions Orthonormality for fixed m

This article proves that the Associated Legendre Functions are orthonormal for fixed m. For more information on Associated Legendre Functions see Associated Legendre Function

Theorem[edit]

${\displaystyle \int \limits _{-1}^{1}P_{l}^{m}\left(x\right)P_{k}^{m}\left(x\right)dx={\frac {2}{2l+1}}{\frac {\left(l+m\right)!}{\left(l-m\right)!}}\delta _{lk}.}$

[Note: This article uses the more common ${\displaystyle P_{l}^{m}}$ notation, rather than ${\displaystyle P_{l}^{\left(m\right)}}$]

Where: ${\displaystyle P_{l}^{m}\left(x\right)={\frac {\left(-1\right)^{m}}{2^{l}l!}}\left(1-x^{2}\right)^{\frac {m}{2}}{\frac {d^{l+m}}{dx^{l+m}}}\left[\left(x^{2}-1\right)^{l}\right],}$ ${\displaystyle 0\leq m\leq l.}$

Proof[edit]

The Associated Legendre Functions are regular solutions to the general Legendre equation: ${\displaystyle \left(\left[1-x^{2}\right]y^{'}\right)^{'}+\left(l\left[l+1\right]-{\frac {m^{2}}{1-x^{2}}}\right)y=0}$ , where ${\displaystyle z^{'}={\frac {dz}{dx}}.}$

This equation is an example of a more general class of equations known as the Sturm-Liouville equations. Using Sturm-Liouville theory, one can show that ${\displaystyle K_{kl}^{m}=\int \limits _{-1}^{1}P_{k}^{m}\left(x\right)P_{l}^{m}\left(x\right)dx}$ vanishes when ${\displaystyle k\neq l.}$ However, one can find ${\displaystyle K_{kl}^{m}}$ directly from the above definition, whether or not ${\displaystyle k=l:}$

${\displaystyle K_{kl}^{m}={\frac {1}{2^{k+l}\left(k!\right)\left(l!\right)}}\int \limits _{-1}^{1}\left\{\left(1-x^{2}\right)^{m}{\frac {d^{k+m}}{dx^{k+m}}}\left[\left(x^{2}-1\right)^{k}\right]\right\}\left\{{\frac {d^{l+m}}{dx^{l+m}}}\left[\left(x^{2}-1\right)^{l}\right]\right\}dx.}$

Since ${\displaystyle k}$ and ${\displaystyle l}$ occur symmetrically, one can without loss of generality assume that ${\displaystyle l\geq k.}$ Integrate by parts ${\displaystyle l+m}$ times, where the curly brackets in the integral indicate the factors, the first being ${\displaystyle u}$ and the second ${\displaystyle v'.}$ For each of the first ${\displaystyle m}$ integrations by parts, ${\displaystyle u}$ in the ${\displaystyle \left.uv\right|_{-1}^{1}}$ term contains the factor ${\displaystyle \left(1-x^{2}\right)}$; so the term vanishes. For each of the remaining ${\displaystyle l}$ integrations, ${\displaystyle v}$ in that term contains the factor ${\displaystyle \left(x^{2}-1\right)}$; so the term also vanishes. This means:

${\displaystyle K_{kl}^{m}={\frac {\left(-1\right)^{l+m}}{2^{k+l}\left(k!\right)\left(l!\right)}}\int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}{\frac {d^{l+m}}{dx^{l+m}}}\left[\left(1-x^{2}\right)^{m}{\frac {d^{k+m}}{dx^{k+m}}}\left[\left(x^{2}-1\right)^{k}\right]\right]dx.}$

Expand the second factor using Leibnitz' rule:

${\displaystyle {\frac {d^{l+m}}{dx^{l+m}}}\left[\left(1-x^{2}\right)^{m}{\frac {d^{k+m}}{dx^{k+m}}}\left[\left(x^{2}-1\right)^{k}\right]\right]=\sum \limits _{r=0}^{l+m}{\frac {\left(l+m\right)!}{r!\left(l+m-r\right)!}}{\frac {d^{r}}{dx^{r}}}\left[\left(1-x^{2}\right)^{m}\right]{\frac {d^{l+k+2m-r}}{dx^{l+k+2m-r}}}\left[\left(x^{2}-1\right)^{k}\right].}$

The leftmost derivative in the sum is non-zero only when ${\displaystyle r\leq 2m}$ (remembering that ${\displaystyle m\leq l}$ ). The other derivative is non-zero only when ${\displaystyle k+l+2m-r\leq 2k}$, that is, when ${\displaystyle r\geq 2m+(l-k).}$ Because ${\displaystyle l\geq k}$ these two conditions imply that the only non-zero term in the sum occurs when ${\displaystyle r=2m}$ and ${\displaystyle l=k.}$ So:

${\displaystyle K_{kl}^{m}={\frac {\left(-1\right)^{l+m}}{2^{2l}\left(l!\right)^{2}}}{\frac {\left(l+m\right)!}{\left(2m\right)!\left(l-m\right)!}}\delta _{kl}\int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}{\frac {d^{2m}}{dx^{2m}}}\left[\left(1-x^{2}\right)^{m}\right]{\frac {d^{2l}}{dx^{2l}}}\left[\left(1-x^{2}\right)^{l}\right]dx.}$

To evaluate the differentiated factors, expand ${\displaystyle \left(1-x^{2}\right)^{k}}$ using the binomial theorem: ${\displaystyle \left(1-x^{2}\right)^{k}=\sum \limits _{j=0}^{k}\left({\begin{array}{c}k\\j\end{array}}\right)\left(-1\right)^{k-j}x^{2\left(k-j\right)}.}$ The only thing that survives differentiation ${\displaystyle 2k}$ times is the ${\displaystyle x^{2k}}$ term, which (after differentiation) equals: ${\displaystyle \left(-1\right)^{k}\left({\begin{array}{c}k\\0\end{array}}\right)\left(2k\right)!=\left(-1\right)^{k}\left(2k\right)!}$. Therefore:

${\displaystyle K_{kl}^{m}={\frac {1}{2^{2l}\left(l!\right)^{2}}}{\frac {\left(2l\right)!\left(l+m\right)!}{\left(l-m\right)!}}\delta _{kl}\int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}dx}$ ................................................. (1)

Evaluate ${\displaystyle \int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}dx}$ by a change of variable: ${\displaystyle x=\cos \theta \Rightarrow dx=-\sin \theta d\theta \;and\;1-x^{2}=\sin \theta .}$ Thus, ${\displaystyle \int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}dx=\int \limits _{0}^{\pi }\left(\sin \theta \right)^{2l+1}d\theta .}$ [To eliminate the negative sign on the second integral, the limits are switched from ${\displaystyle \pi \rightarrow 0\;}$ to ${\displaystyle \;0\rightarrow \pi }$ , recalling that ${\displaystyle \;-1=\cos(\pi )\;}$ and ${\displaystyle \;1=\cos(0)\;}$].

A table of standard trigonometric integrals shows: ${\displaystyle \int \limits _{0}^{\pi }\sin ^{n}\theta d\theta ={\frac {\left.-\sin \theta \cos \theta \right|_{0}^{\pi }}{n}}+{\frac {\left(n-1\right)}{n}}\int \limits _{0}^{\pi }\sin ^{n-2}\theta d\theta .}$ Since ${\displaystyle \left.-\sin \theta \cos \theta \right|_{0}^{\pi }=0,}$ ${\displaystyle \int \limits _{0}^{\pi }\sin ^{n}\theta d\theta ={\frac {\left(n-1\right)}{n}}\int \limits _{0}^{\pi }\sin ^{n-2}\theta d\theta }$ for ${\displaystyle n\geq 2.}$ Applying this result to ${\displaystyle \int \limits _{0}^{\pi }\left(\sin \theta \right)^{2l+1}d\theta }$ and changing the variable back to ${\displaystyle x}$ yields: ${\displaystyle \int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}dx={\frac {2\left(l+1\right)}{2l+1}}\int \limits _{-1}^{1}\left(x^{2}-1\right)^{l-1}dx}$ for ${\displaystyle l\geq 1.}$ Using this recursively:

${\displaystyle \int \limits _{-1}^{1}\left(x^{2}-1\right)^{l}dx={\frac {2\left(l+1\right)}{2l+1}}{\frac {2\left(l\right)}{2l-1}}{\frac {2\left(l-1\right)}{2l-3}}...{\frac {2\left(2\right)}{3}}\left(2\right)={\frac {2^{l+1}l!}{\frac {\left(2l+1\right)!}{2^{l}l!}}}={\frac {2^{2l+1}\left(l!\right)^{2}}{\left(2l+1\right)!}}.}$

Applying this result to (1):

${\displaystyle K_{kl}^{m}={\frac {1}{2^{2l}\left(l!\right)^{2}}}{\frac {\left(2l\right)!\left(l+m\right)!}{\left(l-m\right)!}}{\frac {2^{2l+1}\left(l!\right)^{2}}{\left(2l+1\right)!}}\delta _{kl}={\frac {2}{2l+1}}{\frac {\left(l+m\right)!}{\left(l-m\right)!}}\delta _{kl}.}$ QED.

See also[edit]

• Associated Legendre Function
• Spherical Harmonics

References[edit]

• Kenneth Franklin Riley, Michael Paul Hobson, Stephen John Bence, "Mathematical methods for physics and engineering", pg. 590, (2006) 3${\displaystyle ^{rd}}$ Edition, Cambridge University Press, ISBN 0-521-67971-0.