Associated Legendre function: Difference between revisions

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• See Associated Legendre function/Catalogs for explicit equations through ${\displaystyle \ell =6.\,}$

In mathematics and physics, an associated Legendre function P_l^m is related to a Legendre polynomial P_l by the following equation

${\displaystyle P_{\ell }^{m}(x)=(1-x^{2})^{m/2}{\frac {d^{m}P_{\ell }(x)}{dx^{m}}},\qquad 0\leq m\leq \ell .}$

Although extensions are possible, in this article ${\displaystyle \ell \,}$ and m are restricted to integer numbers. For even m the associated Legendre function is a polynomial, for odd m the function contains the factor (1−x ² )^½ and hence is not a polynomial.

The associated Legendre functions are important in quantum mechanics and potential theory.

According to Ferrers^[1] the polynomials were named "Associated Legendre functions" by the British mathematician Isaac Todhunter in 1875,^[2] where "associated function" is Todhunter's translation of the German term zugeordnete Function, coined in 1861 by Heine,^[3] and "Legendre" is in honor of the French mathematician Adrien-Marie Legendre (1752–1833), who was the first to introduce and study the functions.

Differential equation

Define

${\displaystyle \Pi _{\ell }^{m}(x)\equiv {\frac {d^{m}P_{\ell }(x)}{dx^{m}}},}$

where P_l(x) is a Legendre polynomial. Differentiating the Legendre differential equation:

${\displaystyle (1-x^{2}){\frac {d^{2}\Pi _{\ell }^{0}(x)}{dx^{2}}}-2x{\frac {d\Pi _{\ell }^{0}(x)}{dx}}+\ell (\ell +1)\Pi _{\ell }^{0}(x)=0,}$

m times gives an equation for Π^m_l

${\displaystyle (1-x^{2}){\frac {d^{2}\Pi _{\ell }^{m}(x)}{dx^{2}}}-2(m+1)x{\frac {d\Pi _{\ell }^{m}(x)}{dx}}+\left[\ell (\ell +1)-m(m+1)\right]\Pi _{\ell }^{m}(x)=0.}$

After substitution of

${\displaystyle \Pi _{\ell }^{m}(x)=(1-x^{2})^{-m/2}P_{\ell }^{m}(x),}$

and after multiplying through with ${\displaystyle (1-x^{2})^{m/2}}$, we find the associated Legendre differential equation:

${\displaystyle (1-x^{2}){\frac {d^{2}P_{\ell }^{m}(x)}{dx^{2}}}-2x{\frac {dP_{\ell }^{m}(x)}{dx}}+\left[\ell (\ell +1)-{\frac {m^{2}}{1-x^{2}}}\right]P_{\ell }^{m}(x)=0.}$

One often finds the equation written in the following equivalent way

${\displaystyle \left((1-x^{2})\;y\,'\right)'+\left(\ell (\ell +1)-{\frac {m^{2}}{1-x^{2}}}\right)y=0,}$

where the primes indicate differentiation with respect to x.

In physical applications it is usually the case that x = cosθ, then the associated Legendre differential equation takes the form

${\displaystyle {\frac {1}{\sin \theta }}{\frac {d}{d\theta }}\sin \theta {\frac {d}{d\theta }}P_{\ell }^{m}+\left[\ell (\ell +1)-{\frac {m^{2}}{\sin ^{2}\theta }}\right]P_{\ell }^{m}=0.}$

Extension to negative m

By the Rodrigues formula, one obtains

${\displaystyle P_{\ell }^{m}(x)={\frac {1}{2^{\ell }\ell !}}(1-x^{2})^{m/2}\ {\frac {d^{\ell +m}}{dx^{\ell +m}}}(x^{2}-1)^{\ell }.}$

This equation allows extension of the range of m to: ${\displaystyle -m\leq \ell \leq m}$.

Since the associated Legendre equation is invariant under the substitution m → −m, the equations for P_l ^±m, resulting from this expression, are proportional.^[4]

To obtain the proportionality constant we consider

${\displaystyle (1-x^{2})^{-m/2}{\frac {d^{\ell -m}}{dx^{\ell -m}}}(x^{2}-1)^{\ell }=c_{lm}(1-x^{2})^{m/2}{\frac {d^{\ell +m}}{dx^{\ell +m}}}(x^{2}-1)^{\ell },\qquad 0\leq m\leq \ell ,}$

and we bring the factor (1−x²)^−m/2 to the other side. Equate the coefficient of the highest power of x on the left and right hand side of

${\displaystyle {\frac {d^{\ell -m}}{dx^{\ell -m}}}(x^{2}-1)^{\ell }=c_{lm}(1-x^{2})^{m}{\frac {d^{\ell +m}}{dx^{\ell +m}}}(x^{2}-1)^{\ell },\qquad 0\leq m\leq \ell ,}$

and it follows that the proportionality constant is

${\displaystyle c_{lm}=(-1)^{m}{\frac {(\ell -m)!}{(\ell +m)!}},\qquad 0\leq m\leq \ell ,}$

so that the associated Legendre functions of same |m| are related to each other by

${\displaystyle P_{\ell }^{-|m|}(x)=(-1)^{m}{\frac {(\ell -|m|)!}{(\ell +|m|)!}}P_{\ell }^{|m|}(x).}$

Note that the phase factor (−1)^m arising in this expression is not due to some arbitrary phase convention, but arises from expansion of (1−x²)^m.

Orthogonality relations

Important integral relations are:

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

(see the subpage Proofs for a detailed proof of this relation) and:

${\displaystyle \int _{-1}^{1}P_{\ell }^{m}(x)P_{\ell }^{n}(x){\frac {dx}{1-x^{2}}}={\frac {\delta _{mn}(\ell +m)!}{m(\ell -m)!}},\qquad m\neq 0.}$

The latter integral for n = m = 0

${\displaystyle \int _{-1}^{1}P_{\ell }^{0}(x)P_{\ell }^{0}(x){\frac {dx}{1-x^{2}}}}$

is undetermined (infinite).

Recurrence relations

The functions satisfy the following difference equations, which are taken from Edmonds.^[5]

${\displaystyle (\ell -m+1)P_{\ell +1}^{m}(x)-(2\ell +1)xP_{\ell }^{m}(x)+(\ell +m)P_{\ell -1}^{m}(x)=0}$

${\displaystyle xP_{\ell }^{m}(x)-(\ell -m+1)(1-x^{2})^{1/2}P_{\ell }^{m-1}(x)-P_{\ell -1}^{m}(x)=0}$

${\displaystyle P_{\ell +1}^{m}(x)-xP_{\ell }^{m}(x)-(\ell +m)(1-x^{2})^{1/2}P_{\ell }^{m-1}(x)=0}$

${\displaystyle (\ell -m+1)P_{\ell +1}^{m}(x)+(1-x^{2})^{1/2}P_{\ell }^{m+1}(x)-(\ell +m+1)xP_{\ell }^{m}(x)=0}$

${\displaystyle (1-x^{2})^{1/2}P_{\ell }^{m+1}(x)-2mxP_{\ell }^{m}(x)+(\ell +m)(\ell -m+1)(1-x^{2})^{1/2}P_{\ell }^{m-1}(x)=0}$

${\displaystyle (1-x^{2}){\frac {dP_{\ell }^{m}}{dx}}(x)=(\ell +1)xP_{\ell }^{m}(x)-(\ell -m+1)P_{\ell +1}^{m}(x)}$

${\displaystyle =(\ell +m)P_{\ell -1}^{m}(x)-\ell xP_{\ell }^{m}(x)}$

Reference