Associated Legendre function: Difference between revisions
imported>Dan Nessett (→Orthogonality relations: Modified first orthogonality equation to bring it and the equation provided in the proof into conformance) |
mNo edit summary |
||
(5 intermediate revisions by 2 users not shown) | |||
Line 2: | Line 2: | ||
{{TOC|right}} | {{TOC|right}} | ||
:*''See [[Associated Legendre function/Catalogs]] for explicit equations through'' | :*''See [[Associated Legendre function/Catalogs]] for explicit equations through'' ''ℓ'' = 6. | ||
In [[mathematics]] and [[physics]], an '''associated Legendre function''' ''P''<sub>'' | In [[mathematics]] and [[physics]], an '''associated Legendre function''' ''P''<sub>''ℓ''</sub><sup>''m''</sup> is related to a [[Legendre polynomial]] ''P''<sub>''ℓ''</sub> by the following equation | ||
:<math> | :<math> | ||
P^{m}_\ell(x) = (1-x^2)^{m/2} \frac{d^m P_\ell(x)}{dx^m}, \qquad 0 \le m \le \ell. | P^{m}_\ell(x) = (1-x^2)^{m/2} \frac{d^m P_\ell(x)}{dx^m}, \qquad 0 \le m \le \ell. | ||
</math> | </math> | ||
Although extensions are possible, in this article | Although extensions are possible, in this article ''ℓ'' 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 )<sup>½</sup> and hence is not a polynomial. | ||
The associated Legendre functions are important in [[quantum mechanics]] and [[potential theory]]. | The associated Legendre functions are important in [[quantum mechanics]] and [[potential theory]]. | ||
Line 19: | Line 19: | ||
\Pi^{m}_\ell(x) \equiv \frac{d^m P_\ell(x)}{dx^m}, | \Pi^{m}_\ell(x) \equiv \frac{d^m P_\ell(x)}{dx^m}, | ||
</math> | </math> | ||
where ''P''<sub>'' | where ''P''<sub>''ℓ''</sub>(''x'') is a Legendre polynomial. | ||
Differentiating the [[Legendre polynomials#differential equation|Legendre differential equation]]: | Differentiating the [[Legendre polynomials#differential equation|Legendre differential equation]]: | ||
:<math> | :<math> | ||
Line 57: | Line 57: | ||
:<math>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.</math> | :<math>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.</math> | ||
This equation allows extension of the range of ''m'' to: | This equation allows extension of the range of ''m'' to: −''m'' ≤ ''ℓ'' ≤ ''m''. | ||
Since the associated Legendre equation is invariant under the substitution ''m'' → −''m'', the equations for ''P''<sub>'' | Since the associated Legendre equation is invariant under the substitution ''m'' → −''m'', the equations for ''P''<sub>''ℓ''</sub><sup> ±''m''</sup>, resulting from this expression, are proportional.<ref>The associated Legendre differential equation being of second order, the general solution is of the form <math>AP_\ell^m + BQ_\ell^m</math> where <math>Q_\ell^m</math> is a Legendre polynomial of the second kind, which has a singularity at ''x'' = 0. Hence solutions that are regular at ''x'' = 0 have ''B'' = 0 and are proportional to <math>P_\ell^m</math>. The Rodrigues formula shows that <math>P_\ell^{-m}</math> is a regular (at ''x''=0) solution and the proportionality follows.</ref> | ||
To obtain the proportionality constant we consider | To obtain the proportionality constant we consider | ||
Line 85: | Line 85: | ||
dx =\frac{2}{2l+1} \frac{\left( l+m\right) !}{\left( l-m\right) !} \delta | dx =\frac{2}{2l+1} \frac{\left( l+m\right) !}{\left( l-m\right) !} \delta | ||
_{lk}, </math> | _{lk}, </math> | ||
and: | |||
:<math> | :<math> | ||
\int_{-1}^{1} P^{m}_{\ell}(x) P^{n}_{\ell}(x) \frac{d x}{1-x^2} = | \int_{-1}^{1} P^{m}_{\ell}(x) P^{n}_{\ell}(x) \frac{d x}{1-x^2} = | ||
Line 94: | Line 94: | ||
\int_{-1}^{1} P^{0}_{\ell}(x) P^{0}_{\ell}(x) \frac{d x}{1-x^2} | \int_{-1}^{1} P^{0}_{\ell}(x) P^{0}_{\ell}(x) \frac{d x}{1-x^2} | ||
</math> | </math> | ||
is undetermined (infinite). | is undetermined (infinite). (see the subpage [[Associated_Legendre_function/Proofs|Proofs]] for detailed proofs of these relations.) | ||
==Recurrence relations== | ==Recurrence relations== | ||
Line 130: | Line 130: | ||
==Reference== | ==Reference== | ||
<references /> | <references />[[Category:Suggestion Bot Tag]] |
Latest revision as of 16:00, 13 July 2024
- See Associated Legendre function/Catalogs for explicit equations through ℓ = 6.
In mathematics and physics, an associated Legendre function Pℓm is related to a Legendre polynomial Pℓ by the following equation
Although extensions are possible, in this article ℓ 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
where Pℓ(x) is a Legendre polynomial. Differentiating the Legendre differential equation:
m times gives an equation for Πml
After substitution of
and after multiplying through with , we find the associated Legendre differential equation:
One often finds the equation written in the following equivalent way
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
Extension to negative m
By the Rodrigues formula, one obtains
This equation allows extension of the range of m to: −m ≤ ℓ ≤ m.
Since the associated Legendre equation is invariant under the substitution m → −m, the equations for Pℓ ±m, resulting from this expression, are proportional.[4]
To obtain the proportionality constant we consider
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
and it follows that the proportionality constant is
so that the associated Legendre functions of same |m| are related to each other by
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:
and:
The latter integral for n = m = 0
is undetermined (infinite). (see the subpage Proofs for detailed proofs of these relations.)
Recurrence relations
The functions satisfy the following difference equations, which are taken from Edmonds.[5]
Reference
- ↑ N. M. Ferrers, An Elementary Treatise on Spherical Harmonics, MacMillan, 1877 (London), p. 77. Online.
- ↑ I. Todhunter, An Elementary Treatise on Laplace's, Lamé's, and Bessel's Functions, MacMillan, 1875 (London). In fact, Todhunter called the Legendre polynomials "Legendre coefficients".
- ↑ E. Heine, Handbuch der Kugelfunctionen, G. Reimer, 1861 (Berlin).Google book online
- ↑ The associated Legendre differential equation being of second order, the general solution is of the form where is a Legendre polynomial of the second kind, which has a singularity at x = 0. Hence solutions that are regular at x = 0 have B = 0 and are proportional to . The Rodrigues formula shows that is a regular (at x=0) solution and the proportionality follows.
- ↑ A. R. Edmonds, Angular Momentum in Quantum Mechanics, Princeton University Press, 2nd edition (1960)