Legendre polynomials: Difference between revisions
imported>Paul Wormer (Start of Legendre polynomials (from scratch)) |
imported>Paul Wormer (Integral over cos theta in the lead) |
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\int_{-1}^{1} P_{n}(x) P_{n'}(x) dx = 0\quad \hbox{for}\quad n\ne n'. | \int_{-1}^{1} P_{n}(x) P_{n'}(x) dx = 0\quad \hbox{for}\quad n\ne n'. | ||
</math> | </math> | ||
The polynomials are named after the French mathematician [[Legendre]] (1752–1833). In [[physics]] they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with | The polynomials are named after the French mathematician [[Legendre]] (1752–1833). | ||
:<math> | |||
In [[physics]] they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with ''x'' = cosθ | |||
:<math> | |||
\int^{\pi}_{0} P_{n}(\cos\theta) P_{n'}(\cos\theta) \sin\theta \;d\theta = 0\quad \hbox{for}\quad n\ne n'. | |||
</math>. | </math>. | ||
By repeated [[Gram-Schmidt orthogonalization]]s the polynomials can be constructed. | By repeated [[Gram-Schmidt orthogonalization]]s the polynomials can be constructed. | ||
==Rodrigues' formula== | ==Rodrigues' formula== | ||
The French amateur mathematician Rodrigues (1795–1851) proved the following formula | The French amateur mathematician Rodrigues (1795–1851) proved the following formula |
Revision as of 04:41, 21 August 2007
In mathematics, the Legendre polynomials Pn(x) are orthogonal polynomials in the variable -1 ≤ x ≤ 1. Their orthonormality is with unit weight,
The polynomials are named after the French mathematician Legendre (1752–1833).
In physics they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with x = cosθ
- .
By repeated Gram-Schmidt orthogonalizations the polynomials can be constructed.
Rodrigues' formula
The French amateur mathematician Rodrigues (1795–1851) proved the following formula
Using the Newton binomial and the equation
we get the explicit expression
Generating function
The coefficients of hn in the following expansion of the generating function are Legendre polynomials
The expansion converges for |h| < 1. This expansion is useful in expanding the inverse distance between two points r and R
where
Obviously the expansion makes sense only if R > r.
Normalization
The polynomials are not normalized to unity
where δn m is the Kronecker delta.
Differential equation
The Legendre polynomials are solutions of the Legendre differential equation
This differential has another class of solutions: Legendre functions of the second kind Q_n(x), which are infinite series in 1/x. These functions are of lesser importance.