Legendre polynomials: Difference between revisions
imported>Paul Wormer (→Recurrence Relations: added another recursion relation) |
mNo edit summary |
||
(16 intermediate revisions by 2 users not shown) | |||
Line 1: | Line 1: | ||
In [[mathematics]], the '''Legendre polynomials''' ''P''<sub>''n''</sub>(''x'') are [[orthogonal polynomials]] in the variable | {{subpages}} | ||
{{TOC|right}} | |||
*''See [[Legendre polynomials/Catalogs]] for the first 12 Legendre polynomials.'' | |||
In [[mathematics]], the '''Legendre polynomials''' ''P''<sub>''n''</sub>(''x'') are [[orthogonal polynomials]] in the variable −1 ≤ ''x'' ≤ 1. Their orthogonality is with unit weight, | |||
:<math> | :<math> | ||
\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> | ||
In [[physics]] they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with ''x'' = cosθ | In [[physics]] they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with ''x'' = cosθ | ||
Line 9: | Line 15: | ||
\int^{\pi}_{0} P_{n}(\cos\theta) P_{n'}(\cos\theta) \sin\theta \;d\theta = 0\quad \hbox{for}\quad n\ne n'. | \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 the sequential [[Gram-Schmidt orthogonalization]] procedure applied to {1, ''x'', ''x''², x³, …} the | The polynomials as function of cosθ are part of the solution of the [[Laplace equation]] in [[spherical polar coordinates]]. | ||
By the sequential [[Gram-Schmidt orthogonalization]] procedure applied to {1, ''x'', ''x''², x³, …} the ''n''<sup>th</sup> degree polynomial ''P''<sub>''n''</sub> can be constructed recursively. The Gram-Schmidt procedure applies to all members of the family of [[orthogonal polynomials]], such as Hermite polynomials, Chebyshev polynomials, etc. Further, ''P''<sub>''n''</sub>(''x'') has in common with the other orthogonal polynomials that it has exactly ''n'' real distinct zeroes. These zeroes are used as grid points in [[Gauss quadrature]] (numerical integration) schemes. | |||
==Historical note== | |||
The polynomials were named "Legendre coefficients" by the British mathematician [[Isaac Todhunter]]<ref>I. Todhunter, ''An Elementary Treatise on Laplace's, Lamé's, and Bessel's Functions'', MacMillan, 1875 (London) [http://books.google.nl/books?id=0UGAePAs6pMC&pg=PP1&lpg=PP1&dq=%22Isaac+Todhunter%22+Treatise+Laplace&source=bl&ots=WKx4CooRAe&sig=lWqwuvttgJ7xFl7s9udaItHl7gg&hl=nl&ei=OSSiSrmxBojz-Qb3mMHbDw&sa=X&oi=book_result&ct=result&resnum=6#v=onepage&q=%22Isaac%20Todhunter%22%20Treatise%20Laplace&f=false Google book].</ref> in honor of the French mathematician [[Adrien-Marie Legendre]] (1752–1833), who was the first to introduce and study them. Todhunter called the functions "coefficients", instead of "polynomials", because they appear as coefficients of ''h''<sup>''n''</sup> in the expansion of the generating function ([[#GF|see below]]); Todhunter also introduced the notation ''P''<sub>''n''</sub>, which is still generally used. | |||
Legendre's polynomials have been introduced by Legendre in a memoir ''Sur l'attraction des sphéroïdes homogènes'' published in the ''Mémoires de Mathématiques et de Physique, présentés à l'Académie royale des sciences par sçavants étrangers'', Tome x, pp. 411–435, Paris, 1785.<ref> [http://edocs.ub.uni-frankfurt.de/volltexte/2007/3757/pdf/A009566090.pdf Full text online]: ''Recherches Sur l'attraction des sphéroïdes homogènes'' par M. Le Gendre. Retrieved September 10, 2009.</ref>. The functions also occur in a memoir by Laplace received by the Academy in 1782, ''Théorie des attractions des sphéroïdes et de la figure des planètes'', but the original introduction of the functions appears nevertheless to be due to Legendre, whose work was not published for several years after it was written; his memoir is mentioned as approved for publication in the report of the sittings of the Academy for 1783. Legendre himself declares that Laplace introduced the potential (i.e., generating) function, but that he himself developed the expansion. Later, the mathematicians [[Carl Gustav Jacob Jacobi|Jacobi]], [[Johann Peter Gustav Lejeune Dirichlet|Dirichlet]], and [[Heinrich Eduard Heine|Heine]] have written on the question of priority and agree that Legendre deserves the credit. | |||
==Rodrigues' formula== | ==Rodrigues' formula== | ||
The French amateur mathematician Rodrigues (1795–1851) proved the following formula | The French amateur mathematician [[Olinde Rodrigues]] (1795–1851) proved the following formula | ||
:<math> | :<math> | ||
P_n(x) = {1 \over 2^n n!} \frac{d^n(x^2 -1)^n}{dx^n} . | P_n(x) = {1 \over 2^n n!} \frac{d^n(x^2 -1)^n}{dx^n} . | ||
Line 18: | Line 31: | ||
Using the [[Newton binomial]] and the equation | Using the [[Newton binomial]] and the equation | ||
:<math> | :<math> | ||
\frac{d^ | \frac{d^n x^m}{dx^n} = \frac{m!}{(m-n)!} x^{m-n}, \quad\hbox{for}\quad n\le m, | ||
</math> | </math> | ||
we get the explicit expression | we get the explicit expression | ||
Line 24: | Line 37: | ||
P_n(x) = \frac{1}{2^n \, n!}\sum_{k=\lceil n/2 \rceil}^n (-1)^{n-k} {n \choose k}\frac{(2k)!}{(2k-n)!} x ^{2k-n} . | P_n(x) = \frac{1}{2^n \, n!}\sum_{k=\lceil n/2 \rceil}^n (-1)^{n-k} {n \choose k}\frac{(2k)!}{(2k-n)!} x ^{2k-n} . | ||
</math> | </math> | ||
Substitution ''p''=''n''-''k'' gives this formula a slightly different appearance | |||
:<math> | |||
P_n(x) = \frac{1}{2^n} \sum_{p=0}^{\lfloor n/2 \rfloor} (-1)^p \frac{(2n-2p)!}{p!(n-p)!(n-2p)!} x^{n-2p}. | |||
</math> | |||
<div id=GF> </div> | |||
==Generating function== | ==Generating function== | ||
The coefficients of ''h''<sup>''n''</sup> in the following expansion of the generating function are Legendre polynomials | The coefficients of ''h''<sup>''n''</sup> in the following expansion of the generating function are Legendre polynomials | ||
Line 39: | Line 58: | ||
h\equiv \frac{r}{R}\quad \hbox{and}\quad x \equiv \cos\gamma \equiv \mathbf{r}\cdot\mathbf{R}/(rR). | h\equiv \frac{r}{R}\quad \hbox{and}\quad x \equiv \cos\gamma \equiv \mathbf{r}\cdot\mathbf{R}/(rR). | ||
</math> | </math> | ||
Obviously the expansion makes sense only if ''R'' > ''r''. | Obviously the expansion makes sense only if ''R'' > ''r''. The function appears in [[Newton]]'s gravitational potential and in [[Coulomb]]'s electrostatic potential. | ||
==Normalization== | ==Normalization== | ||
The polynomials are not normalized to unity | The polynomials are not normalized to unity, but | ||
:<math> | :<math> | ||
\int_{-1}^{1} P_{n}(x) P_{m}(x) dx = \frac{2}{2n+1} \delta_{n m}, | \int_{-1}^{1} P_{n}(x) P_{m}(x) dx = \frac{2}{2n+1} \delta_{n m}, | ||
</math> | </math> | ||
where δ<sub>'' | where δ<sub>''nm''</sub> is the [[Kronecker delta]]. | ||
==Differential equation== | ==Differential equation== | ||
The Legendre polynomials are solutions of the Legendre differential equation | The Legendre polynomials are solutions of the Legendre differential equation | ||
Line 54: | Line 74: | ||
This differential equation has another class of solutions: ''Legendre functions of the second kind'' ''Q''<sub>''n''</sub>(x), which are infinite series in 1/''x''. These functions are of lesser importance. | This differential equation has another class of solutions: ''Legendre functions of the second kind'' ''Q''<sub>''n''</sub>(x), which are infinite series in 1/''x''. These functions are of lesser importance. | ||
Note that the differential equation has the form of an [[eigenvalue equation]] with eigenvalue | Note that the differential equation has the form of an [[eigenvalue equation]] with eigenvalue −''n''(''n''+1) of the operator | ||
:<math> | :<math> | ||
\frac{d}{d\cos\theta} \sin^2\theta \frac{d}{d\cos\theta} | \frac{d}{d\cos\theta} \sin^2\theta \frac{d}{d\cos\theta} | ||
Line 62: | Line 82: | ||
==Properties of Legendre polynomials == | ==Properties of Legendre polynomials == | ||
Legendre polynomials have parity ( | Legendre polynomials have parity (−1)<sup>''n''</sup> under ''x'' → -''x'', | ||
:<math>P_n(-x) = (-1)^n P_n(x). \,</math> | :<math>P_n(-x) = (-1)^n P_n(x). \,</math> | ||
Line 82: | Line 102: | ||
\frac{d \big(P_{n+1} - P_{n-1}\big)}{dx} = (2n+1) P_n . | \frac{d \big(P_{n+1} - P_{n-1}\big)}{dx} = (2n+1) P_n . | ||
</math> | </math> | ||
==External link== | |||
Weisstein, Eric W. "Legendre Polynomial." From MathWorld--A Wolfram Web Resource. [http://mathworld.wolfram.com/LegendrePolynomial.html] | |||
==Footnote== | |||
<references />[[Category:Suggestion Bot Tag]] |
Latest revision as of 06:00, 11 September 2024
- See Legendre polynomials/Catalogs for the first 12 Legendre polynomials.
In mathematics, the Legendre polynomials Pn(x) are orthogonal polynomials in the variable −1 ≤ x ≤ 1. Their orthogonality is with unit weight,
In physics they commonly appear as a function of a polar angle 0 ≤ θ ≤ π with x = cosθ
- .
The polynomials as function of cosθ are part of the solution of the Laplace equation in spherical polar coordinates.
By the sequential Gram-Schmidt orthogonalization procedure applied to {1, x, x², x³, …} the nth degree polynomial Pn can be constructed recursively. The Gram-Schmidt procedure applies to all members of the family of orthogonal polynomials, such as Hermite polynomials, Chebyshev polynomials, etc. Further, Pn(x) has in common with the other orthogonal polynomials that it has exactly n real distinct zeroes. These zeroes are used as grid points in Gauss quadrature (numerical integration) schemes.
Historical note
The polynomials were named "Legendre coefficients" by the British mathematician Isaac Todhunter[1] in honor of the French mathematician Adrien-Marie Legendre (1752–1833), who was the first to introduce and study them. Todhunter called the functions "coefficients", instead of "polynomials", because they appear as coefficients of hn in the expansion of the generating function (see below); Todhunter also introduced the notation Pn, which is still generally used.
Legendre's polynomials have been introduced by Legendre in a memoir Sur l'attraction des sphéroïdes homogènes published in the Mémoires de Mathématiques et de Physique, présentés à l'Académie royale des sciences par sçavants étrangers, Tome x, pp. 411–435, Paris, 1785.[2]. The functions also occur in a memoir by Laplace received by the Academy in 1782, Théorie des attractions des sphéroïdes et de la figure des planètes, but the original introduction of the functions appears nevertheless to be due to Legendre, whose work was not published for several years after it was written; his memoir is mentioned as approved for publication in the report of the sittings of the Academy for 1783. Legendre himself declares that Laplace introduced the potential (i.e., generating) function, but that he himself developed the expansion. Later, the mathematicians Jacobi, Dirichlet, and Heine have written on the question of priority and agree that Legendre deserves the credit.
Rodrigues' formula
The French amateur mathematician Olinde Rodrigues (1795–1851) proved the following formula
Using the Newton binomial and the equation
we get the explicit expression
Substitution p=n-k gives this formula a slightly different appearance
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. The function appears in Newton's gravitational potential and in Coulomb's electrostatic potential.
Normalization
The polynomials are not normalized to unity, but
where δnm is the Kronecker delta.
Differential equation
The Legendre polynomials are solutions of the Legendre differential equation
This differential equation has another class of solutions: Legendre functions of the second kind Qn(x), which are infinite series in 1/x. These functions are of lesser importance.
Note that the differential equation has the form of an eigenvalue equation with eigenvalue −n(n+1) of the operator
This operator is the θ-dependent part of the Laplace operator ∇² in spherical polar coordinates.
Properties of Legendre polynomials
Legendre polynomials have parity (−1)n under x → -x,
The following condition normalizes the polynomials
Recurrence Relations
Legendre polynomials satisfy the recurrence relations
From these two relations follows easily
External link
Weisstein, Eric W. "Legendre Polynomial." From MathWorld--A Wolfram Web Resource. [1]
Footnote
- ↑ I. Todhunter, An Elementary Treatise on Laplace's, Lamé's, and Bessel's Functions, MacMillan, 1875 (London) Google book.
- ↑ Full text online: Recherches Sur l'attraction des sphéroïdes homogènes par M. Le Gendre. Retrieved September 10, 2009.