Elliptic gamma function: Difference between revisions

Revision as of 10:49, 28 February 2013

In mathematics, the Picard–Fuchs equation, named after Émile Picard and Lazarus Fuchs, is a linear ordinary differential equation whose solutions describe the periods of elliptic curves.

Definition

Let

j = \frac{g_{2}^{3}}{g_{2}^{3} - 27 g_{3}^{2}}

be the j-invariant with $g_{2}$ and $g_{3}$ the modular invariants of the elliptic curve in Weierstrass form:

y^{2} = 4 x^{3} - g_{2} x - g_{3} .

Note that the j-invariant is an isomorphism from the Riemann surface $ℍ / Γ$ to the Riemann sphere $ℂ \cup {\infty}$ ; where $ℍ$ is the upper half-plane and $Γ$ is the modular group. The Picard–Fuchs equation is then

\frac{d^{2} y}{d j^{2}} + \frac{1}{j} \frac{d y}{d j} + \frac{31 j - 4}{144 j^{2} (1 - j)^{2}} y = 0 .

Written in Q-form, one has

\frac{d^{2} f}{d j^{2}} + \frac{1 - 1968 j + 2654208 j^{2}}{4 j^{2} (1 - 1728 j)^{2}} f = 0 .

Solutions

This equation can be cast into the form of the hypergeometric differential equation. It has two linearly independent solutions, called the periods of elliptic functions. The ratio of the two periods is equal to the period ratio τ, the standard coordinate on the upper-half plane. However, the ratio of two solutions of the hypergeometric equation is also known as a Schwarz triangle map.

The Picard–Fuchs equation can be cast into the form of Riemann's differential equation, and thus solutions can be directly read off in terms of Riemann P-functions. One has

y (j) = P {\begin{matrix} 0 & 1 & \infty \\ 1 / 6 & 1 / 4 & 0 & j \\ - 1 / 6 & 3 / 4 & 0 \end{matrix}}

For an explicit formula of an inverse of the j-invariant see the article listed first in the references.

Dedekind defines the j-fn by its Schwarz derivative in his letter to Borchardt. As a partial fraction, it reveals the geometry of the fundamental domain: Here the first term is in error. We should see:

2 S τ (j) = (1 - 1 / 4) / (1 - j)^{2} + (1 - 1 / 9) / j^{2} + (1 - 1 / 4 - 1 / 9) / j (1 - j) .

Identities

This solution satisfies the differential equation

(S τ) (j) = \frac{3}{8 (1 - j)^{2}} + \frac{4}{9 j^{2}} + \frac{23}{72 j (1 - j)}

where (Sƒ)(x) is the Schwarzian derivative of ƒ with respect to x.

Generalization

In algebraic geometry this equation has been shown to be a very special case of a general phenomenon, the Gauss–Manin connection.

References

Template:Cite arXiv

J. Harnad and J. McKay, Modular solutions to equations of generalized Halphen type, Proc. R. Soc. London A 456 (2000), 261–294,

(Provides a readable introduction, some history, references, and various interesting identities and relations between solutions)

J. Harnad, Picard–Fuchs Equations, Hauptmoduls and Integrable Systems, Chapter 8 (Pgs. 137–152) of Integrability: The Seiberg–Witten and Witham Equation (Eds. H.W. Braden and I.M. Krichever, Gordon and Breach, Amsterdam (2000)).

(Provides further examples of Picard–Fuchs equations satisfied by modular functions of genus 0, including non-triangular ones, and introduces Inhomogeneous Picard–Fuchs equations as special solutions to isomonodromic deformation equations of Painlevé type.)

de:J-Funktion

@@ Line 1: / Line 1: @@
-Hi there, I am Alyson Boon although it is not the title on my birth certification. What me and my family members love is doing ballet but I've been using on new issues recently. I am presently a travel agent. My spouse and I live in Mississippi and I adore every day living here.<br><br>my blog :: certified psychics ([http://Thebankchina.com/index.php?do=/profile-12480/info/ click on Thebankchina.com Thebankchina.com])
+In [[mathematics]], the '''Picard–Fuchs equation''', named after [[Émile Picard]] and [[Lazarus Fuchs]], is a linear [[ordinary differential equation]] whose solutions describe the periods of [[elliptic curve]]s.
+==Definition==
+Let
+:<math>j=\frac{g_2^3}{g_2^3-27g_3^2}</math>
+be the [[j-invariant]] with <math>g_2</math> and <math>g_3</math> the [[modular invariant]]s of the elliptic curve in [[Weierstrass equation|Weierstrass form]]:
+:<math>y^2=4x^3-g_2x-g_3.\,</math>
+Note that the ''j''-invariant is an [[isomorphism]] from the [[Riemann surface]] <math> \mathbb{H}/\Gamma </math> to the [[Riemann sphere]] <math>\mathbb{C}\cup\{\infty\}</math>; where <math>\mathbb{H}</math> is the [[upper half-plane]] and <math>\Gamma</math> is the [[modular group]].  The Picard–Fuchs equation is then
+:<math>\frac{d^2y}{dj^2} + \frac{1}{j} \frac{dy}{dj} +
+\frac{31j -4}{144j^2(1-j)^2} y=0.\,</math>
+Written in [[Schwarzian derivative|Q-form]], one has
+:<math>\frac{d^2f}{dj^2} +
+\frac{1-1968j + 2654208j^2}{4j^2 (1-1728j)^2} f=0.\,</math>
+==Solutions==
+This equation can be cast into the form of the [[hypergeometric differential equation]].  It has two linearly independent solutions, called the '''periods''' of elliptic functions.  The ratio of the two periods is equal to the [[half-period ratio|period ratio]] τ, the standard coordinate on the upper-half plane. However, the ratio of two solutions of the hypergeometric equation is also known as a [[Schwarz triangle map]].
+The Picard–Fuchs equation can be cast into the form of [[Riemann's differential equation]], and thus solutions can be directly read off in terms of [[Riemann P-function]]s. One has
+:<math>y(j)=P  \left\{ \begin{matrix}
+& 1 & \infty & \; \\
+{1/6} & {1/4} & 0 & j \\
+{-1/6\;} & {3/4} & 0 & \;
+\end{matrix} \right\}\,</math>
+For an explicit formula of an inverse of the ''j''-invariant see the article listed first in the references.
+Dedekind defines the ''j''-fn by its Schwarz derivative in his letter to Borchardt.   As a partial fraction, it reveals the geometry of the
+fundamental domain:    Here the first term is in error. We should see:
+: <math> 2S\tau(j) = (1-1/4)/(1-j)^2 + (1-1/9)/j^2 + (1-1/4-1/9)/j(1-j). \,  </math>
+==Identities==
+This solution satisfies the differential equation
+:<math>(S\tau)(j)=\frac{3}{8(1-j)^2}+\frac{4}{9j^2}+\frac{23}{72j(1-j)}</math>
+where (''Sƒ'')(''x'') is the [[Schwarzian derivative]] of ''ƒ'' with respect to ''x''.
+==Generalization==
+In [[algebraic geometry]] this equation has been shown to be a very special case of a general phenomenon, the [[Gauss&ndash;Manin connection]].
+==References==
+* {{cite arXiv |last=Adlaj |first=Semjon |eprint=1110.3274 |class=math.NT |title=An inverse of the modular invariant |year=2011}}
+* [[J. Harnad]] and J. McKay, ''Modular solutions to equations of generalized Halphen type'', Proc. R. Soc. London A '''456''' (2000), 261&ndash;294,
+:(Provides a readable introduction, some history, references, and various interesting identities and relations between solutions)
+* J. Harnad, ''Picard–Fuchs Equations, Hauptmoduls and Integrable Systems'', Chapter 8 (Pgs. 137&ndash;152) of ''Integrability:  The Seiberg–Witten and Witham Equation'' (Eds. H.W. Braden and I.M. Krichever, Gordon and Breach, Amsterdam (2000)).
+:(Provides further examples of Picard–Fuchs equations satisfied by modular functions of genus 0, including non-triangular ones, and introduces ''Inhomogeneous Picard–Fuchs equations'' as special solutions to [[isomonodromic deformation]] equations of [[Painlevé type]].)
+{{DEFAULTSORT:Picard-Fuchs Equation}}
+[[Category:Elliptic functions]]
+[[Category:Modular forms]]
+[[Category:Hypergeometric functions]]
+[[Category:Ordinary differential equations]]
+[[de:J-Funktion]]

Elliptic gamma function: Difference between revisions

Revision as of 10:49, 28 February 2013

Contents

Definition

Solutions

Identities

Generalization

References

Navigation menu

Elliptic gamma function: Difference between revisions

Revision as of 10:49, 28 February 2013

Definition

Solutions

Identities

Generalization

References

Navigation menu

Search