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In mathematics , the elliptic gamma function is a generalization of the q-Gamma function , which is itself the q-analog of the ordinary Gamma function . It is closely related to a function studied by Jackson (1905) , and can be expressed in terms of the triple gamma function . It is given by
Γ
(
z
;
p
,
q
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=
∏
m
=
0
∞
∏
n
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0
∞
1
−
p
m
+
1
q
n
+
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/
z
1
−
p
m
q
n
z
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{\displaystyle \Gamma (z;p,q)=\prod _{m=0}^{\infty }\prod _{n=0}^{\infty }{\frac {1-p^{m+1}q^{n+1}/z}{1-p^{m}q^{n}z}}.}
It obeys several identities:
Γ
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p
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q
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=
1
Γ
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p
q
/
z
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p
,
q
)
{\displaystyle \Gamma (z;p,q)={\frac {1}{\Gamma (pq/z;p,q)}}\,}
Γ
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p
z
;
p
,
q
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=
θ
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z
;
q
)
Γ
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{\displaystyle \Gamma (pz;p,q)=\theta (z;q)\Gamma (z;p,q)\,}
and
Γ
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q
z
;
p
,
q
)
=
θ
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z
;
p
)
Γ
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z
;
p
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q
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{\displaystyle \Gamma (qz;p,q)=\theta (z;p)\Gamma (z;p,q)\,}
where θ is the q-theta function .
When
p
=
0
{\displaystyle p=0}
q-Pochhammer symbol :
Γ
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z
;
0
,
q
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=
1
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z
;
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∞
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{\displaystyle \Gamma (z;0,q)={\frac {1}{(z;q)_{\infty }}}.}
Define
Γ
~
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z
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p
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:=
(
q
;
q
)
∞
(
p
;
p
)
∞
(
θ
(
q
;
p
)
)
1
−
z
∏
m
=
0
∞
∏
n
=
0
∞
1
−
p
m
+
1
q
n
+
1
−
z
1
−
p
m
q
n
+
z
.
{\displaystyle {\tilde {\Gamma }}(z;p,q):={\frac {(q;q)_{\infty }}{(p;p)_{\infty }}}(\theta (q;p))^{1-z}\prod _{m=0}^{\infty }\prod _{n=0}^{\infty }{\frac {1-p^{m+1}q^{n+1-z}}{1-p^{m}q^{n+z}}}.}
Then the following formula holds with
r
=
q
n
{\displaystyle r=q^{n}}
Felder & Varchenko (2003) harvtxt error: no target: CITEREFFelderVarchenko2003 (help ) ).
Γ
~
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n
z
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,
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Γ
~
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1
/
n
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p
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r
)
Γ
~
(
2
/
n
;
p
,
r
)
⋯
Γ
~
(
(
n
−
1
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/
n
;
p
,
r
)
=
(
θ
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r
;
p
)
θ
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q
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p
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)
n
z
−
1
Γ
~
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z
;
p
,
r
)
Γ
~
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z
+
1
/
n
;
p
,
r
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⋯
Γ
~
(
z
+
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n
−
1
)
/
n
;
p
,
r
)
.
{\displaystyle {\tilde {\Gamma }}(nz;p,q){\tilde {\Gamma }}(1/n;p,r){\tilde {\Gamma }}(2/n;p,r)\cdots {\tilde {\Gamma }}((n-1)/n;p,r)=\left({\frac {\theta (r;p)}{\theta (q;p)}}\right)^{nz-1}{\tilde {\Gamma }}(z;p,r){\tilde {\Gamma }}(z+1/n;p,r)\cdots {\tilde {\Gamma }}(z+(n-1)/n;p,r).}
References
Jackson, F. H. (1905), "The Basic Gamma-Function and the Elliptic Functions", Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character , 76 (508), The Royal Society: 127– 144, doi :10.1098/rspa.1905.0011 ISSN 0950-1207 , JSTOR 92601 Gasper, George; Rahman, Mizan (2004), Basic hypergeometric series , Encyclopedia of Mathematics and its Applications, vol. 96 (2nd ed.), Cambridge University Press , ISBN 978-0-521-83357-8 MR 2128719 Ruijsenaars, S. N. M. (1997), "First order analytic difference equations and integrable quantum systems" , Journal of Mathematical Physics 38 (2): 1069– 1146, doi :10.1063/1.531809 , ISSN 0022-2488 , MR 1434226 
