Jacobi zeta function: Difference between revisions

Latest revision as of 17:20, 19 June 2024

In mathematics, the Jacobi zeta function Z(u) is the logarithmic derivative of the Jacobi theta function Θ(u). It is also commonly denoted as $zn (u, k)$ ^[1]

Θ (u) = Θ_{4} (\frac{π u}{2 K})

Z (u) = \frac{\partial}{\partial u} \ln Θ (u)

= \frac{Θ^{'} (u)}{Θ (u)}

^[2]

Z (ϕ | m) = E (ϕ | m) - \frac{E (m)}{K (m)} F (ϕ | m)

^[3]

Where E, K, and F are generic Incomplete Elliptical Integrals of the first and second kind. Jacobi Zeta Functions being kinds of Jacobi theta functions have applications to all their relevant fields and application.

zn (u, k) = Z (u) = \int_{0}^{u} {dn}^{2} v - \frac{E}{K} d v

^[1]

This relates Jacobi's common notation of,

dn u = \sqrt{1 - m \sin θ^{2}}

,

sn u = \sin θ

,

cn u = \cos θ

.^[1] to Jacobi's Zeta function.

Some additional relations include ,

zn (u, k) = \frac{π}{2 K} \frac{{Θ_{1}}^{'} \frac{π u}{2 K}}{Θ_{1} \frac{π u}{2 K}} - \frac{cn u dn u}{sn u}

^[1]

zn (u, k) = \frac{π}{2 K} \frac{{Θ_{2}}^{'} \frac{π u}{2 K}}{Θ_{2} \frac{π u}{2 K}} - \frac{sn u dn u}{cn u}

^[1]

zn (u, k) = \frac{π}{2 K} \frac{{Θ_{3}}^{'} \frac{π u}{2 K}}{Θ_{3} \frac{π u}{2 K}} - k^{2} \frac{sn u cn u}{dn u}

^[1]

zn (u, k) = \frac{π}{2 K} \frac{{Θ_{4}}^{'} \frac{π u}{2 K}}{Θ_{4} \frac{π u}{2 K}}

^[1]

References

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↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 ^1.6 Template:Cite web
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↑ Template:Cite web

[:0-1] 1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 ^1.6 Template:Cite web

[2] Template:Cite book

[3] Template:Cite web

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Jacobi zeta function: Difference between revisions

Latest revision as of 17:20, 19 June 2024

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