EllipticNomeQ
gives the nome q corresponding to the parameter m in an elliptic function.
Details
- Mathematical function, suitable for both symbolic and numerical manipulation.
- EllipticNomeQ is related to EllipticK by
![TemplateBox[{m}, EllipticNomeQ]=exp[-piTemplateBox[{{1, -, m}}, EllipticK]/TemplateBox[{m}, EllipticK]]](Files/EllipticNomeQ.en/1.png "TemplateBox[{m}, EllipticNomeQ]=exp[-piTemplateBox[{{1, -, m}}, EllipticK]/TemplateBox[{m}, EllipticK]]")
. - EllipticNomeQ[m] has a branch cut discontinuity in the complex m plane running from
to 
. - For certain special arguments, EllipticNomeQ automatically evaluates to exact values.
- EllipticNomeQ can be evaluated to arbitrary numerical precision.
- EllipticNomeQ automatically threads over lists.
Examples
open allclose allBasic Examples (6)
Plot over a subset of the reals:
Plot over a subset of the complexes:
Series expansion at the origin:
Asymptotic expansion at Infinity:
Scope (29)
Numerical Evaluation (6)
The precision of the output tracks the precision of the input:
Evaluate efficiently at high precision:
Compute worst-case guaranteed intervals using Interval and CenteredInterval objects:
Or compute average-case statistical intervals using Around:
Compute the elementwise values of an array:
Or compute the matrix EllipticNomeQ function using MatrixFunction:
Specific Values (5)
Simple arguments evaluate automatically:
Find a value of x for which EllipticNomeQ[x]=0.1:
Visualization (2)
Plot the EllipticNomeQ function for various parameters:
![TemplateBox[{z}, EllipticNomeQ]](Files/EllipticNomeQ.en/4.png "TemplateBox[{z}, EllipticNomeQ]"){kind=small}
![TemplateBox[{z}, EllipticNomeQ]](Files/EllipticNomeQ.en/5.png "TemplateBox[{z}, EllipticNomeQ]"){kind=small}
Function Properties (10)
Real and complex domains of EllipticNomeQ:
Approximate function range of EllpiticNomeQ:
EllipticNomeQ threads element-wise over lists:
EllipticNomeQ is not an analytic function:
Has both singularities and discontinuities for x≥1:
EllipticNomeQ is nondecreasing over its real domain:
EllipticNomeQ is injective:
EllipticNomeQ is not surjective:
EllipticNomeQ is neither non-negative nor non-positive:
EllipticNomeQ is convex over its real domain:
TraditionalForm formatting:
Differentiation (2)
Generalizations & Extensions (1)
EllipticNomeQ can be applied to power series:
Applications (3)
Define the Halphen constant [MathWorld]:
Find the extended precision value:
Verify that it is zero of the function 
:
Plot EllipticNomeQ over the complex plane:
Closed form of the iteration steps for calculating the arithmetic‐geometric mean:
Show convergence speed using arbitrary‐precision arithmetic:
Properties & Relations (6)
Use FullSimplify to simplify expressions containing EllipticNomeQ:
Compose with inverse functions:
Find the derivative:
Symbolically solve a transcendental equation:
Numerically find a root of a transcendental equation:
Special values of Neville theta functions involve EllipticNomeQ:
Possible Issues (1)
For most named special functions, the direct function is single‐valued and the inverse is multi‐valued. EllipticNomeQ is a multi‐valued function and the inverse function, InverseEllipticNomeQ, is single-valued. As a result, the following is correct everywhere:
Neat Examples (1)
Riemann surface of EllipticNomeQ:
Text
Wolfram Research (1996), EllipticNomeQ, Wolfram Language function, https://reference.wolfram.com/language/ref/EllipticNomeQ.html.
CMS
Wolfram Language. 1996. "EllipticNomeQ." Wolfram Language & System Documentation Center. Wolfram Research. https://reference.wolfram.com/language/ref/EllipticNomeQ.html.
APA
Wolfram Language. (1996). EllipticNomeQ. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/EllipticNomeQ.html