Hypergeometric0F1
Hypergeometric0F1[a,z]
is the confluent hypergeometric function ![TemplateBox[{a, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/1.png "TemplateBox[{a, z}, Hypergeometric0F1]"){kind=small}
.
Details
- Mathematical function, suitable for both symbolic and numerical manipulation.
- The
function has the series expansion ![TemplateBox[{a, z}, Hypergeometric0F1]=sum_(k=0)^(infty)1/TemplateBox[{a, k}, Pochhammer] z^k/k!](Files/Hypergeometric0F1.en/3.png "TemplateBox[{a, z}, Hypergeometric0F1]=sum_(k=0)^(infty)1/TemplateBox[{a, k}, Pochhammer] z^k/k!")
, where ![TemplateBox[{a, k}, Pochhammer]](Files/Hypergeometric0F1.en/4.png "TemplateBox[{a, k}, Pochhammer]")
is the Pochhammer symbol. - For certain special arguments, Hypergeometric0F1 automatically evaluates to exact values.
- Hypergeometric0F1 can be evaluated to arbitrary numerical precision.
- Hypergeometric0F1 automatically threads over lists.
- Hypergeometric0F1 can be used with Interval and CenteredInterval objects. »
Examples
open allclose allBasic Examples (5)
Plot over a subset of the reals:
Plot over a subset of the complexes:
Series expansion at the origin:
Series expansion at Infinity:
Scope (38)
Numerical Evaluation (5)
The precision of the output tracks the precision of the input:
Evaluate for complex arguments and parameters:
Evaluate Hypergeometric0F1 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 Hypergeometric0F1 function using MatrixFunction:
Specific Values (4)
![TemplateBox[{{sqrt(, 2, )}, x}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/5.png "TemplateBox[{{sqrt(, 2, )}, x}, Hypergeometric0F1]"){kind=small}
Visualization (3)
Plot the Hypergeometric0F1 function for various values of parameter 
:
Plot Hypergeometric0F1 as a function of its first parameter 
:
![TemplateBox[{{sqrt(, 2, )}, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/8.png "TemplateBox[{{sqrt(, 2, )}, z}, Hypergeometric0F1]"){kind=small}
![TemplateBox[{{sqrt(, 2, )}, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/9.png "TemplateBox[{{sqrt(, 2, )}, z}, Hypergeometric0F1]"){kind=small}
Function Properties (9)
![TemplateBox[{a, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/10.png "TemplateBox[{a, z}, Hypergeometric0F1]"){kind=small}
![TemplateBox[{a, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/11.png "TemplateBox[{a, z}, Hypergeometric0F1]"){kind=small}
is an analytic function when 
:
For negative values of 
, it may or may not be analytic:
![TemplateBox[{1, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/14.png "TemplateBox[{1, z}, Hypergeometric0F1]"){kind=small}
is neither non-decreasing nor non-increasing:
![TemplateBox[{1, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/15.png "TemplateBox[{1, z}, Hypergeometric0F1]"){kind=small}
![TemplateBox[{1, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/16.png "TemplateBox[{1, z}, Hypergeometric0F1]"){kind=small}
![TemplateBox[{{1, /, 3}, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/17.png "TemplateBox[{{1, /, 3}, z}, Hypergeometric0F1]"){kind=small}
Note that the latter function grows very slowly as 
:
Hypergeometric0F1 is neither non-negative nor non-positive:
![TemplateBox[{1, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/19.png "TemplateBox[{1, z}, Hypergeometric0F1]"){kind=small}
has no singularities or discontinuities:
![TemplateBox[{{1, /, 2}, z}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/20.png "TemplateBox[{{1, /, 2}, z}, Hypergeometric0F1]"){kind=small}
is neither convex nor concave:
TraditionalForm formatting:
Differentiation (3)
derivative:Integration (3)
Series Expansions (3)
Taylor expansion for Hypergeometric0F1:
Plot the first three approximations for ![TemplateBox[{1, x}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/24.png "TemplateBox[{1, x}, Hypergeometric0F1]"){kind=small}
around 
:
General term in the series expansion of Hypergeometric0F1:
![TemplateBox[{1, x}, Hypergeometric0F1]](Files/Hypergeometric0F1.en/26.png "TemplateBox[{1, x}, Hypergeometric0F1]"){kind=small}
Function Identities and Simplifications (3)
Product of the Hypergeometric0F1 functions:
Use FunctionExpand to express Hypergeometric0F1 through other functions:
Function Representations (5)
Relation to Hypergeometric1F1 function:
Hypergeometric0F1 can be represented as a DifferentialRoot:
Hypergeometric0F1 can be represented in terms of MeijerG:
TraditionalForm formatting:
Applications (2)
Solve the 1+1-dimensional Dirac equation:
Hypergeometric0F1 has the following infinite series:
Properties & Relations (2)
Use FunctionExpand to expand in terms of Bessel functions:
Hypergeometric0F1 can be represented as a DifferenceRoot:
Text
Wolfram Research (1988), Hypergeometric0F1, Wolfram Language function, https://reference.wolfram.com/language/ref/Hypergeometric0F1.html (updated 2022).
CMS
Wolfram Language. 1988. "Hypergeometric0F1." Wolfram Language & System Documentation Center. Wolfram Research. Last Modified 2022. https://reference.wolfram.com/language/ref/Hypergeometric0F1.html.
APA
Wolfram Language. (1988). Hypergeometric0F1. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/Hypergeometric0F1.html