AiryBiPrime
AiryBiPrime[z]
gives the derivative of the Airy function 
.
Details
- Mathematical function, suitable for both symbolic and numerical manipulation.
- For certain special arguments, AiryBiPrime automatically evaluates to exact values.
- AiryBiPrime can be evaluated to arbitrary numerical precision.
- AiryBiPrime automatically threads over lists.
- AiryBiPrime 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)
Evaluate numerically to high precision:
The precision of the output tracks the precision of the input:
Evaluate for complex arguments:
Evaluate AiryBiPrime 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 AiryBiPrime function using MatrixFunction:
Specific Values (3)
Simple exact values are generated automatically:
Find a zero of AiryBiPrime using Solve:
Visualization (2)
![TemplateBox[{z}, AiryBiPrime]](Files/AiryBiPrime.en/2.png "TemplateBox[{z}, AiryBiPrime]"){kind=small}
![TemplateBox[{z}, AiryBiPrime]](Files/AiryBiPrime.en/3.png "TemplateBox[{z}, AiryBiPrime]"){kind=small}
Function Properties (9)
AiryBiPrime is defined for all real and complex values:
Function range of AiryBiPrime:
AiryBiPrime is an analytic function of x:
AiryBiPrime is neither non-increasing nor non-decreasing:
AiryBiPrime is not injective:
AiryBiPrime is surjective:
AiryBiPrime is neither non-negative nor non-positive:
AiryBiPrime has no singularities or discontinuities:
AiryBiPrime is neither convex nor concave:
derivative:Integration (3)
Indefinite integral of AiryBiPrime gives back AiryBi:
Definite integral of AiryBiPrime:
Series Expansions (4)
Taylor expansion for AiryBiPrime:
Plot the first three approximations for AiryBiPrime around 
:
General term in the series expansion of AiryBiPrime:
Find the series expansion at infinity:
The behavior at negative infinity is quite different:
AiryBiPrime can be applied to power series:
Integral Transforms (2)
Function Identities and Simplifications (3)
Simplify the expression to AiryBiPrime:
FunctionExpand tries to simplify the argument of AiryBiPrime:
Function Representations (4)
Relationship to Bessel functions:
AiryBiPrime can be represented as a DifferentialRoot:
Represent in terms of MeijerG using MeijerGReduce:
TraditionalForm formatting:
Applications (3)
Solve differential equations in terms of AiryBiPrime:
Solution of the modified linearized Korteweg–deVries equation for any function 
:
Solution of the time‐independent Schrödinger equation in a linear cone potential, represented with AiryAiPrime and AiryBiPrime:
The normalizable states are determined through the zeros of AiryAiPrime:
Properties & Relations (5)
Use FullSimplify to simplify Airy functions, here in the Wronskian of the Airy equation:
Compare with the output of Wronskian:
Generate Airy functions from differential equations:
Obtain AiryBiPrime from sums:
AiryBiPrime appears in special cases of several mathematical functions:
Possible Issues (3)
Machine-precision input is insufficient to give a correct answer:
Use arbitrary-precision evaluation instead:
A larger setting for $MaxExtraPrecision can be needed:
Neat Examples (1)
Nested integrals of the square of AiryBiPrime:
Text
Wolfram Research (1991), AiryBiPrime, Wolfram Language function, https://reference.wolfram.com/language/ref/AiryBiPrime.html (updated 2022).
CMS
Wolfram Language. 1991. "AiryBiPrime." Wolfram Language & System Documentation Center. Wolfram Research. Last Modified 2022. https://reference.wolfram.com/language/ref/AiryBiPrime.html.
APA
Wolfram Language. (1991). AiryBiPrime. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/AiryBiPrime.html