Bessel functions: Difference between revisions

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[[File:Besselj0j1plotT.png|400px|thumb|Explicit plots of the <math>J_0</math> and <math>J_1</math> from <ref name="toriplot">
http://tori.ils.uec.ac.jp/TORI/index.php/File:Besselj0j1plotT.png
Explicit plots of the <math>J_0</math> and <math>J_1</math>.
</ref>]]
[[File:Besselj1mapT080.png|400px|thumb|[[Complex map]] of <math>J_1</math> by
<ref name="torimapj0">
http://tori.ils.uec.ac.jp/TORI/index.php/File:Besselj1map1T080.png
Complex map of the Bessel function BesselJ1.
</ref>;
<math>u+\mathrm i v = J_1(x+\mathrm i y)</math>
]].
'''Bessel functions''' are solutions of the Bessel differential equation:<ref>{{cite book|author=Frank Bowman|title=Introduction to Bessel Functions|edition=1st Edition|publisher=Dover Publications|year=1958|id=ISBN 0-486-60462-4}}</ref><ref>{{cite book|author=George Neville Watson|title=A Treatise on the Theory of Bessel Functions|edition=2nd Edition|publisher=Cambridge University Press|year=1966|id=}}</ref><ref>[http://mathworld.wolfram.com/BesselFunctionoftheFirstKind.html Bessel Function of the First Kind] Eric W. Weisstein, From the website of "MathWorld--A Wolfram Web Resource".</ref>
:<math> z^2 \frac {d^2 w}{dz^2} + z \frac {dw}{dz} + (z^2 - \alpha^2)w = 0 </math>
where &alpha; is a constant.
Because this is a second-order differential equation, it should have two linearly-independent solutions:
(i) J<sub>&alpha;</sub>(x) and<br/>
(ii) Y<sub>&alpha;</sub>(x).
In addition, a linear combination of these solutions is also a solution:
(iii) H<sub>&alpha;</sub>(x) = C<sub>1</sub> J<sub>&alpha;</sub>(x) + C<sub>2</sub> Y<sub>&alpha;</sub>(x)
where C<sub>1</sub> and  C<sub>2</sub> are constants.
These three kinds of solutions are called Bessel functions of the first kind, second kind, and third kind.
==Properties==
Many properties of functions $J$, $Y$ and $H$ are collected at the handbook by [[Abramowitz, Stegun]]
<ref>
http://people.math.sfu.ca/~cbm/aands/page_358.htm
M. Abramowitz and I. A. Stegun.
Handbook of mathematical functions.
</ref>.
===Integral representations===
: <math> \!\!\!\!\!\!\!\!\!\! (9.1.20) ~ ~ ~ \displaystyle
J_\nu(z) = \frac{(z/2)^{\nu}}{\pi^{1/2} ~(\nu-1/2)!}
~
\int_0^\pi
~
\cos(z \cos(t)) \sin(t)^{2 \nu} ~t~ \mathrm d t
</math>
===Expansions at small argument===
: <math>\displaystyle  J_\alpha(z)
=\left(\frac{z}{2}\right)^{\!\alpha} ~
\sum_{k=0}^{\infty}
~ \frac{ (-z^2/4)^k}{ k! ~ (\alpha\!+\!k)!}
</math>
The series converges in the whole complex $z$ plane, but fails at negative integer values of <math>\alpha</math> . The postfix form of [[factorial]] is used above; <math>k!=\mathrm{Factorial}(k)</math>.
==Applications==
Bessel functions arise in many applications. For example, [[Johannes Kepler|Kepler]]’s [[Kepler's laws|Equation of Elliptical Motion]], the vibrations of a membrane, and heat conduction, to name a few.
In [[paraxial optics]] the Bessel functions are used to describe solutions with circular symmetry.
==References==
{{reflist}}[[Category:Suggestion Bot Tag]]

Latest revision as of 06:01, 18 July 2024

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Explicit plots of the and from [1]
Complex map of by [2];

.

Bessel functions are solutions of the Bessel differential equation:[3][4][5]

where α is a constant.

Because this is a second-order differential equation, it should have two linearly-independent solutions:

(i) Jα(x) and
(ii) Yα(x).

In addition, a linear combination of these solutions is also a solution:

(iii) Hα(x) = C1 Jα(x) + C2 Yα(x)

where C1 and C2 are constants.

These three kinds of solutions are called Bessel functions of the first kind, second kind, and third kind.

Properties

Many properties of functions $J$, $Y$ and $H$ are collected at the handbook by Abramowitz, Stegun [6].

Integral representations

Expansions at small argument

The series converges in the whole complex $z$ plane, but fails at negative integer values of . The postfix form of factorial is used above; .

Applications

Bessel functions arise in many applications. For example, Kepler’s Equation of Elliptical Motion, the vibrations of a membrane, and heat conduction, to name a few. In paraxial optics the Bessel functions are used to describe solutions with circular symmetry.

References

  1. http://tori.ils.uec.ac.jp/TORI/index.php/File:Besselj0j1plotT.png Explicit plots of the and .
  2. http://tori.ils.uec.ac.jp/TORI/index.php/File:Besselj1map1T080.png Complex map of the Bessel function BesselJ1.
  3. Frank Bowman (1958). Introduction to Bessel Functions, 1st Edition. Dover Publications. ISBN 0-486-60462-4. 
  4. George Neville Watson (1966). A Treatise on the Theory of Bessel Functions, 2nd Edition. Cambridge University Press. 
  5. Bessel Function of the First Kind Eric W. Weisstein, From the website of "MathWorld--A Wolfram Web Resource".
  6. http://people.math.sfu.ca/~cbm/aands/page_358.htm M. Abramowitz and I. A. Stegun. Handbook of mathematical functions.