Integral transform
A transform of functions, having the form
 | (1) |
where 
is a finite or infinite contour in the complex plane and 
is the kernel of the integral transform (cf. Kernel of an integral operator). In most cases one considers integral transforms for which 
and 
is the real axis or a part 
of it. If 
, then the transform is said to be finite. Formulas enabling one to recover the function 
from a known 
are called inversion formulas of the integral transform.
Examples of integral transforms. The Bochner transform:
 |
where 
is the Bessel function of the first kind of order 
(cf. Bessel functions) and 
is the distance in 
. The inversion formula is: 
. The Parseval identity is:
 |
The Weber transform:
 |
where 
and 
and 
are the Bessel functions of first and second kind. The inversion formula is:
 |
For 
, the Weber transform turns into the Hankel transform:
 |
For 
this transform reduces to the Fourier sine and cosine transforms. The inversion formula is as follows: If 
, if 
is of bounded variation in a neighbourhood of a point 
and if 
, then
 |
The Parseval identity: If 
, if 
and 
are the Hankel transforms of the functions 
and 
, where 
, then
 |
Other forms of the Hankel transform are:
 |
The Weierstrass transform:
 |
it is a special case of a convolution transform.
Repeated transforms. Let
 |
where 
. Such a sequence of integral transforms is called a chain of integral transforms. For 
, repeated integral transforms are often called Fourier transforms.
Multiple (multi-dimensional) integral transforms are transforms (1) where 
and 
is some domain in the complex Euclidean 
-dimensional space.
Integral transforms of generalized functions can be constructed by the following basic methods:
1) One constructs a space of test functions 
containing the kernel 
of the integral transform 
under consideration. Then the transform 
for any generalized function 
is defined as the value of 
on the test function 
according to the formula
 |
2) A space of test functions 
is constructed on which the classical integral transform 
is defined, mapping 
onto some space of test functions 
. Then the integral transform 
of a generalized function 
is defined by the equation
 |
3) The required integral transform is expressed in terms of another integral transform that is defined for generalized functions.
See also Convolution transform; Euler transformation; Fourier transform; Gauss transform; Gegenbauer transform; Hardy transform; Hermite transform; Jacobi transform; Kontorovich–Lebedev transform; Mehler–Fock transform; Meijer transform; Mellin transform; Stieltjes transform; Watson transform; Whittaker transform.
References
| [1] | V.A. Ditkin, A.P. Prudnikov, "Operational calculus" Progress in Math. , 1 (1968) pp. 1–75 Itogi Nauk. Mat. Anal. 1966 (1967) pp. 7–82 |
| [2] | Y.A. Brychkov, A.P. Prudnikov, "Integral transforms of generalized functions" , Gordon & Breach (1989) (Translated from Russian) |
| [3] | V.S. Vladimirov, "Generalized functions in mathematical physics" , MIR (1979) (Translated from Russian) |
Comments
References
| [a1] | I.N. Sneddon, "The use of integral transforms" , McGraw-Hill (1972) |
| [a2] | H. Zemanian, "Generalized integral transformations" , Interscience (1968) |
Integral transform. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Integral_transform&oldid=47383