Inverse Laplace transform

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In mathematics, the inverse Laplace transform of a function is a real function that is piecewise-continuous, exponentially-restricted (that is, for some constants and ) and has the property:

where denotes the Laplace transform.

It can be proven that, if a function has the inverse Laplace transform , then is uniquely determined (considering functions which differ from each other only on a point set having Lebesgue measure zero as the same). This result was first proven by Mathias Lerch in 1903 and is known as Lerch's theorem.[1][2]

The Laplace transform and the inverse Laplace transform together have a number of properties that make them useful for analysing linear dynamical systems.

Mellin's inverse formula

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An integral formula for the inverse Laplace transform, called the Mellin's inverse formula, the Bromwich integral, or the FourierMellin integral, is given by the line integral:

 

where the integration is done along the vertical line   in the complex plane such that   is greater than the real part of all singularities of   and   is bounded on the line, for example if the contour path is in the region of convergence. If all singularities are in the left half-plane, or   is an entire function, then   can be set to zero and the above inverse integral formula becomes identical to the inverse Fourier transform.

In practice, computing the complex integral can be done by using the Cauchy residue theorem.

Post's inversion formula

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Post's inversion formula for Laplace transforms, named after Emil Post,[3] is a simple-looking but usually impractical formula for evaluating an inverse Laplace transform.

The statement of the formula is as follows: Let   be a continuous function on the interval   of exponential order, i.e.

 

for some real number  . Then for all  , the Laplace transform for   exists and is infinitely differentiable with respect to  . Furthermore, if   is the Laplace transform of  , then the inverse Laplace transform of   is given by

 

for  , where   is the  -th derivative of   with respect to  .

As can be seen from the formula, the need to evaluate derivatives of arbitrarily high orders renders this formula impractical for most purposes.

With the advent of powerful personal computers, the main efforts to use this formula have come from dealing with approximations or asymptotic analysis of the Inverse Laplace transform, using the Grunwald–Letnikov differintegral to evaluate the derivatives.

Post's inversion has attracted interest due to the improvement in computational science and the fact that it is not necessary to know where the poles of   lie, which make it possible to calculate the asymptotic behaviour for big   using inverse Mellin transforms for several arithmetical functions related to the Riemann hypothesis.

Software tools

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See also

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References

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  1. ^ Cohen, A. M. (2007). "Inversion Formulae and Practical Results". Numerical Methods for Laplace Transform Inversion. Numerical Methods and Algorithms. Vol. 5. pp. 23–44. doi:10.1007/978-0-387-68855-8_2. ISBN 978-0-387-28261-9.
  2. ^ Lerch, M. (1903). "Sur un point de la théorie des fonctions génératrices d'Abel". Acta Mathematica. 27: 339–351. doi:10.1007/BF02421315. hdl:10338.dmlcz/501554.
  3. ^ Post, Emil L. (1930). "Generalized differentiation". Transactions of the American Mathematical Society. 32 (4): 723–781. doi:10.1090/S0002-9947-1930-1501560-X. ISSN 0002-9947.
  4. ^ Abate, J.; Valkó, P. P. (2004). "Multi-precision Laplace transform inversion". International Journal for Numerical Methods in Engineering. 60 (5): 979. Bibcode:2004IJNME..60..979A. doi:10.1002/nme.995. S2CID 119889438.

Further reading

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This article incorporates material from Mellin's inverse formula on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.