Title :
A Closed-Form Approach to the Inverse Fourier Transform and Its Applications
Author_Institution :
Rambus, Inc., Los Altos, CA
Abstract :
The inverse Fourier transform of a complex-valued weighted exponential frequency-domain function is derived. A bounded causal frequency-domain transfer function can be approximated by a sum of exponential functions using numerical techniques such as the Prony´s method or the matrix pencil method, which leads to the corresponding time-domain response through an exact inverse Fourier transform. The method is demonstrated in examples with given tabulated frequency-domain data for function interpolation and extrapolation, direct generation of time-domain pulse responses, and deriving time-domain reflectometry waveform from measured S-parameters.
Keywords :
Fourier transforms; S-parameters; electromagnetic wave scattering; extrapolation; frequency-domain analysis; interpolation; matrix algebra; time-domain analysis; transfer functions; Pronys method; S-parameters; bounded causal frequency-domain transfer function; closed-form approach; complex-valued weighted exponential frequency-domain function; extrapolation; function interpolation; inverse Fourier transform; matrix pencil method; scattering parameters; sum of exponential functions; time-domain pulse responses; time-domain reflectometry waveform; Extrapolation; Fourier transforms; Frequency measurement; Interpolation; Pulse generation; Pulse measurements; Reflectometry; Scattering parameters; Time domain analysis; Transfer functions; Inverse Fourier transform; scattering parameters; sum of exponentials; transient analysis;
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
DOI :
10.1109/TEMC.2008.924396
