Shannon wavelet

In functional analysis, a Shannon wavelet may be either of real or complex type. Signal analysis by ideal bandpass filters defines a decomposition known as Shannon wavelets (or sinc wavelets). The Haar and sinc systems are Fourier duals of each other.

Real Shannon wavelet[]

Real Shannon wavelet

The Fourier transform of the Shannon mother wavelet is given by:

\Psi ^{(\operatorname {Sha} )}(w)=\prod \left({\frac {w-3\pi /2}{\pi }}\right)+\prod \left({\frac {w+3\pi /2}{\pi }}\right).

where the (normalised) gate function is defined by

\prod (x):={\begin{cases}1,&{\mbox{if }}{|x|\leq 1/2},\\0&{\mbox{if }}{\mbox{otherwise}}.\\\end{cases}}

The analytical expression of the real Shannon wavelet can be found by taking the inverse Fourier transform:

\psi ^{(\operatorname {Sha} )}(t)=\operatorname {sinc} \left({\frac {t}{2}}\right)\cdot \cos \left({\frac {3\pi t}{2}}\right)

or alternatively as

\psi ^{(\operatorname {Sha} )}(t)=2\cdot \operatorname {sinc} (2t)-\operatorname {sinc} (t),

where

\operatorname {sinc} (t):={\frac {\sin {\pi t}}{\pi t}}

is the usual sinc function that appears in Shannon sampling theorem.

This wavelet belongs to the $C^{\infty }$ -class of differentiability, but it decreases slowly at infinity and has no bounded support, since band-limited signals cannot be time-limited.

The scaling function for the Shannon MRA (or Sinc-MRA) is given by the sample function:

\phi ^{(Sha)}(t)={\frac {\sin \pi t}{\pi t}}=\operatorname {sinc} (t).

Complex Shannon wavelet[]

In the case of complex continuous wavelet, the Shannon wavelet is defined by

\psi ^{(CSha)}(t)=\operatorname {sinc} (t)\cdot e^{-2\pi it}

,

References[]

S.G. Mallat, A Wavelet Tour of Signal Processing, Academic Press, 1999, ISBN 0-12-466606-X
C.S. Burrus, R.A. Gopinath, H. Guo, Introduction to Wavelets and Wavelet Transforms: A Primer, Prentice-Hall, 1988, ISBN 0-13-489600-9.