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Flip Operator

We define the flip operator by

$\displaystyle \hbox{\sc Flip}_n(x) \isdef x(-n) \protect$ (7.1)

which, by modulo indexing, is also $ x(N-n)$. The $ \hbox{\sc Flip}()$ operator reverses the order of samples $ 1$ through $ N-1$ of a sequence, leaving sample 0 alone, as shown in Fig.7.1a. Thanks to modulo indexing, it can also be viewed as ``flipping'' the sequence about the vertical axis, as shown in Fig.7.1b. The interpretation of Fig.7.1b is usually the one we want, and the $ \hbox{\sc Flip}$ operator is usually thought of as ``time reversal'' when applied to a signal $ x$ or ``frequency reversal'' when applied to a spectrum $ X$.

Figure 7.1: Illustration of $ x$ and $ \hbox{\sc Flip}(x)$ for $ N=5$ for the two main domain conventions: a) $ n\in [0,N-1]$. b) $ n\in [-(N-1)/2, (N-1)/2]$.
\begin{figure}\input fig/flip.pstex_t \end{figure}

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[How to cite this work] [Order a printed hardcopy]
``Mathematics of the Discrete Fourier Transform (DFT), with Music and Audio Applications'', by Julius O. Smith III, W3K Publishing, 2003, ISBN 0-9745607-0-7.
Copyright © 2007-02-02 by Julius O. Smith III
Center for Computer Research in Music and Acoustics (CCRMA),   Stanford University
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