Shift-Variance Analysis of Generalized Sampling Processes

This paper is concerned with quantifying shift-variance of linear systems with continuous-time input and discrete-time output. We first introduce a notion of -shift-invariance for the system. It specifies how the system should respond when the input signal is shifted. For generalized sampling proces...

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Veröffentlicht in:	IEEE transactions on signal processing 2012-06, Vol.60 (6), p.2840-2850
1. Verfasser:	Yu, Runyi
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Atmospheric measurements Detection, estimation, filtering, equalization, prediction Discrete wavelet transforms Discrete wavelet transforms (DWTs) Exact sciences and technology Fourier transforms generalized sampling Information, signal and communications theory Linear systems Particle measurements Sampling, quantization shift-invariant subspaces shift-variance measure short-time Fourier transform Signal and communications theory Signal, noise system norms Telecommunications and information theory
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description	This paper is concerned with quantifying shift-variance of linear systems with continuous-time input and discrete-time output. We first introduce a notion of -shift-invariance for the system. It specifies how the system should respond when the input signal is shifted. For generalized sampling processes, the property is characterized by the sampling kernel, and is shown to be equivalent to lack of aliasing and to shiftability. We then define a shift-variance level which describes how far the system can be possibly away from the set of systems that are -shift-invariant. The level is defined to be the maximum of the induced norms of the commutators of the system and the shift-operators (both continuous-time or discrete-time are necessarily involved). A shift-variance measure is then defined to be the ratio of the shift-variance level to the system norm, further divided by two so that the measure is between zero and unity. For generalized sampling, we obtain analytical formulas for the shift-variance level and the shift-variance measure. The results allow us to analyze the shift-variance of, among others, the discrete-time wavelet transform (DWT) and the short-time Fourier transform (STFT). We obtain a simple relation between the shift-variance levels at all scales of the DWT, and show that the shift-variance measures are identical at all scales. We calculate the shift-variance level and the shift-variance measure of some typical DWTs and the STFTs.
doi_str_mv	10.1109/TSP.2012.2190062
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The results allow us to analyze the shift-variance of, among others, the discrete-time wavelet transform (DWT) and the short-time Fourier transform (STFT). We obtain a simple relation between the shift-variance levels at all scales of the DWT, and show that the shift-variance measures are identical at all scales. 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We first introduce a notion of -shift-invariance for the system. It specifies how the system should respond when the input signal is shifted. For generalized sampling processes, the property is characterized by the sampling kernel, and is shown to be equivalent to lack of aliasing and to shiftability. We then define a shift-variance level which describes how far the system can be possibly away from the set of systems that are -shift-invariant. The level is defined to be the maximum of the induced norms of the commutators of the system and the shift-operators (both continuous-time or discrete-time are necessarily involved). A shift-variance measure is then defined to be the ratio of the shift-variance level to the system norm, further divided by two so that the measure is between zero and unity. For generalized sampling, we obtain analytical formulas for the shift-variance level and the shift-variance measure. The results allow us to analyze the shift-variance of, among others, the discrete-time wavelet transform (DWT) and the short-time Fourier transform (STFT). We obtain a simple relation between the shift-variance levels at all scales of the DWT, and show that the shift-variance measures are identical at all scales. We calculate the shift-variance level and the shift-variance measure of some typical DWTs and the STFTs.</abstract><cop>New York, NY</cop><pub>IEEE</pub><doi>10.1109/TSP.2012.2190062</doi><tpages>11</tpages></addata></record>
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subjects	Applied sciences Atmospheric measurements Detection, estimation, filtering, equalization, prediction Discrete wavelet transforms Discrete wavelet transforms (DWTs) Exact sciences and technology Fourier transforms generalized sampling Information, signal and communications theory Linear systems Particle measurements Sampling, quantization shift-invariant subspaces shift-variance measure short-time Fourier transform Signal and communications theory Signal, noise system norms Telecommunications and information theory
title	Shift-Variance Analysis of Generalized Sampling Processes
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