Detection of stochastic signals in the frequency domain

The optimum detector for a random signal, the estimator-correlator, is difficult to implement. If the power spectral density (PSD) of a continuous time signal is known, a locally optimum detector is available. It maximizes the deflection ratio (DR), a measure of the detector output signal-to-noise r...

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Published in:IEEE transactions on aerospace and electronic systems 2001-07, Vol.37 (3), p.978-988
Main Authors: Chan, Y.T., Yuan, Q., So, H.C., Inkol, R.
Format: Article
Language:English
Subjects:
Aircraft components
Bandwidth
Detectors
Frequency domain analysis
Optimization
Phase detection
Phase frequency detector
Radar detection
Segments
Signal detection
Signal to noise ratio
Simulation
Sonar detection
Spectra
Statistics
Stochastic processes
Stochastic resonance
Studies
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container_end_page 988
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container_title IEEE transactions on aerospace and electronic systems
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creator Chan, Y.T.
Yuan, Q.
So, H.C.
Inkol, R.
description The optimum detector for a random signal, the estimator-correlator, is difficult to implement. If the power spectral density (PSD) of a continuous time signal is known, a locally optimum detector is available. It maximizes the deflection ratio (DR), a measure of the detector output signal-to-noise ratio (SNR). A discrete version of this detector is developed here, called the discrete-MDRD, which takes a weighted sum of the spectral components of the signal data as the detection statistic. Its derivation is applicable to nonwhite noise samples as well. A comparison of this new detector against three other common types, through their DR values and simulation results, reveals that the discrete-MDRD is near optimal at low SNRs. When the PSD of a signal is not known, a common test statistic is the peak of the PSD of the data. To reduce spectral variations, the PSD estimator first divides the data sequence into several segments and then forms the averaged PSD estimate. The segment length affects the DR values; the length that maximizes the DR is approximately the reciprocal of the signal bandwidth. Thus for unknown signal PSD, a detector that approaches the maximum DR is realizable from just the knowledge of the signal bandwidth, which is normally available. Examples and simulation results are provided to illustrate the properties and performance of the new detector.
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source IEEE Electronic Library (IEL) Journals
subjects Aircraft components
Bandwidth
Detectors
Frequency domain analysis
Optimization
Phase detection
Phase frequency detector
Radar detection
Segments
Signal detection
Signal to noise ratio
Simulation
Sonar detection
Spectra
Statistics
Stochastic processes
Stochastic resonance
Studies
title Detection of stochastic signals in the frequency domain
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