Title :
Study of chaotic dynamical systems via time-frequency analysis
Author_Institution :
Ilya Prigogine Center for Studies in Stat. Mech. & Complex Syst., Texas Univ., Austin, TX, USA
Abstract :
Time-frequency representation is helpful in studying the frequency pattern of nonlinear dynamical systems. Specifically, the Wigner-Gabor-Qian (WGQ) spectrogram, a synthesis of the Wigner distribution and the Gabor expansion through time-frequency distribution series, is a very useful tool because it achieves a good solution in time-frequency representation as well as few cross-interferences. The fine structure of frequency patterns, such as sub-harmonics of chaotic dynamics, can be revealed by the WGQ spectrogram. Frequency patterns of chaos and noise are studied for system identification in empirical analysis. Time-frequency analysis provides important information for pattern recognition and system identification in analyzing empirical time series
Keywords :
Wigner distribution; chaos; identification; nonlinear dynamical systems; pattern recognition; signal representation; spectral analysis; time series; time-frequency analysis; Gabor expansion; Wigner distribution; Wigner-Gabor-Qian spectrogram; chaos; chaotic dynamical systems; chaotic dynamics; cross-interferences; empirical analysis; empirical time series; frequency pattern; noise; nonlinear dynamical systems; pattern recognition; sub-harmonics; system identification; time-frequency analysis; time-frequency distribution series; time-frequency representation; Chaos; Nonlinear dynamical systems; Pattern analysis; Pattern recognition; Physics; Spectral analysis; Spectrogram; System identification; Time frequency analysis; Time series analysis;
Conference_Titel :
Time-Frequency and Time-Scale Analysis, 1994., Proceedings of the IEEE-SP International Symposium on
Conference_Location :
Philadelphia, PA
Print_ISBN :
0-7803-2127-8
DOI :
10.1109/TFSA.1994.467221
