Stochastic resonance in an asymmetric tri-stable system driven by correlated noises and periodic signal

This paper proposes an Asymmetric Tri-stable Stochastic Resonance (ATSSR) system that is driven by a periodic signal and a combination of correlated non-Gaussian noise and Gaussian white noise. The authors obtain the Markov process using the unified color noise approximation method and derive analyt...

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Veröffentlicht in:	Indian journal of physics 2023-11, Vol.97 (13), p.4017-4029
Hauptverfasser:	He, Lifang, Liu, Xiaoman, Jiang, Zhongjun
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Sprache:	eng
Schlagworte:	Approximation Astrophysics and Astroparticles Asymmetry Correlation Markov processes Mathematical analysis Original Paper Physics Physics and Astronomy Random noise Stochastic resonance White noise
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container_title	Indian journal of physics
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creator	He, Lifang Liu, Xiaoman Jiang, Zhongjun
description	This paper proposes an Asymmetric Tri-stable Stochastic Resonance (ATSSR) system that is driven by a periodic signal and a combination of correlated non-Gaussian noise and Gaussian white noise. The authors obtain the Markov process using the unified color noise approximation method and derive analytical expressions for the steady-state probability density, the Mean First-Pass Time, and the spectral amplification under the adiabatic approximation limit. Afterwards, the effects of various system parameters on them are analyzed, and the results show that both non-Gaussian noise and Gaussian white noise can induce stochastic resonance, with stronger resonance occurring when the two types of noise are correlated. Then, a periodic attenuated pulse signal and a harmonic vibration signal are constructed, which are applied in simulated experiments to detect fault signals using the ATSSR system. The experimental results demonstrate the outstanding performances in detecting fault signals and confirm its the feasibility for this purpose.
doi_str_mv	10.1007/s12648-023-02729-5
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The authors obtain the Markov process using the unified color noise approximation method and derive analytical expressions for the steady-state probability density, the Mean First-Pass Time, and the spectral amplification under the adiabatic approximation limit. Afterwards, the effects of various system parameters on them are analyzed, and the results show that both non-Gaussian noise and Gaussian white noise can induce stochastic resonance, with stronger resonance occurring when the two types of noise are correlated. Then, a periodic attenuated pulse signal and a harmonic vibration signal are constructed, which are applied in simulated experiments to detect fault signals using the ATSSR system. 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The authors obtain the Markov process using the unified color noise approximation method and derive analytical expressions for the steady-state probability density, the Mean First-Pass Time, and the spectral amplification under the adiabatic approximation limit. Afterwards, the effects of various system parameters on them are analyzed, and the results show that both non-Gaussian noise and Gaussian white noise can induce stochastic resonance, with stronger resonance occurring when the two types of noise are correlated. Then, a periodic attenuated pulse signal and a harmonic vibration signal are constructed, which are applied in simulated experiments to detect fault signals using the ATSSR system. 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The authors obtain the Markov process using the unified color noise approximation method and derive analytical expressions for the steady-state probability density, the Mean First-Pass Time, and the spectral amplification under the adiabatic approximation limit. Afterwards, the effects of various system parameters on them are analyzed, and the results show that both non-Gaussian noise and Gaussian white noise can induce stochastic resonance, with stronger resonance occurring when the two types of noise are correlated. Then, a periodic attenuated pulse signal and a harmonic vibration signal are constructed, which are applied in simulated experiments to detect fault signals using the ATSSR system. The experimental results demonstrate the outstanding performances in detecting fault signals and confirm its the feasibility for this purpose.</abstract><cop>New Delhi</cop><pub>Springer India</pub><doi>10.1007/s12648-023-02729-5</doi><tpages>13</tpages></addata></record>
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subjects	Approximation Astrophysics and Astroparticles Asymmetry Correlation Markov processes Mathematical analysis Original Paper Physics Physics and Astronomy Random noise Stochastic resonance White noise
title	Stochastic resonance in an asymmetric tri-stable system driven by correlated noises and periodic signal
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