Shengli Zhao scite author profile

Shengli Zhao

5Publications

17Citation Statements Received

49Citation Statements Given

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Affiliations

Chongqing University of Technology, Beijing Wuzi University, Zhong Ke San Huan (China)

Publications

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Statistical Detection of Weak Pulse Signal under Chaotic Noise Based on Elman Neural Network

Deng

Zhu

et al. 2020

Wireless Communications and Mobile Computing

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Weak signal detection is a significant problem in modern detection such as mechanical fault diagnosis. The uniqueness of chaos and good learning ability of neural networks provide new ideas and framework for weak signal detection field. In this paper, Elman neural network is applied to detect and recover weak pulse signal in chaotic noise. For detection problem of weak pulse signal under chaotic noise, based on short-term predictability of chaotic observations, phase space reconstruction for observed signals is carried out. And Elman deep learning adaptive detection model (EDAD model) is established for weak pulse signal detection, and a hypothesis test is used to detect weak pulse signal from the prediction error. For the recovery of weak pulse signal under chaotic noise, a double-layer Elman deep neural network recovery model (DEDR model) is proposed, which is based on the Elman deep learning network model and single-point jump model for weak pulse signal, and it is optimized with goal of minimizing mean square prediction error of the Elman model. The profile least squares method is applied to estimate parameters of the DEDR model for difficult recovery of weak pulse signal because the DEDR model is essentially a semiparametric model with parametric and nonparametric parts. In the end, simulation experiments show that the model built in this paper can effectively detect and recover weak pulse signal in the background of chaotic noise.

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Distributed Sensor Local Linear Fusion Detection of Weak Pulse Signal in Chaotic Background

Zhao

et al. 2021

Journal of Sensors

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This paper combines the distributed sensor fusion system with the signal detection under chaotic noise to realize the distributed sensor fusion detection from chaotic background. First, based on the short-term predictability of the chaotic signal and its sensitivity to small interference, the phase space reconstruction of the observation signal of each sensor is carried out. Second, the distributed sensor local linear autoregressive (DS-LLAR) model is constructed to obtain the one-step prediction error of each sensor. Then, we construct a Bayesian risk model and also obtain the corresponding conditional probability density function under each sensor’s hypothesis test which firstly needs to fit the distribution of prediction errors according to the parameter estimation. Finally, the fusion optimization algorithm is designed based on the Bayesian fusion criterion, and the optimal decision rule of each sensor and the optimal fusion rule of the fusion center are jointly solved to effectively detect the weak pulse signal in the observation signal. Simulation experiments show that the proposed method which used a distributed sensor combined with a local linear model can effectively detect weak pulse signals from chaotic background.

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Detection of Weak Pulse Signal under Chaotic Noise based on Fractional Maximum Correlation Entropy Algorithm

Shi

et al. 2022

J. Phys.: Conf. Ser.

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How to improve the detection accuracy of target weak signal is always the difficulty of signal processing. In this paper, based on fractional maximum correlation entropy algorithm and combined with the local linear model, a method for detecting weak pulse signal in chaotic noise background is proposed. Firstly, for the sensitivity of chaotic signal to initial values and short-term predictability, reconstruct the phase space of the observation signal, establish a local linear model, use the fractional maximum correlation entropy algorithm for parameter estimation, and perform a single-step prediction to obtain the prediction error. Then, in order to accurately detect the submerged weak pulse signal, a threshold is given. Finally, the simulation results show that the proposed model in this paper can effectively detect the weak pulse signal under the background of chaotic noise, and it is suitable for signals of different intensities, and the detection speed and accuracy are much better than other models.

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Weak Harmonic Signal Detecting in Chaotic Noise Based on Empirical Likelihood Ratio

Zhu

Ling

et al. 2022

Wireless Pers Commun

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Research on Support Vector Machine's Prediction of Concrete Carbonization

Li¹,

He²,

Zhao³

2008

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Shengli Zhao

Statistical Detection of Weak Pulse Signal under Chaotic Noise Based on Elman Neural Network

Distributed Sensor Local Linear Fusion Detection of Weak Pulse Signal in Chaotic Background

Detection of Weak Pulse Signal under Chaotic Noise based on Fractional Maximum Correlation Entropy Algorithm

Weak Harmonic Signal Detecting in Chaotic Noise Based on Empirical Likelihood Ratio

Research on Support Vector Machine's Prediction of Concrete Carbonization

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