Nonfragile fault‐tolerant control of suspension systems subject to input quantization and actuator fault

Jun, Xiong; Chang, Xiao‐Heng; Park, Ju H.; Li, Zhimin

doi:10.1002/rnc.5135

Cited by 65 publications

(26 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In [28], a two-stage quantization approach was derived to reduce the number of bits required to represent floating-point parameters. Dynamic quantization has been recently explored by Chang and Liu [29] and Xiong et al [30] for vehicle systems, which suggests a growing trend in the use of an adaptive approach for signal quantization. In [29], a dynamic quantizer was developed to adjust the quantization level and parameter used to reduce the steady state limit cycle in in-vehicle networked systems as static quantizers suffer from sensor failure and dropouts.…”

Section: Introductionmentioning

confidence: 99%

“…In [29], a dynamic quantizer was developed to adjust the quantization level and parameter used to reduce the steady state limit cycle in in-vehicle networked systems as static quantizers suffer from sensor failure and dropouts. In [30], the control input of nonfragile feedback control for active suspension in vehicles is quantized by a class of quantizers with adjustable dynamic parameters to provide more desirable closed-loop system performance.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Towards More Efficient DNN-Based Speech Enhancement Using Quantized Correlation Mask

2021

View full text Add to dashboard Cite

Many studies on deep learning-based speech enhancement (SE) utilizing the computational auditory scene analysis method typically employs the ideal binary mask or the ideal ratio mask to reconstruct the enhanced speech signal. However, many SE applications in real scenarios demand a desirable balance between denoising capability and computational cost. In this study, first, an improvement over the ideal ratio mask to attain more superior SE performance is proposed through introducing an efficient adaptive correlation-based factor for adjusting the ratio mask. The proposed method exploits the correlation coefficients among the noisy speech, noise and clean speech to effectively re-distribute the power ratio of the speech and noise during the ratio mask construction phase. Second, to make the supervised SE system more computationally-efficient, quantization techniques are considered to reduce the number of bits needed to represent floating numbers, leading to a more compact SE model. The proposed quantized correlation mask is utilized in conjunction with a 4-layer deep neural network (DNN-QCM) comprising dropout regulation, pre-training and noise-aware training to derive a robust and high-order mapping in enhancement, and to improve generalization capability in unseen conditions. Results show that the quantized correlation mask outperforms the conventional ratio mask representation and the other SE algorithms used for comparison. When compared to a DNN with ideal ratio mask as its learning targets, the DNN-QCM provided an improvement of approximately 6.5% in the short-time objective intelligibility score and 11.0% in the perceptual evaluation of speech quality score. The introduction of the quantization method can reduce the neural network weights to a 5-bit representation from a 32-bit, while effectively suppressing stationary and non-stationary noise. Timing analyses also show that with the techniques incorporated in the proposed DNN-QCM system to increase its compactness, the training and inference time can be reduced by 15.7% and 10.5%, respectively. INDEX TERMSCorrelation coefficients, deep neural network, dynamic noise-aware training, quantization, speech enhancement, training targets.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards More Efficient DNN-Based Speech Enhancement Using Quantized Correlation Mask

2021

View full text Add to dashboard Cite

show abstract

“…Among them, the active suspension is equipped with controllable actuators to provide or dissipate the energy from the system, so as to eliminate the vibration or impact which is transmitted to the vehicle body by the irregular road surface roughness. Since the active suspension has advantages in the tradeoff between ride quality and mechanical constraints, in recent years, research on the active vehicle suspension control design has attracted considerable attention, and many useful results have been accumulated [1][2][3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Robust fuzzy delayed sampled-data control for nonlinear active suspension systems with varying vehicle load and frequency-domain constraint

Park

Cheng

2021

Nonlinear Dyn

Self Cite

View full text Add to dashboard Cite

This article studies the Takagi-Sugeno (T-S) fuzzy delayed sampled-data $$\mathcal {H}_\infty $$ H ∞ control problem for a class of intelligent suspension systems with varying vehicle load and frequency-domain constraint. The T-S fuzzy model is utilized to characterize the varying vehicle load. Considering the transmission delay, a robust fuzzy delayed sampled-data control mechanism is newly propounded for suspension systems. According to the Lyapunov stability theory, a useful theorem is proposed based on the Wirtinger inequality to guarantee the states of the active suspension system being asymptotically stabilized with the required $$\mathcal {H}_\infty $$ H ∞ performance by the proposed controller. Moreover, the suspension constrained requirements are also satisfied within the finite frequency domain. Finally, simulation examples are presented to attest to the usefulness and superiority of the proposed controller.

show abstract

“…The fault-tolerant design approach can be mainly classified into passive and active types [21,22]. And active-passive hybrid compensation is a novel attempt to deal with compound faults.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Adaptive Fault-Tolerant Control for Compound Faults of Hypersonic Vehicle

Cheng

2021

IEEE Access

View full text Add to dashboard Cite

This study investigates the hybrid fault-tolerant control (FTC) for hypersonic flight vehicles (HFVs) under the rudder structure fault (RSF) and rudder angle deviation fault (RADF). The nonlinear equations of the model are linearised by fuzzy logic, the external nonlinear disturbance is approximated by radial basis functions, which transforms the classical HFV into a linear system. In the case of only a RSF, the state feedback system can passively shield the fault using a compensation function and design a threshold to create conditions for RADF detection. During the RSF and RADF compound faults, the system with an adaptive observer implements angle deviation fault isolation/estimation and shields the structural fault. By using the estimation results, active-passive hybrid compensation completes passive FTC of the structural fault and active FTC of the angle deviation fault. The adaptive learning rates that mimic animal predatory behaviour increase the sensitivity to incipient deviation of RADF and improve compensation. Lyapunov method proves the stability and semi-physical simulation shows the control efficiency.

show abstract

Nonfragile fault‐tolerant control of suspension systems subject to input quantization and actuator fault

Cited by 65 publications

References 50 publications

Towards More Efficient DNN-Based Speech Enhancement Using Quantized Correlation Mask

Towards More Efficient DNN-Based Speech Enhancement Using Quantized Correlation Mask

Robust fuzzy delayed sampled-data control for nonlinear active suspension systems with varying vehicle load and frequency-domain constraint

Hybrid Adaptive Fault-Tolerant Control for Compound Faults of Hypersonic Vehicle

Contact Info

Product

Resources

About