Hybrid fault tolerant control for air–fuel ratio control of internal combustion gasoline engine using Kalman filters with advanced redundancy

Amin, Arslan Ahmed; Mahmood-ul-Hasan, Khalid

doi:10.1177/0020294019842593

Cited by 41 publications

(41 citation statements)

References 52 publications

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“…The presented work can achieve the exact position of the faulty sensor in less time. The studies 14,15 show the dual hardware redundancy for engine sensors application in which the primary component performs all the normal operations until it fails and then back-up components come into operation to perform the tasks. With this approach, a single point of failure can be eliminated due to a single sensor or actuator and the overall failure of the system can be avoided that would have been caused by a single component.…”

Section: Literature Reviewmentioning

confidence: 99%

Reliable speed control of a permanent magnet DC motor using fault-tolerant H-bridge

Ahmed

Amin

Wajid

et al. 2014

Advances in Mechanical Engineering

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Reliable, smooth, and fault free speed control of a Permanent Magnet (PM) DC motor using an H-bridge is an important need for many industrial applications such as robotics, automotive, and process industry to improve the overall efficiency and productivity. The reliability of H-bridge depends on the semiconductor switches used. The faults in these components can lead to a complete failure of the system. This paper presents a dual redundancy-based fault-tolerant system with a Fault Detection and Isolation (FDI) unit that can detect, isolate, and replace the faulty switch with the standby to prevent the unwanted shut down of the system and support the process continuity thereby increasing reliability. MATLAB/Simulink environment was used for simulation experiments and the results demonstrate the stable operation of the motor in the events of faults while maintaining its speed. The presented work establishes that the dual redundancy-based fault-tolerant H-bridge with the FDI unit is a highly reliable solution for the speed control of a DC motor.

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Section: Literature Reviewmentioning

confidence: 99%

Reliable speed control of a permanent magnet DC motor using fault-tolerant H-bridge

Ahmed

Amin

Wajid

et al. 2014

Advances in Mechanical Engineering

Self Cite

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“…In the passive approach, the same controller is used throughout the normal and fault cases; therefore, this passive fault-tolerant controller can be implemented [24,25]. Passive FTC is suitable for systems with simple fault expressions and small amplitudes, thereby simplifying the HFV control algorithm and improving the response speed [26,27]. In the active approach, the observer is first designed to estimate faults, and then systems use estimated values to reconstruct the control algorithms for tracking the ideal output [28].…”

Section: Introductionmentioning

confidence: 99%

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

Cheng

2021

IEEE Access

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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.

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“…Redundancy is mainly divided into hardware redundancy and analytical redundancy [9]. In hardware redundancy, multiple backup sensors or actuators are used to perform the same task thereby preventing the failure of the system [10], such as dual redundancy [11], triple modular redundancy [12], and modified triple redundancy [13]. Owing to increasing the cost, weight, and physical size, hardware redundancy is often not an option for turbofan engines.…”

Section: Introductionmentioning

confidence: 99%

“…Owing to increasing the cost, weight, and physical size, hardware redundancy is often not an option for turbofan engines. In analytical redundancy, filters [12], adaptive observers [14], linear regression-based VOLUME 4, 2016 observers [15] are designed to estimate the operation of components, which are mainly used in the case of sensor faults. To estimate actuator faults, many other fault diagnosis approaches have been proposed for turbofan engines, such as Kalman filter [16]- [21], observer [22], [23], and other related methods [24]- [29].…”

Section: Introductionmentioning

confidence: 99%

CNN-Based Intelligent Fault-Tolerant Control Design for Turbofan Engines With Actuator Faults

Cheng

Liu

2021

IEEE Access

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In this paper, the problem of fault-tolerant control is investigated for turbofan engines with actuator faults. The controller involvement has repressed the effects of actuator faults on the controlled outputs of turbofan engines, making fault-tolerant control difficult. To solve this problem, the internal gaspath data of turbofan engines is introduced to provide conducive fault information. Besides, the useful property of the convolution neural network (CNN) is explored and utilized in fault-tolerant control. Based on the analysis of actuator faults, by using the Lyapunov stability and L 2-gain like theorems, a novel CNN-based intelligent fault-tolerant control system for turbofan engines is proposed, including a CNNbased fault diagnosis module and a nonlinear fault-tolerant controller with corresponding reconfiguration unit. The CNN-based intelligent fault-tolerant control system has the advantages of reducing the accuracy requirements of the mathematical description of turbofan engines. Furthermore, the proposed system can diagnose actuator faults and reduce the adverse effects of actuator faults on turbofan engines. Finally, simulation results are presented to demonstrate the efficiency of the designed method. INDEX TERMS CNN-based intelligent fault-tolerant control, actuator faults, gas-path data, fault diagnosis, nonlinear fault-tolerant controller, turbofan engines.

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Hybrid fault tolerant control for air–fuel ratio control of internal combustion gasoline engine using Kalman filters with advanced redundancy

Cited by 41 publications

References 52 publications

Reliable speed control of a permanent magnet DC motor using fault-tolerant H-bridge

Reliable speed control of a permanent magnet DC motor using fault-tolerant H-bridge

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

CNN-Based Intelligent Fault-Tolerant Control Design for Turbofan Engines With Actuator Faults

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