Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone
This paper focuses on the problem of neuroadaptive quantized control for heterogeneous vehicular platoon when the follower vehicles suffer from external disturbances, mismatch input quantization, and unknown actuator deadzone. The PID-based sliding-mode (PIDSM) control technique is used due to its s...
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sg-ntu-dr.10356-1500402021-06-04T03:28:38Z Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone Guo, Xianggui Wang, Jianliang Liao, Fang Teo, Rodney Swee Huat Teo School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Constant Time Headway Policy Neuroadaptive Control This paper focuses on the problem of neuroadaptive quantized control for heterogeneous vehicular platoon when the follower vehicles suffer from external disturbances, mismatch input quantization, and unknown actuator deadzone. The PID-based sliding-mode (PIDSM) control technique is used due to its superior capability to reduce spacing errors and to eliminate the steady-state spacing errors. Then, a neuroadaptive quantized PIDSM control scheme with minimal learning parameters is designed not only to guarantee the string stability of the whole vehicular platoon and ultimate uniform boundedness of all adaptive law signals but also to attenuate the negative effects caused by external disturbance, mismatch input quantization, and unknown actuator deadzone. Furthermore, optimizing the interspacing between consecutive vehicles is very important to reduce traffic congestion on highways, and a new modified constant time headway policy is proposed to not only increase traffic density but also address the negative effect of nonzero initial spacing, velocity, and acceleration errors. Compared with most existing methods, the proposed method does not linearize the system model and neither requires precise knowledge of the system model. Finally, the effectiveness and advantage of the proposed method are demonstrated by comparative simulation studies. 2021-06-04T03:28:38Z 2021-06-04T03:28:38Z 2019 Journal Article Guo, X., Wang, J., Liao, F. & Teo, R. S. H. T. (2019). Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone. International Journal of Robust and Nonlinear Control, 29(1), 188-208. https://dx.doi.org/10.1002/rnc.4394 1049-8923 0000-0002-7265-4391 https://hdl.handle.net/10356/150040 10.1002/rnc.4394 2-s2.0-85056390761 1 29 188 208 en International Journal of Robust and Nonlinear Control © 2018 John Wiley & Sons, Ltd. All rights reserved. |
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Engineering::Electrical and electronic engineering Constant Time Headway Policy Neuroadaptive Control |
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Engineering::Electrical and electronic engineering Constant Time Headway Policy Neuroadaptive Control Guo, Xianggui Wang, Jianliang Liao, Fang Teo, Rodney Swee Huat Teo Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| description |
This paper focuses on the problem of neuroadaptive quantized control for heterogeneous vehicular platoon when the follower vehicles suffer from external disturbances, mismatch input quantization, and unknown actuator deadzone. The PID-based sliding-mode (PIDSM) control technique is used due to its superior capability to reduce spacing errors and to eliminate the steady-state spacing errors. Then, a neuroadaptive quantized PIDSM control scheme with minimal learning parameters is designed not only to guarantee the string stability of the whole vehicular platoon and ultimate uniform boundedness of all adaptive law signals but also to attenuate the negative effects caused by external disturbance, mismatch input quantization, and unknown actuator deadzone. Furthermore, optimizing the interspacing between consecutive vehicles is very important to reduce traffic congestion on highways, and a new modified constant time headway policy is proposed to not only increase traffic density but also address the negative effect of nonzero initial spacing, velocity, and acceleration errors. Compared with most existing methods, the proposed method does not linearize the system model and neither requires precise knowledge of the system model. Finally, the effectiveness and advantage of the proposed method are demonstrated by comparative simulation studies. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Guo, Xianggui Wang, Jianliang Liao, Fang Teo, Rodney Swee Huat Teo |
| format |
Article |
| author |
Guo, Xianggui Wang, Jianliang Liao, Fang Teo, Rodney Swee Huat Teo |
| author_sort |
Guo, Xianggui |
| title |
Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| title_short |
Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| title_full |
Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| title_fullStr |
Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| title_full_unstemmed |
Neuroadaptive quantized PID sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| title_sort |
neuroadaptive quantized pid sliding-mode control for heterogeneous vehicular platoon with unknown actuator deadzone |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/150040 |
| _version_ |
1702431263847088128 |