A Hierarchical Control Scheme for Adaptive Cruise Control System Based on Model Predictive Control

Mu, Hongyuan; Zhang, Lipeng; Mei, Mingming; Zhao, Yongtao

doi:10.3390/act12060249

Cited by 6 publications

(2 citation statements)

References 29 publications

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“…The simulation test proves that this improved neuroendocrine-PID provides better control performances in terms of the objective function, the total norm of error, and the total norm of input compared to PID and neuroendocrine-PID controllers. In [15], genetic algorithm is used to determine the composition and parameters of each meta-heuristic and the order of mixed meta-heuristics. And the hybrid heuristics for an aircraft landing problem and two-dimensional assembly optimization problem are designed automatically and evaluated by using genetic algorithm.…”

Section: Introductionmentioning

confidence: 99%

Fuzzy Neural Network PID-Based Constant Deceleration Control for Automated Mine Electric Vehicles Using EMB System

Li,

Ma,

Jiang

2024

Sensors

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It is urgent for automated electric transportation vehicles in coal mines to have the ability of self-adaptive tracking target constant deceleration to ensure stable and safe braking effects in long underground roadways. However, the current braking control system of underground electric trackless rubber-tired vehicles (UETRVs) still adopts multi-level constant braking torque control, which cannot achieve target deceleration closed-loop control. To overcome the disadvantages of lower safety and comfort, and the non-precise stopping distance, this article describes the architecture and working principle of constant deceleration braking systems with an electro-mechanical braking actuator. Then, a deceleration closed-loop control algorithm based on fuzzy neural network PID is proposed and simulated in Matlab/Simulink. Finally, an actual brake control unit (BCU) is built and tested in a real industrial field setting. The test illustrates the feasibility of this constant deceleration control algorithm, which can achieve constant decelerations within a very short time and maintain a constant value of −2.5 m/s2 within a deviation of ±0.1 m/s2, compared with the deviation of 0.11 m/s2 of fuzzy PID and the deviation of 0.13 m/s2 of classic PID. This BCU can provide electric and automated mine vehicles with active and smooth deceleration performance, which improves the level of electrification and automation for mine transport machinery.

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Section: Introductionmentioning

confidence: 99%

Fuzzy Neural Network PID-Based Constant Deceleration Control for Automated Mine Electric Vehicles Using EMB System

Li,

Ma,

Jiang

2024

Sensors

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“…Note that such a missed detection may propagate as the curve continues and cause a trajectory oscillation, and even sideslip owing to speeding. In this regard, previous studies focused on developing novel or improved algorithms from a microscopic aspect enabling V-ACC to negotiate the curve and the leading car safely, comfortably, steadily, or eco-friendly [6,[16][17][18]. However, whether such algorithms, which might be still limited in demonstrations for validation, can be applied in commercial V-ACC needs further extensive field tests.…”

Section: Introductionmentioning

confidence: 99%

Implications of As-built Highway Horizontal Curves on Vehicle Dynamic/Kinematic Characteristics Under Adaptive Cruise Control

Wang,

Lai,

Qiu

et al. 2023

Preprint

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Due to the presence of the road’s curvature and sensors’ limited field of view, as-built highway curves designed based on traditional human-driven vehicles’ characteristics pose a challenge to the adaptive cruise control (ACC) system and its shared control. However, very few efforts in the literature were expended on exploring the adaptability of the ACC system-dedicated vehicle (V-ACC) from the perspective of vehicle-road geometry interaction. Therefore, the objectives of this study are threefold: (i) to investigate the implications of existing horizontal curves on V-ACC dynamic and kinematic characteristics; (ii) to unravel the impact mechanism of curve geometric features; and (iii) to evaluate the ACC system’s adaptability from different aspects and extract the critical curve geometric features. To this end, a virtual co-simulation platform was established and validated by the OpenACC database. A series of tests featuring circular curve radius (RC), desired speed (Vde), and desired clearance were created, and V-ACC characteristics were output. The results show that: (i) a smaller RC causes V-ACC characteristics toward the margins of safety, comfort, and speed consistency, but neither sideslip nor rollover occurs, and speed consistency is good; (ii) the driver and passengers (if any) feel comfortable at Vde = 40, 80-100 km/h following the leading car, but they may feel ‘moderately uncomfortable’ at Vde = 50-70 km/h when RC decreases toward its lower limit; and (iii) asymmetrical maneuvers and discomfort would exist before and after the circular curve. These findings could help road administrators regulate V-ACC’s behaviors and improve its road-oriented operation design domain.

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Vehicle-Following Control Based on Continuous Synthesis Variable Time Headway Model

Chen,

Tao,

et al. 2024

Int. J. Fuzzy Syst.

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A Hierarchical Control Scheme for Adaptive Cruise Control System Based on Model Predictive Control

Cited by 6 publications

References 29 publications

Fuzzy Neural Network PID-Based Constant Deceleration Control for Automated Mine Electric Vehicles Using EMB System

Fuzzy Neural Network PID-Based Constant Deceleration Control for Automated Mine Electric Vehicles Using EMB System

Implications of As-built Highway Horizontal Curves on Vehicle Dynamic/Kinematic Characteristics Under Adaptive Cruise Control

Vehicle-Following Control Based on Continuous Synthesis Variable Time Headway Model

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