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| Model predictive control parameter optimization in autonomous driving considering both subjective and objective factors |
Tiangen CHANG1( ),Guofu TIAN1,*( ),Yuanyuan TANG2,Mingxue CAO1 |
1. School of Mechanical Engineering, Shenyang University of Technology, Shenyang 110870, China 2. Engineering Training Center, Shenyang University of Technology, Shenyang 110870, China |
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Abstract A novel parameter optimization method for model predictive control was proposed to address the problems of insufficient tracking accuracy and poor real-time performance of model predictive controllers in trajectory tracking of autonomous vehicles. An improved non-dominated sorting whale optimization algorithm (NSWOA) based on the improved Sinusoidal mapping and a Lévy flight strategy was proposed to solve the problem of relatively concentrated and out-of-bound optimal solutions obtained by the NSWOA. The parameter optimization problem of model predictive controllers was formulated as a multi-objective optimization problem. The predictive horizon, control horizon, and sampling time were used as optimization variables. The sum of squared lateral trajectory errors and total computation time were used as optimization objectives. The improved NSWOA was employed to solve the multi-objective optimization problem and obtain the Pareto optimal solution set. The optimal controller parameter combination was determined by using the expert scoring method, the continuous ordered weighted averaging operator method, the game theory-based combined weighting method, and the technique for order preference by similarity to an ideal solution. The tracking accuracy of the proposed method was improved by an average of 56.27%, and the computation time was reduced by an average of 21.54%. This method provides a new idea that balances high tracking accuracy and high real-time performance for the tuning strategy of model predictive control parameters.
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Received: 30 June 2025
Published: 16 July 2026
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| Fund: 国家自然科学基金资助项目(52375258). |
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Corresponding Authors:
Guofu TIAN
E-mail: 1473505308@qq.com;tianguofu@126.com
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考虑主客观因素的自动驾驶模型预测控制参数优化
针对自动驾驶汽车轨迹跟踪过程中模型预测控制器跟踪精度不足和实时性差的问题,提出考虑主客观因素的模型预测控制参数优化方法. 针对非支配排序鲸鱼优化算法(NSWOA)得到的最优解相对集中和超出边界的问题,提出基于改进Sinusoidal映射和莱维飞行策略的改进NSWOA. 将模型预测控制器的参数优化问题转化为多目标优化问题,以预测时域、控制时域和采样时间作为优化变量,以横向轨迹误差平方和与总计算时间作为优化目标,利用改进NSWOA求解多目标优化问题,获得Pareto最优解集. 采用专家打分法、连续有序加权平均算子法、博弈论组合赋权法和逼近理想解排序法,确定最佳的控制器参数组合. 所提方法的跟踪精度平均提高了56.27%,计算时间平均减少了21.54%,为模型预测控制参数的整定策略提供了兼顾高跟踪精度和高实时性的新思路.
关键词:
自动驾驶,
模型预测控制,
鲸鱼优化算法,
连续有序加权平均算子,
博弈论组合赋权
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