Experimental Path tracking optimization and control of a nonlinear skid steering tracked mobile robot

M. Barakat, H. Ammar, M. Elsamanty
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引用次数: 1

Abstract

The skid steering tracked robot is consider one of the famous robots that used in the autonomous agricultural field. The robot model is considered as a coupled nonlinear model. So, a real kinematic model is required to develop the robot motion which will improve the high quality and quantity of the cultivated crops. So, in this research a mathematical model for the skid steering mobile robot (SSMR) and a mathamtical model has been presented to simulate the robot. The model has been validated based on experimental data for the Skid Steering model. The robot motion as position and velocity has been measured using Inertial Measurement Unit (IMU) and fused with the External Camera measurements. These data used to train a neural network model to develop the equivalent kinematic model that replace the nonlinear model. Then, PID controller was used to perform position and speed control for the two tracks and then to the whole robot body pose. Moreover, metaheuristic techniques were used to improve the PID response by tuning gains based on Particle Swarm Optimization (PSO) and Artificial Bee Colony (ABC). The system response for the path tracking and its precision has been optimized based on the developed techniques. Moreover, the extracted results show the high performance of tracking path based on a tuned PID controller based on ABC optimization technique.
非线性滑移转向履带移动机器人实验路径跟踪优化与控制
滑移转向履带式机器人被认为是应用于自主农业领域的著名机器人之一。将机器人模型视为一个耦合的非线性模型。因此,需要一个真实的运动学模型来开发机器人运动,从而提高农作物的质量和产量。为此,本文建立了滑移转向移动机器人(SSMR)的数学模型,并对其进行了仿真。基于滑移转向模型的实验数据,对该模型进行了验证。利用惯性测量单元(IMU)测量机器人运动的位置和速度,并与外部摄像机测量相融合。利用这些数据训练神经网络模型,建立等效的运动学模型来代替非线性模型。然后利用PID控制器对两个轨迹进行位置和速度控制,进而对整个机器人的身体姿态进行控制。此外,采用基于粒子群优化(PSO)和人工蜂群(ABC)的元启发式方法,通过调整增益来改善PID响应。在此基础上,优化了系统对路径跟踪的响应和精度。此外,提取的结果表明,基于ABC优化技术的自整定PID控制器的跟踪路径具有良好的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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