The main objective of this study was to develop an automated agricultural vehicle guidance system capable of controlling the vehicle during high-speed agricultural field operations. The posture sensor used in the study was a kinematic differential Global Positioning System (GPS) receiver. Experimental frequency response tests were used to develop models of steering equipment and vehicle dynamics. Classical feedback control was developed based on these models. Guidance controller effectiveness was evaluated with experimental step response tests. Frequency response tests of vehicle dynamics showed that the transfer function relating vehicle lateral deviation to steering angle was a double integrator. The dynamics of the automatic steering were within the same frequency range as desired vehicle dynamics. Guidance controller design had to compensate for both vehicle and steering equipment dynamics. When the GPS sensor was mounted above the front axle of the vehicle, guidance control to within 16 cm of the desired path was demonstrated at speeds up to 6.8 m/s. Moving the sensor rearward to a more practical location added phase lag to the system, and guidance control was less effective.
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机译:这项研究的主要目的是开发一种自动农用车辆引导系统,该系统能够在高速农业现场作业期间控制车辆。研究中使用的姿势传感器是运动学差分全球定位系统(GPS)接收器。实验频率响应测试用于开发转向设备和车辆动力学的模型。基于这些模型开发了经典的反馈控制。制导控制器的有效性通过实验阶跃响应测试进行了评估。车辆动力学的频率响应测试表明,将车辆横向偏差与转向角相关的传递函数是一个双重积分器。自动转向的动力与期望的车辆动力在相同的频率范围内。制导控制器的设计必须补偿车辆和转向设备的动力。当GPS传感器安装在车辆的前轴上方时,以高达6.8 m / s的速度将引导控制控制在所需路径的16 cm之内。将传感器向后移动到更实际的位置会增加系统的相位滞后,并且引导控制效果不佳。
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