SF2104拖拉机自主行驶与作业控制方法
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国家重点研发计划项目(2016YFB0501805)


Autonomous driving and operation control method for SF2104 tractors
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    摘要:

    针对农业机械无人化作业的应用需求,该研究基于SF2104动力换向线控底盘拖拉机和全球卫星导航系统(Global Navigation Satellite System,GNSS),研发了拖拉机自主行驶与作业控制系统。该系统针对田内直线作业与地头转弯,采用分层控制思想,将控制系统划分为规划层、控制层和执行层。规划层生成U形转弯所需的路网数据,控制层进行拖拉机横向控制、速度控制、转弯控制、机具升降控制、当前路径更新及终止作业等行为决策;执行层负责以上行为的配置执行。拖拉机挂载深松机进行深松作业,并与有人驾驶深松作业进行对照。结果表明,拖拉机自主行驶与作业控制系统横向偏差的平均标准差为4 cm,平均作业速度及其平均标准差分别为1.66和0.09 m/s,稳定作业时发动机转速的平均标准差为7.9 r/min,平均机具位置的极差为23.8,均优于有人驾驶。该研究初步实现了拖拉机的自主行驶与作业,有助于解决农村劳动力紧缺问题。

    Abstract:

    Abstract: To solve the critical shortage and the increasing cost of rural labor, the concept of "one person, multiple machines" were proposed and an autonomous driving and operating system for SF2104 was developed. The hardware of the system included SF2104 tractor with a power reverser transmission and wire-controlled chassis, WAS-3106 angle sensor, 1SZ-230 subsoiler, GNSS (Global Navigation Satellite System) based auto-steering system for agricultural machinery (FARMSTARF2BD-2.5RD), SF9507 vehicle controller, and mobile monitor such as smartphone and PC (personal computer). The control system mainly included three function units, i.e., data acquisition unit, planning and control unit, and movement unit. The navigation and control method was deployed in the planning and control unit according to the hierarchical control method. The entire method constituted of the layer of navigation planning, the layer of behavior control, and the layer of behavior execution. The operation width, the turning radius and the first operation path (AB straight line) from user inputs were transferred to the layer of navigation planning, and it also used to calculate the path network data. The path network data, wheelbase from user inputs and the real-time data (i.e.,location, heading and front wheel angle), were transferred to the layer of behavior control involving the target behavior decision. The decision of the target behavior wouldl be transferred to the layer of behavior execution, which derived the target front wheel angle, the target engine rotation speed and the target implement position. The layer of navigation planning generated the path network data to meet the requirement of operating in the field and turning in the headland through the FSP (First Turn Skip Pattern). The layer of behavior control made the decisions of target behavior, including lateral control, speed control, turning control, lifting control, current path update and operation ending. When the tractor entered the operating strip, the system identified the starting point of the operation, and sequentially executed the behavior of implement lowering, the behavior of speed increase, and the behavior of tracking the AB straight line. When the tractor finished the operation of the current path, the behaviors of implement lifting, speed reduction, and turning were executed sequentially. The behavior of speed control was executed by controlling the tractor's engine rotation speed at a high value or a low value through the vehicle controller. The behavior of lifting control was executed by transmitting an implement status value to the controller of the hydraulic lifting system. The behavior of turning control was executed by transmitting a fixed front wheel angle which was calculated by tractor kinematics turning distance. The subsoil operation experiments were carried out in the Shunyi District of Beijing. The experiments included the manual driving group and the autonomous driving group. For the autonomous driving group, the operating trajectories were straight and smooth, the average standard deviation of lateral deviation was 4 cm, the average operating speed was 1.66 m/s, and the standard deviation of operating speed was 0.09 m/s. During the stable operating stage in the field, the standard deviation of engine rotation speed was 7.9 r/min, and the range of the average implement position was 23.8. For the manual driving group, the operating trajectories were not smoother than the trajectories of the autonomous driving group, and the average standard deviation of lateral deviation was 8 cm, the average operating speed was 2.98 m/s, and the standard deviation of operating speed was 0.27 m/s. The stability of engine rotation speed and the range of implement position were also poor in manual driving group. The results showed that the autonomous driving group outperformed the manual driving group in terms of operating accuracy and working stability, which can effectively reduce labor costs. This research provides a platform foundation and theoretical basis for the future research of multi-vehicle and multi-operation collaboration with less human operations.

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吴才聪,王东旭,陈智博,宋兵兵,杨丽丽,杨卫中. SF2104拖拉机自主行驶与作业控制方法[J].农业工程学报,2020,36(18):42-48. DOI:10.11975/j. issn.1002-6819.2020.18.006

Wu Caicong, Wang Dongxu, Chen Zhibo, Song Bingbing, Yang Lili, Yang Weizhong. Autonomous driving and operation control method for SF2104 tractors[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE),2020,36(18):42-48. DOI:10.11975/j. issn.1002-6819.2020.18.006

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  • 收稿日期:2020-06-03
  • 最后修改日期:2020-08-01
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  • 在线发布日期: 2020-10-09
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