通过深度测量反馈和复合滑模控制的耕作深度调节系统:实地对比验证研究

Anzhe Wang, Xin Ji, Yongyun Zhu, Qingzhuang Wang, Xinhua Wei, Shaocen Zhang
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引用次数: 0

摘要

用于量化和调节拖拉机耕作深度的现有方法存在相当大的缺陷,主要表现在精确度低以及在复杂的农业地形中干扰抑制能力差。在这项研究中,我们提出了一种复杂的反馈控制策略,旨在减轻这些挑战。我们的创新方法是通过机械角度传感器,根据拖拉机液压提升臂的对齐情况计算耕作深度。该传感器能够精确测量提升臂的角度,并将其与拉杆的耕作角度和机具的角度相匹配,从而建立一个强大的关系模型,将提升臂角度与耕作深度相关联。这种开创性的方法将基于耕作角度的深度测量得出的静态模型固有的精确性与机械确定提升臂角度带来的动态稳定性相结合。与此同时,我们还引入了基于混合扩展状态观测器的反步态滑动模式控制器(HESO-BacksteppingSMC)。混合扩展状态观测器有助于利用系统的输出反馈信号来估计未测量的状态变量和叠加干扰。我们的控制框架组件利用快速功率提升法则产生连续平滑的控制信号,有效消除了控制器固有的传统颤振现象,扩大了其功能适用性。理论评估确认了与我们提出的观测器和控制器相关的误差具有均匀且最终有界的稳定性,从而强调了它们的鲁棒性。我们提出的耕作深度测量和控制方法的卓越性能已通过一系列综合模拟和田间耕作试验得到证实,证明了其在复杂农业环境中的精确性和可靠性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tillage depth regulation system via depth measurement feedback and composite sliding mode control: A field comparison validation study
The existing methodologies employed for the quantification and regulation of tractor’s tillage depth present considerable shortcomings, primarily characterized by their low accuracy and poor disturbance rejection proficiency in complex agricultural terrains. In this study, we present a sophisticated feedback control strategy designed to mitigate these challenges. Our innovative approach hinges on calculating tillage depth from the alignment of the tractor’s hydraulic lifting arm, achieved by employing a mechanical angle sensor. This sensor adeptly gages the angle of the lifting arm, aligning it with the tillage angle of the pull rod and the implement’s angle, resulting in a robust relational model correlating the lifting arm angle with the tillage depth. This pioneering method amalgamates the accuracy inherent in the static model, derived from the tillage angle-based depth measurement, with the dynamic stability afforded by the mechanical ascertainment of the lifting arm angle. In conjunction, we introduce a Hybrid Extended State Observer-Based Backstepping Sliding Mode Controller (HESO-BacksteppingSMC). The HESO is instrumental in estimating unmeasured state variables and lumped disturbances, utilizing the system’s output feedback signal. Our control frame component capitalizes on the fast power-reaching law to yield a continuously smooth control signal, effectively eradicating the conventional chattering phenomenon inherent in controllers and amplifying its functional applicability. Theoretical evaluations affirm the uniformly and ultimately bounded stability of the errors associated with our proposed observer and controller, underscoring their robustness. The superior performance of our proposed tillage depth measurement and control methodology has been corroborated through a series of comprehensive simulation and field plowing trials, attesting to its precision and reliability in complex agricultural settings.
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