受自由落体猫自对准反射启发的用于姿态调整的捕获后空间基座操纵器-目标系统的非符合人体工程学轨迹规划

IF 7 2区 计算机科学 Q1 ENGINEERING, AEROSPACE IEEE Transactions on Aerospace and Electronic Systems Pub Date : 2024-09-03 DOI:10.1109/TAES.2024.3453235
Yaqiang Wei;Xiao Yang;Xinlin Bai;Zhigang Xu
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引用次数: 0

摘要

空间机器人的基础姿态决定了太阳能电池板的发电效率和与地面站的通信质量。捕获空间目标后,形成的基-机-目标系统的基姿态具有不确定性。在空间中,基-机械手-目标系统的姿态重定向是一个非完整约束问题。很少有出版物利用非完整行为来重新定位态度。提出了一种受自由落体猫自校正反射启发的姿态重定向非完整轨迹规划方法。首先,对自由落体猫的自扶正反射进行了分析。然后,利用连杆广义雅可比矩阵建立了基-机械手-目标系统的运动学模型。此外,参考自由落体猫自校正反射,将基础-机械手-目标系统分为基础部分和目标部分。推导了二者的旋转角速度与基-机-目标构型的关系,并规划了姿态重定向轨迹。导出了非完整角动量守恒约束和完整线性动量守恒约束。最后进行了数值模拟。仿真结果表明,该方法可用于空间姿态再定向的基-机-靶系统的非完整轨迹规划。
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Nonholonomic Trajectory Planning of Postcapture Space Base–Manipulator–Target System for Attitude Reorientation Inspired by Free- Falling-Cat Self-Righting Reflex
The base attitude of the space robot determines the power generation efficiency of the solar panel and the quality of communication with the ground station. After capturing the space target, the base attitude of the formed base-manipulator-target system is uncertain. In space, attitude reorientation of the base–manipulator–target system is the nonholonomic constraint problem. There are few publications that exploit the nonholonomic behavior for attitude reorientation. In the study, a nonholonomic trajectory planning method for attitude reorientation inspired by the free-falling-cat self-righting reflex is proposed. First, the free-falling-cat self-righting reflex is analyzed. Then, the kinematic model of the base–manipulator–target system is established using the link generalized Jacobian matrix. Moreover, referring to the free-falling-cat self-righting reflex, the base–manipulator–target system is divided into the base part and the target part. The relationship between the rotation angular velocity of both and the configuration of the base-manipulator-target is deduced, and the attitude reorientation trajectory is planned. The nonholonomic angular momentum conservation constraint and the holonomic linear momentum conservation constraint are derived. Finally, the numerical simulation is conducted. The simulation results show that the proposed method can be used for nonholonomic trajectory planning of the base–manipulator–target system for attitude reorientation in space.
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来源期刊
CiteScore
7.80
自引率
13.60%
发文量
433
审稿时长
8.7 months
期刊介绍: IEEE Transactions on Aerospace and Electronic Systems focuses on the organization, design, development, integration, and operation of complex systems for space, air, ocean, or ground environment. These systems include, but are not limited to, navigation, avionics, spacecraft, aerospace power, radar, sonar, telemetry, defense, transportation, automated testing, and command and control.
期刊最新文献
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