Trajectory Optimization of Continuum arm robots

2019 28th IEEE International Conference on Robot and Human Interactive Communication (RO-MAN) Pub Date : 2019-10-01 DOI:10.1109/RO-MAN46459.2019.8956407

Ritesh Yadav, B. K. Rout

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引用次数: 1

Abstract

Rigid manipulators are applicable for a very structured environment and standard applications. For real world applications, continuum manipulators are used which has required high degrees of freedom, and compliance. The current work focus on the trajectory optimization of continuum robot for a specified application to minimize energy usage. To achieve this task Lagrangian mechanics is used to develop the mathematical model of the continuum robot with the payload. In this case the trajectory optimization has been carried out by treating the problem as a nested optimization problem. The outer optimization task is to optimize the trajectory using minimization of input force as primary goal where initial and final configurations of the arm are already available. Here, Genetic Algorithm is used as the optimizer for the selected tasks. The purpose of inner optimization loop is to find the feasible inverse solution for the manipulator that is required to calculate input forces which is further required to optimize the trajectory of the arm. A constrained non-linear optimization algorithm is used for the task. The optimization results show 30-80 % decrease in the input force required for the specified trajectories of the arm. The current paper shows that various tasks can be optimized using the formulated strategy to save the energy required by the arm to execute specified task.

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连续臂机器人的轨迹优化

刚性机械手适用于非常结构化的环境和标准应用。在实际应用中，使用连续体机械手，这需要高度的自由度和顺应性。目前的工作主要集中在连续体机器人的轨迹优化，以减少特定应用的能量消耗。为了实现这一任务，利用拉格朗日力学建立了带载荷连续体机器人的数学模型。在这种情况下，通过将问题视为嵌套优化问题来进行轨迹优化。外部优化任务是在机械臂初始构型和最终构型已知的情况下，以输入力最小为主要目标对轨迹进行优化。在这里，遗传算法被用作所选任务的优化器。内优化环的目的是为机械臂求出可行的逆解，计算输入力，进而优化臂的运动轨迹。采用约束非线性优化算法求解该问题。优化结果表明，在手臂的指定轨迹下，所需的输入力降低了30- 80%。本文表明，利用所制定的策略可以优化各种任务，以节省手臂执行特定任务所需的能量。

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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2019 28th IEEE International Conference on Robot and Human Interactive Communication (RO-MAN)

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