FUZZY FRACTIONAL ORDER SLIDING MODE CONTROL FOR OPTIMAL ENERGY CONSUMPTION-TRANSIENT RESPONSE TRADE-OFF IN ROBOTIC SYSTEMS

Fractals Pub Date : 2024-07-16 DOI:10.1142/s0218348x24500944
Fatma Abdelhédi, Rim Jallouli Khlif, Ahmed Said Nouri, Nabil Derbel
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Abstract

This work presents a new fuzzy logic parameter tuning-based fractional order sliding mode control (F-FOSMC) strategy for the trajectory tracking of robotic systems. The primary objective is to achieve an optimal control compromise seeking to minimize energy consumption for required motions, all while increasing both accuracy and rapidity of the transient response, addressing therefore a critical challenge in the field of robotics. Our approach integrates a sophisticated fuzzy logic fractional order mechanism to dynamically fine-tune the noninteger derivation parameter of the FOSMC, offering adaptability to varying operational conditions. This intelligent fuzzy logic controller tuning optimizes the FOSMC performance, demonstrates a remarkable capacity to handle uncertainties and disturbances intrinsic to robotic applications and allows to optimize the trade-off between the energy consumption and transient response efficiency throughout the robot’s motion. The effectiveness of the proposed study is thoroughly examined via simulations conducted on a 3 DOF manipulator robotic system. Results showcase that F-FOSMC significantly reduces control energy consumption while preserving rapid and efficient transient response characteristics.
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在机器人系统中实现能耗-瞬态响应权衡最优的模糊分数阶滑动模式控制
本研究针对机器人系统的轨迹跟踪,提出了一种基于模糊逻辑参数调整的分数阶滑模控制(F-FOSMC)新策略。其主要目标是实现最优控制折衷,力求将所需运动的能耗降至最低,同时提高瞬态响应的准确性和快速性,从而解决机器人领域的关键挑战。我们的方法集成了复杂的模糊逻辑分数阶机制,可动态微调 FOSMC 的非整数推导参数,提供对不同运行条件的适应性。这种智能模糊逻辑控制器调整优化了 FOSMC 的性能,展示了处理机器人应用中固有的不确定性和干扰的卓越能力,并允许在整个机器人运动过程中优化能耗和瞬态响应效率之间的权衡。通过在 3 DOF 机械手机器人系统上进行仿真,对所提研究的有效性进行了全面检验。结果表明,F-FOSMC 能显著降低控制能耗,同时保持快速高效的瞬态响应特性。
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