反向动力学
趋同(经济学)
运动学
计算机科学
还原(数学)
数学优化
人工神经网络
计算
最优化问题
一般化
迭代法
反向传播
反向
机械臂
机器人运动学
反问题
机器人学
控制理论(社会学)
逆动力学
机器人
人工智能
算法
控制工程
自由度(物理和化学)
工业机器人
适应性
加速
代表(政治)
数学
作者
Yining Zhang,Shujun Ma,D. Wang,Hu Rong-hua
摘要
ABSTRACT With the growing demand for precise and efficient control of robotic arms in the era of Industry 4.0, traditional methods for solving the inverse kinematics problem face significant limitations in terms of accuracy, computational speed, and adaptability to complex robotic configurations. This paper proposes a novel approach for solving the inverse kinematics problem by integrating the Improved Dung Beetle Optimization (IDBO) algorithm with Backpropagation Neural Networks (BPNN). This hybrid method is applied to Newton‐Raphson (NR) iterative algorithms for computing the kinematic solutions of robotic arms, effectively enhancing both optimization efficiency and solution accuracy. The IDBO algorithm, an advanced version of the traditional Dung Beetle Optimization (DBO), incorporates innovative strategies that improve convergence speed and balance local and global search capabilities, making it an effective tool for optimizing the weights and biases of the neural network. As a case study, the UR5e robotic arm is modeled using the Denavit‐Hartenberg convention. The proposed IDBO‐BPNN method is benchmarked against traditional and other optimization algorithms through simulations, demonstrating superior performance in terms of convergence speed, solution accuracy, and computational stability. Notably, the IDBO‐BPNN‐NR approach significantly reduces computation time, achieving an 80.6% reduction compared to the Random Iteration Point‐NR method and a 66.6% reduction compared to the Fixed Starting Point‐NR method. By comparing the solution parameters obtained using the IDBO‐BPNN‐NR algorithm and the Fixed Starting Point‐NR algorithm across robotic arms with varying degrees of freedom and structural configurations, the robust generalization capability of the proposed method is further validated. The results indicate that this hybrid approach is highly suitable for real‐time robotic applications, offering a scalable, efficient, and accurate solution to the inverse kinematics problem.
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