反向动力学
人工神经网络
运动学
反向
最大值和最小值
趋同(经济学)
计算机科学
反向传播
算法
机器人
运动学方程
控制理论(社会学)
机器人运动学
数学
人工智能
移动机器人
控制(管理)
几何学
经典力学
经济增长
物理
数学分析
经济
作者
Yonghua Bai,Minzhou Luo,Fenglin Pang
出处
期刊:Applied sciences
[Multidisciplinary Digital Publishing Institute]
日期:2021-08-02
卷期号:11 (15): 7129-7129
被引量:53
摘要
The solution of robot inverse kinematics has a direct impact on the control accuracy of the robot. Conventional inverse kinematics solution methods, such as numerical solution, algebraic solution, and geometric solution, have insufficient solution speed and solution accuracy, and the solution process is complicated. Due to the mapping ability of the neural network, the use of neural networks to solve robot inverse kinematics problems has attracted widespread attention. However, it has slow convergence speed and low accuracy. This paper proposes the FOA optimized BP neural network algorithm to solve inverse kinematics. It overcomes the shortcomings of low convergence accuracy, slow convergence speed, and easy to fall into local minima when using BP neural network to solve inverse kinematics. The experimental results show that using the trained FOA optimized BP neural network to solve the inverse kinematics, the maximum error range of the output joint angle is [−0.04686, 0.1271]. The output error of the FOA optimized BP neural network algorithm is smaller than that of the ordinary BP neural network algorithm and the PSO optimized BP neural network algorithm. Using the FOA optimized BP neural network algorithm to solve the robot kinematics can improve the control accuracy of the robot.
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