Abstract
Different from traditional redundant manipulators, the redundant manipulators used in the surgical environment require the end effector (EE) to have high pose (position and orientation) accuracy to ensure the smooth progress of the operation. When analyzing the inverse kinematics (IK) of traditional redundant manipulators, gradient-projection method (GPM) and weighted least-norm (WLN) method are commonly used methods to avoid joint position limits. However, for the traditional GPM and WLN method, when joints are close to their limits, they stop moving, which greatly reduces the accuracy of the IK solution. When robotic manipulators enter a singular region, although traditional damped least-squares (DLS) algorithms are used to handle singularities effectively, motion errors of the EE will be introduced. Furthermore, selecting singular region through trial and error may cause some joint velocities exceed their corresponding limits. More importantly, traditional DLS algorithms cannot guide robotic manipulators away from singular regions. Inspired by the merits of GPM, WLN, and DLS methods, an improved weighted gradient projection method (IWGPM) is proposed to solve the IK problem of redundant manipulators used in the surgical environment with avoiding joint position limits and singularities. The weighted matrix of the WLN method and the damping factor of the DLS algorithm have been improved, and a joint limit repulsive potential field function and singular repulsive potential field function belong to the null space are introduced to completely keep joints away from the damping interval and redundant manipulators away from the unsafe region. To verify the validity of the proposed IWGPM, simulations on a 7 degree of freedom (DOF) redundant manipulator used in laparoscopic surgery indicate that the proposed method can not only achieve higher accuracy IK solution but also avoid joint position limits and singularities effectively by comparing them with the results of the traditional GPM and WLN method, respectively. Furthermore, based on the proposed IWGPM, simulation tests in two cases show that joint position limits have a great impact on the orientation accuracy, and singular potential energy function has a great impact on the position accuracy.
Highlights
Compared with six degree of freedom (DOF) robotic manipulators, 7-DOF robotic manipulators ensure motion accuracy of the end-effector (EE), and optimize other objectives due to the existence of a redundant DOF, such as avoiding obstacles and adapting to human action [1,2,3,4,5,6]
Based on gradient-projection method (GPM), a joint limit repulsive potential field function and a singular repulsive potential field function are introduced in the null space to solve the shortages of GPM, weighted least-norm (WLN), and damped least-squares (DLS) methods
Of the manipulator is set (Note: The final joint position is used to calculate the desired pose of EE, which is to clarify that the joint position is different from that obtained by the proposed improved weighted gradient projection method (IWGPM).), respectively, which determines the initial pose and desired pose expressed as Euler angles of the EE: pinitial = [39.9883, 117.4741, 175.0739]T(mm) oinitial = [0.7865,1.4431, − 0.8411]T(rad) and the desired pose is: pdesired = [71.4062, 106.7273, 191.9349]T(mm) odesired = [−0.9057,1.2209, − 0.0824] T(rad)
Summary
Compared with six degree of freedom (DOF) robotic manipulators, 7-DOF robotic manipulators ensure motion accuracy of the end-effector (EE), and optimize other objectives due to the existence of a redundant DOF, such as avoiding obstacles and adapting to human action [1,2,3,4,5,6]. The GPM and WLN methods are popular algorithms for solving IK of redundant manipulators, and have the effect of avoiding joint position limits. Hu [20] presented a gradient projection of a weighted Jacobian matrix method for IK of a planar 3-DOF manipulator This method did not solve the problem of motion accuracy reduction caused by joint positions near their limits. The existing GPM and WLN methods do not completely keep redundant manipulators away from joint position limits and singular configurations, which can reduce the motion accuracy of the EE. The vicinity of singular configurations may cause joint velocities to exceed the corresponding limits To overcome this drawback, a DLS algorithm [23,25] is a widely used approach that sacrifices accuracy of the IK solution to generate an improved.
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