On Forward Kinematics of a 3SPR Parallel Manipulator

TL;DR

This paper introduces a computationally efficient numerical method for solving the forward kinematics of a 3SPR parallel manipulator, reducing calculations compared to traditional Jacobian-based approaches.

Contribution

A novel iterative algorithm that simplifies forward kinematics computation for 3SPR manipulators by avoiding Jacobian matrix calculations at each step.

Findings

The proposed method requires fewer computations than Jacobian-based approaches.

The algorithm effectively estimates platform orientation and heave with high accuracy.

Validation shows improved efficiency in forward kinematics calculations.

Abstract

In this paper, a new numerical method to solve the forward kinematics (FK) of a parallel manipulator with three-limb spherical-prismatic-revolute (3SPR) structure is presented. Unlike the existing numerical approaches that rely on computation of the manipulator's Jacobian matrix and its inverse at each iteration, the proposed algorithm requires much less computations to estimate the FK parameters. A cost function is introduced that measures the difference of the estimates from the actual FK values. At each iteration, the problem is decomposed into two steps. First, the estimates of the platform orientation from the heave estimates are obtained. Then, heave estimates are updated by moving in the gradient direction of the proposed cost function. To validate the performance of the proposed algorithm, it is compared against a Jacobian-based (JB) approach for a 3SPR parallel manipulator.