Paper ID: 2409.13448

Concurrent and Scalable Trajectory Optimization for Manufacturing with Redundant Robots

Yongxue Chen, Tianyu Zhang, Yuming Huang, Tao Liu, Charlie C.L. Wang

We present a concurrent and scalable trajectory optimization method for redundant robots in this paper to improve the quality of robot-assisted manufacturing. The joint angles, the tool orientations and the manufacturing time-sequences are optimized simultaneously on input trajectories with large numbers of waypoints to improve the kinematic smoothness while incorporating the manufacturing constraints. Differently, existing methods always determine them in a decoupled manner. To deal with the large number of waypoints on a toolpath, we propose a decomposition based numerical scheme to optimize the trajectory in an out-of-core manner which can also run in parallel to improve the efficiency. Simulations and physical experiments have been conducted to demonstrate the performance of our method in examples of robot-assisted additive manufacturing.

Submitted: Sep 20, 2024