Abstract.A collaborative optimization scheme of obstacle avoidance and singularity avoidance path planning method is presented for redundant robot. An improved real-time minimum distance calculated method is presented and search the connect rod which easy to collision based on this minimum distance. Complete the obstacle avoidance based on the self-motion of the redundant manipulator on a null space and two obstacle avoidance parameters related to real-time minimum distance are introduced to improve optimization of obstacle avoidance. Adopt the DLS method to solve the problem that very high joint velocities in the vicinity of singular configuration. At last, through simulation of planar 3R redundant manipulator, the algorithm proves to be feasible and effective.
This thesis proposes a path planning method of obstacle and singularity avoidance with synergistic effect for redundant robot. By analyzing robot configuration, it proposes an improved method to calculate real-time minimum distance. At first, it screens out the connecting rod which might collide. Then, it calculates the distance by coordinate variation method and took the minimum value. At last, it obtains the real-time minimum distance. By introducing two obstacle avoidance parameters related to the real-time minimum distance, this thesis uses the self-motion of redundant kinematic chain in null space to complete obstacle avoidance. Also, it applies DLS method to complete singularity avoidance optimization to the obstacle avoidance algorithm. It solves the problem of excessive joint velocity close to singularity configuration. In the end, this thesis verifies the effectiveness of the algorithm by conducting simulation experiment on a plane 3R redundant robot.
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