Optimal Multi-Manipulator Arm Placement for Maximal Dexterity during Robotics Surgery
This work addresses the challenge of preoperative arm positioning in robotic surgery, offering a generalizable solution to improve dexterity and reduce collisions, though it is incremental as it builds on existing optimization techniques.
The paper tackles the problem of optimizing robot arm placements in multi-port surgical systems to minimize collisions and maximize reachability, developing a method that successfully satisfies these criteria on canonical trajectories.
Robot arm placements are oftentimes a limitation in surgical preoperative procedures, relying on trained staff to evaluate and decide on the optimal positions for the arms. Given new and different patient anatomies, it can be challenging to make an informed choice, leading to more frequently colliding arms or limited manipulator workspaces. In this paper, we develop a method to generate the optimal manipulator base positions for the multi-port da Vinci surgical system that minimizes self-collision and environment-collision, and maximizes the surgeon's reachability inside the patient. Scoring functions are defined for each criterion so that they may be optimized over. Since for multi-manipulator setups, a large number of free parameters are available to adjust the base positioning of each arm, a challenge becomes how one can expediently assess possible setups. We thus also propose methods that perform fast queries of each measure with the use of a proxy collision-checker. We then develop an optimization method to determine the optimal position using the scoring functions. We evaluate the optimality of the base positions for the robot arms on canonical trajectories, and show that the solution yielded by the optimization program can satisfy each criterion. The metrics and optimization strategy are generalizable to other surgical robotic platforms so that patient-side manipulator positioning may be optimized and solved.