Adjusting Distributed Cameras for Robust Moving Object Pose Estimation

Abstract

Robust moving object pose estimation is crucial in fine manipulation tasks, such as surgical instrument tracking. This paper presents a distributed-camera system with robotic adjustments to maintain consistent tracking of moving objects, thus avoiding tracking failures. An integrated framework for camera adjustment and pose estimation is developed for this distributed-camera system. In each detection cycle, the camera exhibiting the largest deviation with the object is adjusted by a visual servoing technique. After adjustment, the camera extrinsics are re-calibrated in the following detection cycles. For the unadjusted cameras, an online extrinsic optimization method based on multi-frame detection results is proposed to refine the camera extrinsics. Based on the refined camera extrinsics and detection results from multiple cameras, the pose of moving objects relative to the principal camera can be robustly estimated. We test the performance of this system in both simulation environments and real-world scenarios. The results indicate that our system achieves higher pose estimation accuracy and exhibits strong resistance to limited field-of-view (FoV) compared to conventional equivalent fixed multi-camera systems.