Temporally Consistent Object 6D Pose Estimation for Robot Control

Figure 2: Overview. Our goal is to estimate the poses of objects in time with respect to the reference frame R as shown in figure a . To achieve this, we use measurements at a time step k of the camera pose \tilde{T}^{k}_{C} and the object pose \tilde{T}^{k,A}_{CO} , where A is the label of the object. Both objects and the robot are moving in time, as illustrated by purple arrows. Our approach maintains the probabilistic world representation of the object poses as visualized in figure b , where the ellipsoids represent the poses uncertainty. This uncertainty is used to filter outliers and pred

Figure 3: Measurement covariance model. Visualization of the translation covariance model for the object pose estimations. Consider two objects (red and purple) whose projection on the image plane (dotted line) is shown in red and purple, respectively. The size of the covariance ellipsoid depends on the size of the object in the image plane. The uncertainty is higher in the direction of ray that points towards the object, mitigating the fact that the depth estimation is more difficult from monocular measurements.

Figure 4: Qualitative results on HOPE-Video. Comparison between our method and CosyPose [ 19 ] on HOPE-Video sequence (the first row). It can be seen that some of the objects are not detected by CosyPose (the second row). Our temporally smoothed predictions are shown in the last row, largely mitigating the issue of missing detections.

Figure 5: Qualitative results on SynthHOPEDynamic. Comparison between our method and CosyPose [ 19 ] on SynthHOPEDynamic sequence shown in the first row. The center of the frame is occluded by a black rectangle, and some of the frames are artificially blurred in the input video. It can be seen that some of the objects are not detected by per-frame CosyPose shown in the second row ( e.g . , frames 2 and 3) or that some outliers are detected ( e.g . , rotated cookie box in frame 5). Our temporally smoothed predictions (the last row) largely mitigate missing detections and outliers.

Figure 6: Ablation study for the constant pose motion model (left) evaluated on three scenes of the static synthetic dataset and for the constant velocity motion model (right) evaluated on three scenes of the dynamic synthetic dataset. The precision-recall trade-off is controlled by hyperparameters of our model. Recall oriented parameters are selected such that recall is maximal and precision is at least at CosyPose level. The precision oriented parameters are chosen analogously.

Figure 8: Robot tracking experiment. The illustration depicts a selected sequence of images recorded during an experiment where the robot attempts to maintains a constant relative end-effector transformation with respect to the Cheez-it box from the YCB [ 3 ] dataset. During the tracking process, the object is occluded by a sheet of paper, demonstrating the temporal consistency and stability of the refined pose estimates.