TY - GEN
T1 - 6N-DoF Pose Tracking for Tensegrity Robots
AU - Lu, Shiyang
AU - Johnson, William R.
AU - Wang, Kun
AU - Huang, Xiaonan
AU - Booth, Joran
AU - Kramer-Bottiglio, Rebecca
AU - Bekris, Kostas
N1 - Publisher Copyright:
© 2023, The Author(s), under exclusive license to Springer Nature Switzerland AG.
PY - 2023
Y1 - 2023
N2 - Tensegrity robots, which are composed of compressive elements (rods) and flexible tensile elements (e.g., cables), have a variety of advantages, including flexibility, low weight, and resistance to mechanical impact. Nevertheless, the hybrid soft-rigid nature of these robots also complicates the ability to localize and track their state. This work aims to address what has been recognized as a grand challenge in this domain, i.e., the state estimation of tensegrity robots through a marker-less, vision-based method, as well as novel, on-board sensors that can measure the length of the robot’s cables. In particular, an iterative optimization process is proposed to track the 6-DoF pose of each rigid element of a tensegrity robot from an RGB-D video as well as endcap distance measurements from the cable sensors. To ensure that the pose estimates of rigid elements are physically feasible, i.e., they are not resulting in collisions between rods or with the environment, physical constraints are introduced during the optimization. Real-world experiments are performed with a 3-bar tensegrity robot, which performs locomotion gaits. Given ground truth data from a motion capture system, the proposed method achieves less than 1 cm translation error and 3∘ rotation error, which significantly outperforms alternatives. At the same time, the approach can provide accurate pose estimation throughout the robot’s motion, while motion capture often fails due to occlusions.
AB - Tensegrity robots, which are composed of compressive elements (rods) and flexible tensile elements (e.g., cables), have a variety of advantages, including flexibility, low weight, and resistance to mechanical impact. Nevertheless, the hybrid soft-rigid nature of these robots also complicates the ability to localize and track their state. This work aims to address what has been recognized as a grand challenge in this domain, i.e., the state estimation of tensegrity robots through a marker-less, vision-based method, as well as novel, on-board sensors that can measure the length of the robot’s cables. In particular, an iterative optimization process is proposed to track the 6-DoF pose of each rigid element of a tensegrity robot from an RGB-D video as well as endcap distance measurements from the cable sensors. To ensure that the pose estimates of rigid elements are physically feasible, i.e., they are not resulting in collisions between rods or with the environment, physical constraints are introduced during the optimization. Real-world experiments are performed with a 3-bar tensegrity robot, which performs locomotion gaits. Given ground truth data from a motion capture system, the proposed method achieves less than 1 cm translation error and 3∘ rotation error, which significantly outperforms alternatives. At the same time, the approach can provide accurate pose estimation throughout the robot’s motion, while motion capture often fails due to occlusions.
KW - Robot perception
KW - Soft robotics
UR - http://www.scopus.com/inward/record.url?scp=85151058631&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85151058631&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-25555-7_10
DO - 10.1007/978-3-031-25555-7_10
M3 - Conference contribution
AN - SCOPUS:85151058631
SN - 9783031255540
T3 - Springer Proceedings in Advanced Robotics
SP - 136
EP - 152
BT - Robotics Research
A2 - Billard, Aude
A2 - Asfour, Tamim
A2 - Khatib, Oussama
PB - Springer Nature
T2 - 18th International Symposium of Robotics Research, ISRR 2022
Y2 - 25 September 2022 through 30 September 2022
ER -