Deformation in Robotics: Applications in Tactile Sensing and Grasp Planning- [electronic resource]
Deformation in Robotics: Applications in Tactile Sensing and Grasp Planning- [electronic resource]
- 자료유형
- 학위논문파일 국외
- 최종처리일시
- 20240214100429
- ISBN
- 9798380380843
- DDC
- 629.8
- 저자명
- Huang, Isabella.
- 서명/저자
- Deformation in Robotics: Applications in Tactile Sensing and Grasp Planning - [electronic resource]
- 발행사항
- [S.l.]: : University of California, Berkeley., 2023
- 발행사항
- Ann Arbor : : ProQuest Dissertations & Theses,, 2023
- 형태사항
- 1 online resource(106 p.)
- 주기사항
- Source: Dissertations Abstracts International, Volume: 85-03, Section: B.
- 주기사항
- Advisor: Bajcsy, Ruzena.
- 학위논문주기
- Thesis (Ph.D.)--University of California, Berkeley, 2023.
- 사용제한주기
- This item must not be sold to any third party vendors.
- 초록/해제
- 요약If robots are to function in unconstrained, dynamic, and real-world environments, it is critical that are able to interact with deformable materials. Deformable materials have historically been overlooked in traditional robotics due to prevailing assumption of robot and object rigidity. These assumptions, though perfectly appropriate for constrained environments such as factory settings, are often broken in the real-world. At the same time, deformable interactions are uniquely challenging due to the infinite-dimensional, non-linear nature of the deformable materials involved. To address the challenges of introducing and implementing deformation in robotics, we present this thesis work in two parts. First, we study deformation on the robot side, where we design a soft tactile sensor and demonstrate its use in human-robot interaction and automation. Second, we also explore deformation on the object side, where in particular we focus on optimizing grasp strategies over 3D field quantities.In our first group of work, we propose and fabricate a novel soft tactile device that utilizes an embedded 3D depth-sensing camera to produce interpretable signals for geometry and force sensing. We demonstrate that this sensor is inherently safe and functional for applications including physical upper limb assistance for humans, contour following for domestic wiping tasks, as well as geometry-dependent learning from demonstration tasks for general contact-rich manipulation tasks. In the second part of the thesis, we develop grasp planners for 3D deformable objects (e.g., fruits, internal organs, containers) for applications in food processing, robotic surgery, and household automation. In particular, we optimize for field quantities that are not only inaccessible in the real world, but have also been, until recent years, computationally intractable to model. We create DefGraspSim, a finite element method-based physics simulator of arbitrary grasps on arbitrary 3D meshes over a wide range of material parameters. We also create DefGraspNets, a graph neural network-based forward dynamics model that is not only up to 1500x faster than DefGraspSim, but also enables gradient-based grasp optimization. For both methods, we demonstrate generalized performance across multiple test sets, including on real-world experiments.
- 일반주제명
- Robotics.
- 일반주제명
- Computer science.
- 일반주제명
- Electrical engineering.
- 키워드
- Grasping
- 키워드
- Soft robotics
- 키워드
- Tactile sensing
- 기타저자
- University of California, Berkeley Electrical Engineering & Computer Sciences
- 기본자료저록
- Dissertations Abstracts International. 85-03B.
- 기본자료저록
- Dissertation Abstract International
- 전자적 위치 및 접속
- 로그인 후 원문을 볼 수 있습니다.
