![Figure 1 from A Robot Finger Design Using a Dual-Mode Twisting Mechanism to Achieve High-Speed Motion and Large Grasping Force | Semantic Scholar Figure 1 from A Robot Finger Design Using a Dual-Mode Twisting Mechanism to Achieve High-Speed Motion and Large Grasping Force | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/8a278894f815fe26ec243eef248660b9b72c6ecc/1-Figure1-1.png)
Figure 1 from A Robot Finger Design Using a Dual-Mode Twisting Mechanism to Achieve High-Speed Motion and Large Grasping Force | Semantic Scholar
![Robotics | Free Full-Text | A Single-Actuated, Cable-Driven, and Self-Contained Robotic Hand Designed for Adaptive Grasps | HTML Robotics | Free Full-Text | A Single-Actuated, Cable-Driven, and Self-Contained Robotic Hand Designed for Adaptive Grasps | HTML](https://www.mdpi.com/robotics/robotics-10-00109/article_deploy/html/images/robotics-10-00109-g002.png)
Robotics | Free Full-Text | A Single-Actuated, Cable-Driven, and Self-Contained Robotic Hand Designed for Adaptive Grasps | HTML
![Design of a 3D-printable, robust anthropomorphic robot hand including intermetacarpal joints | SpringerLink Design of a 3D-printable, robust anthropomorphic robot hand including intermetacarpal joints | SpringerLink](https://media.springernature.com/lw685/springer-static/image/art%3A10.1007%2Fs11370-018-0267-8/MediaObjects/11370_2018_267_Fig5_HTML.png)
Design of a 3D-printable, robust anthropomorphic robot hand including intermetacarpal joints | SpringerLink
![Configuration Design of an Under-Actuated Robotic Hand Based on Maximum Grasping Space | Chinese Journal of Mechanical Engineering | Full Text Configuration Design of an Under-Actuated Robotic Hand Based on Maximum Grasping Space | Chinese Journal of Mechanical Engineering | Full Text](https://media.springernature.com/lw685/springer-static/image/art%3A10.1186%2Fs10033-018-0243-4/MediaObjects/10033_2018_243_Fig10_HTML.gif)
Configuration Design of an Under-Actuated Robotic Hand Based on Maximum Grasping Space | Chinese Journal of Mechanical Engineering | Full Text
![Figure 3 from Robot finger design for myoelectric prosthetic hand and recognition of finger motions via surface EMG | Semantic Scholar Figure 3 from Robot finger design for myoelectric prosthetic hand and recognition of finger motions via surface EMG | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/101aaa7f431295cff6494983fc86fb2e64a03c7f/2-Figure3-1.png)
Figure 3 from Robot finger design for myoelectric prosthetic hand and recognition of finger motions via surface EMG | Semantic Scholar
![Luka Mivsek on Twitter: "Lunch practice, robotic finger design with #moi3d and #octane #robotics https://t.co/9C9wf1CanW" / Twitter Luka Mivsek on Twitter: "Lunch practice, robotic finger design with #moi3d and #octane #robotics https://t.co/9C9wf1CanW" / Twitter](https://pbs.twimg.com/media/EMJqQuTWwAA9YYu.jpg)
Luka Mivsek on Twitter: "Lunch practice, robotic finger design with #moi3d and #octane #robotics https://t.co/9C9wf1CanW" / Twitter
![Figure 2 from Development of a robotic finger with an active dual-mode twisting actuation and a miniature tendon tension sensor | Semantic Scholar Figure 2 from Development of a robotic finger with an active dual-mode twisting actuation and a miniature tendon tension sensor | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/beb0ad490e55296b7b79ecb029c7b59c01a0e524/2-Figure2-1.png)