TAILIEUCHUNG - Báo cáo hóa học: " Prosthetic finger phalanges with lifelike skin compliance for low-force social touching interactions"

Tuyển tập báo cáo các nghiên cứu khoa học quốc tế ngành hóa học dành cho các bạn yêu hóa học tham khảo đề tài: Prosthetic finger phalanges with lifelike skin compliance for low-force social touching interactions | JNER JOURNAL OF NEUROENGINEERING AND REHABILITATION Prosthetic finger phalanges with lifelike skin compliance for low-force social touching interactions Cabibihan et al. Cabibihan et al. Journal of NeuroEngineering and Rehabilitation 2011 8 16 http content 8Zl 16 30 March 2011 BioMed Central Cabibihan et al. Journal of NeuroEngineering and Rehabilitation 2011 8 16 http content 8 1 16 Hill JOURNAL OF NEUROENGINEERING NCR AND REHABILITATION RESEARCH Open Access Prosthetic finger phalanges with lifelike skin compliance for low-force social touching interactions John-John Cabibihan Raditya Pradipta and Shuzhi Sam Ge Abstract Background Prosthetic arms and hands that can be controlled by the user s electromyography EMG signals are emerging. Eventually these advanced prosthetic devices will be expected to touch and be touched by other people. As realistic as they may look the currently available prosthetic hands have physical properties that are still far from the characteristics of human skins because they are much stiffer. In this paper different configurations of synthetic finger phalanges have been investigated for their skin compliance behaviour and have been compared with the phalanges of the human fingers and a phalanx from a commercially available prosthetic hand. Methods Handshake tests were performed to identify which areas on the human hand experience high contact forces. After these areas were determined experiments were done on selected areas using an indenting probe to obtain the force-displacement curves. Finite element simulations were used to compare the force-displacement results of the synthetic finger phalanx designs with that of the experimental results from the human and prosthetic finger phalanges. The simulation models were used to investigate the effects of a varying the internal topology of the finger phalanx and b varying different materials for the internal and external layers. Results and .

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