Sébastien Mick, Charlotte Marchand, Étienne de Montalivet, Florian Richer, Mathilde Legrand, Alexandre Peudpièce, Laurent Fabre, Christophe Huchet, Nathanaël Jarrassé
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引用次数: 0
Abstract
Background: In the last decade, notable progress in mechatronics paved the way for a new generation of arm prostheses, expanding motor capabilities thanks to their multiple active joints. Yet, the design of control schemes for these advanced devices still poses a challenge, especially with the limited availability of command signals for higher levels of arm impairment. When addressing this challenge, current commercial devices lack versatility and customizing options to be employed as test-beds for developing novel control schemes. As a consequence, researchers resort to using lab-specific experimental apparatuses on which to deploy their innovations, such as virtual reality setups or mock prosthetic devices worn by unimpaired participants.
Methods: To meet this need for a test-bed, we developed the Smart Arm platform, a human-like, multi-articulated robotic arm that can be worn as a trans-humeral arm prosthesis. The design process followed three principles: provide a reprogrammable embedded system allowing in-depth customization of control schemes, favor easy-to-buy parts rather than custom-made components, and guarantee compatibility with industrial standards in prosthetics.
Results: The Smart ArM platform includes motorized elbow and wrist joints while being compatible with commercial prosthetic hands. Its software and electronic architecture can be easily adapted to build devices with a wide variety of sensors and actuators. This platform was employed in several experiments studying arm prosthesis control and sensory feedback. We also report our participation in Cybathlon, where our pilot with forearm agenesia successfully drives the Smart Arm prosthesis to perform activities of daily living requiring both strength and dexterity.
Conclusion: These application scenarios illustrate the versatility and adaptability of the proposed platform, for research purposes as well as outside the lab. The Smart Arm platform offers a test-bed for experimenting with prosthetic control laws and command signals, suitable for running tests in lifelike settings where impaired participants wear it as a prosthetic device. In this way, we aim at bridging a critical gap in the field of upper limb prosthetics: the need for realistic, ecological test conditions to assess the actual benefit of a technological innovation for the end-users.
背景:在过去十年中,机电一体化领域取得了显著进展,为新一代假肢铺平了道路,这些假肢的多个活动关节扩大了运动能力。然而,为这些先进设备设计控制方案仍然是一项挑战,尤其是在手臂损伤程度较高的情况下,指令信号的可用性有限。在应对这一挑战时,目前的商用设备缺乏多功能性和定制选项,无法用作开发新型控制方案的试验台。因此,研究人员不得不使用实验室专用的实验装置来部署他们的创新成果,例如虚拟现实装置或由无障碍参与者佩戴的模拟假肢装置:为了满足对试验平台的需求,我们开发了智能手臂平台,这是一个仿人的多关节机器人手臂,可作为跨肱骨假肢佩戴。设计过程遵循三个原则:提供一个可重新编程的嵌入式系统,允许对控制方案进行深度定制;采用易于购买的部件而不是定制部件;保证与假肢工业标准兼容:智能 ArM 平台包括电动肘关节和腕关节,同时与商用假手兼容。它的软件和电子结构可以轻松地进行调整,以构建带有各种传感器和致动器的设备。该平台被用于多项研究假肢控制和感觉反馈的实验中。我们还报告了我们参加 Cybathlon 的情况,在这项比赛中,我们的前臂失能症试验人员成功驱动智能手臂假肢完成了需要力量和灵活性的日常生活活动:这些应用场景说明了拟议平台的多功能性和适应性,既可用于研究目的,也可用于实验室之外。智能臂平台为假肢控制法则和指令信号的实验提供了一个测试平台,适合在逼真的环境中进行测试,让受损的参与者将其作为假肢设备佩戴。通过这种方式,我们的目标是弥补上肢假肢领域的一个关键缺口:即需要真实的生态测试条件来评估技术创新对最终用户的实际益处。
期刊介绍:
Journal of NeuroEngineering and Rehabilitation considers manuscripts on all aspects of research that result from cross-fertilization of the fields of neuroscience, biomedical engineering, and physical medicine & rehabilitation.