Engineers build smart robotic exoskeletons
Researchers are developing exoskeletons and prosthetic legs capable of thinking and making control decisions on their own using AI technology.
Researchers are developing exoskeletons and prosthetic legs capable of thinking and making control decisions on their own using AI technology.
更多的研究人员和公司正在进入大脑 - 计算机接口,但从用户培训到侵入性脑植入程序的现实,仍然存在重大挑战。
Researchers have created synthetic materials with morphing abilities that can be 3D printed and self-heal within seconds.
Researchers have been working to advance a technology that could one day help people with paralysis regain use of their limbs, and enable amputees to use their thoughts to control prostheses.
铜雅各布Segil博尔德生物医学工程师的工作ing to bring back that sense of touch for amputees, including veterans of the wars in Iraq and Afghanistan.
New prosthetic technologies that stimulate the nerves could pave the way for prostheses that feel like a natural part of the body and reduce the phantom limb pain commonly endured by amputees.
工程师设计了柔韧的3D印刷网状材料,其灵活性和韧性,它们可以调谐,以刺激和支持肌肉和肌腱等软组织。
Researchers have developed an intelligent system for "tuning" powered prosthetic knees, allowing patients to walk comfortably with the prosthetic device in minutes.
Electronic skins will play a significant role in monitoring, personalized medicine, prosthetics, and robotics.
对于具有高肢截肢患者的患者,佩戴者允许佩戴者思考,表现和运作,就像一个没有截肢的人一样。
Future brain-computer interface systems employ a network of independent, wireless microscale neural sensors to record and stimulate brain activity.
研究人员有3D印刷一个柔软的机器人手,足以打击任天堂的超级马里奥兄弟 - 并获胜!
Researchers have developed an artificial skin that senses force through ionic signals and also changes color from yellow to a bruise-like purple, providing a visual cue that damage has occurred.
With the aid of a virtual reality model, researchers from the Knappschaftskrankenhaus Bochum have examined, which errors can occur during the communication between the brain and robotic prosthesis.
Scientists have used an implanted sensor to record the brain signals associated with handwriting, and used those signals to create text on a computer in real time.
Mechanical engineers have developed a new high-performance artificial muscle technology that enables robots to motion more human-like.
研究人员已经证明,随着训练,动力假肢脚踝的神经控制可以恢复各种能力,包括站在非常具有挑战性的表面和蹲下。
BrainGate researchers demonstrated the first human use of a wireless transmitter capable of delivering high-bandwidth neural signals.
Researchers have constructed a 3D vision-guided artificial skin that enables tactile sensing with high performance, opening doors to innumerable applications in medicine.
Neuroscientists have demonstrated that the brain does not remap itself even with long-term bionic limb use, posing challenges for the development of realistic prosthetic limbs.
研究人员已经启用了一名四轮车,以控制一对假肢武器。
皮肤和软骨既有强度又柔韧 - 难以在人造材料中复制的性质。但是新的制造过程带来了寿命的合成聚合物较近的一步。
一种名为痕量的新型E-Skin,比传统的软材料更好地执行五倍。它适用于测量脉冲诊断的血流,帮助机器人“感受”表面的纹理。
Researchers have developed “electronic skin” sensors capable of mimicking the dynamic process of human motion.
研究人员表明,机器学习技术帮助个体瘫痪,学会使用其脑活动来控制计算机光标。
研究人员已经开发出电子人造皮肤,就像真正的皮肤一样对疼痛做出反应,为更好的假肢开辟道路,更聪明的机器人和非侵入性替代品到皮肤移植物。
研究人员开发了一种新的测量方法,以测试野外屏幕和穿着它的人是否平稳地和谐地移动。
研究人员开发了机器人的假腿,这些腿使用最初设计用于ISS的机器人臂。
Researchers take a step closer to 3D printing living tissues in patients as they develop a specially-formulated bio-ink designed for printing directly in the body.
Researchers have developed new software that can be integrated with existing hardware to enable people using robotic prosthetics to walk in a safer, more natural manner on different types of terrain.
Scientists have proposed the concept of a memristive neurohybrid chip to be used in compact biosensors and neuroprostheses.
Researchers have tapped faint, latent signals from arm nerves and amplified them to enable real-time, intuitive, finger-level control of a robotic hand.
Engineers from the Massachusetts Institute of Technology have developed a biorobotic hybrid heart for testing prosthetic valves and other cardiac devices.
First fully integrated flexible electronics made of magnetic sensors and organic circuits opens the path towards the development of electronic skin.
结合新型可穿戴电子产品和深度学习算法可以帮助残疾人与计算机无线交互。
Scientists have successfully tested neuroprosthetic technology that combines robotic control with users’ voluntary control, opening avenues in the new interdisciplinary field of shared control for neuroprosthetic technologies.
Thanks to bionic prosthesis that features sensors that connect to residual nerves in the thigh, two volunteers are the first above-knee amputees in the world to feel their prosthetic foot and knee in real time.
Researchers reported the discovery of a multifunctional ultra-thin wearable electronic device that is imperceptible to the wearer.
Reseachers are developing a prosthetic arm that can move with the person's thoughts and feel the sensation of touch via an array of electrodes implanted in the muscles of the patient.
Researchers have successfully implanted sensors in three male patients following nerve transfers, to transmit biosignals for wireless control of robotic arms.
Researchers have developed an e-skin that may soon have a sense of touch equivalent to, or better than, the human skin with the Asynchronous Coded Electronic Skin (ACES).
A new 3D printed prosthetic hand can learn the wearers' movement patterns to help amputee patients perform daily tasks.
The Open-Source Bionic Leg will enable investigators to efficiently solve challenges associated with controlling bionic legs across a range of activities in the lab and out in the community.
Wearing a sensor-packed glove while handling a variety of objects, researchers have compiled a massive dataset that enables an AI system to recognize objects through touch alone.
A female Swedish patient with hand amputation has become the first recipient of an osseo-neuromuscular implant to control a dexterous hand prosthesis.
Robots will be able to conduct a wide variety of tasks as well as humans if they can be given tactile sensing capabilities.
在EPFL开发的基于新的基于头像的软件看着人们如何走路,以预测他们的能源支出。该软件可以在医学和运动中有许多用途。
Prosthetics for arms and legs have evolved from the rudimentary wooden appendages of just a few decades ago.
Resеarchers have created аrtificial "e-whiskers" which mimic thе prоpеrties of thе reаl thing.
Electronic ‘skin’ will enable amputees to perceive through prosthetic fingertips.
A robotics company has launched the world's first medically certified 3D printed artificial arms for amputees.