Imagine traveling in a foreign country, reaching for a window you've never seen before, and instead of struggling to open it, ...

Bioengineers have invented a thin, flexible device that adheres to the neck and translates the muscle movements of the larynx into audible speech. The device is trained through machine learning to ...

AI and human-movement research intersect in a study that enables precise estimation of hand muscle activity from standard video recordings. Using a deep-learning framework trained on a large, ...

A new system from Yun Ho, Romain Nith, and Pedro Lopes combines AI and electrical muscle stimulation to physically guide users through unfamiliar tasks—marking a leap toward general-purpose, ...

A growing body of neuroscience research is revealing that the brain’s ability to learn and its ability to move depend on the same razor-thin timing windows, sometimes as brief as 30 milliseconds.

Learning new languages, sending emails, attending a virtual class, or speaking to loved ones halfway around the world are just some of the tasks accomplished by touching a button on a smartphone.