CSAIL researchers have developed a system that allows robots to correct their mistakes based on input from the brainwaves of human operators, reports Wired’s Matt Simon. “It’s a new way of controlling the robot,” explains Prof. Daniela Rus, “in the sense that we aim to have the robot adapt to what the human would like to do.”
Anthony Cuthbertson of Newsweek writes that CSAIL researchers have developed a system that allows robots to change their actions based on feedback from the brain waves of a human operator. “Imagine robots or smartphones that could immediately correct themselves when you realize they’re making a mistake,” says PhD candidate Joseph DelPreto.
CSAIL researchers have developed a system that allows robots to detect brain signals generated by human operators, writes Oscar Williams of Huffington Post. The researchers hope the new system could “pave the way for more seamless interactions between robots and humans.”
A feedback system developed by CSAIL researchers allows humans to correct a robot’s mistakes using brain signals, writes Janet Burns for Forbes. The system could be used as a “communication method for those who can't use verbal means, such as immobilized or even 'locked in' victims of paralysis,” explains Burns.
MIT researchers have developed a device that allows humans to guide robots using brainwaves, reports Clive Cookson for the Financial Times. The prototype brain-computer interface “enables a human observer to transmit an immediate error message to a robot, telling it to fix a mistake when it does something wrong.”
New Scientist reporter Matt Reynolds writes that MIT researchers have developed a new brain-computer interface that enables people to correct robots’ mistakes using brain signals. “We’re taking baby steps towards having machines learn about us, and having them adjust to what we think,” explains Prof. Daniela Rus, director of CSAIL.
Boston Globe reporter Andy Rosen writes about a new MIT study examining how the brain perceives rhythm that finds people tend to reorganize random series of beats into familiar patterns. “We think that these biases on rhythm, they probably are really important to how you hear music,” explains Prof. Josh McDermott.
MIT researchers have found similarities in how the brains of babies and adults respond to visual information, reports Courtney Humphries for The Atlantic. “Every region that we knew about in adults [with] a preference for faces or scenes has that same preference in babies 4 to 6 months old,” explains Prof. Rebecca Saxe.
The Boston Globe Magazine’s list of some of the most innovative ideas, people, and companies of 2016 features graduate student Dheeraj Roy, whose research suggests that one day optogenetics could potentially be used to help stimulate memories in patients with Alzheimer’s disease.
MIT researchers have found that reduced plasticity in the brains of people with dyslexia may explain why they experience difficulties with reading and with processing spoken speech, writes Kevin Murnane of Forbes. Murnane explains that the findings “indicate that dyslexia is not just about reading. It involves a reduction in neural adaptation to a variety of perceptual stimuli.”
Prof. Ann Graybiel speaks with Forbes contributor Pat Brans about age and habit formation. Graybiel explains that she does not think “it’s ever too late to change habits or to make new ones,” adding that “‘habit’ patterns in the brain have to get renewed reinforcement from time to time.”
Scientific American reporter Veronique Greenwood highlights a study by MIT researchers examining why some people seem to have an aptitude for languages. The researchers explored the structure of neuron fibers in white matter in beginning Mandarin students and found that students “who had more spatially aligned fibers in their right hemisphere had higher test scores after four weeks of classes.”
MIT researchers have found that flashing lights could potentially be used to stave off Alzheimer’s disease, writes Oscar Williams for The Huffington Post. “Light stimulation directed to the hippocampus, the part of the brain that processes memories, led to a reduction of…beta amyloid,” which is found in Alzheimer’s disease.
Financial Times reporter Clive Cookson writes that MIT researchers have found evidence that flashing lights could potentially be used as a noninvasive treatment for Alzheimer’s disease. The researchers found that “lights flashing on and off 40 times per second restored ‘gamma oscillation’ waves that were suppressed in the disease.”
Writing for Fortune, Prof. Earl Miller makes the case that humans cannot multitask successfully and that trying to do so ruins productivity, causes mistakes and interferes with creativity. “When you try to multitask, you typically don’t get far enough down any road to stumble upon something original because you’re constantly switching and backtracking,” explains Miller.