CSAIL researchers have developed a new system that uses low-power radio waves to detect and track people behind walls, reports Matt Simon for Wired. The system, which can be used to detect signs of distress in elderly patients, also “distinguishes one person from another in the same way your fingerprint distinguishes you,” explains Prof. Dina Katabi.
CSAIL researchers have created a system that can sense a person’s movements through walls, writes John Biggs for TechCrunch. The system is primarily intended as a healthcare device and could help with “passive monitoring of a subject inside a room without cameras or other intrusions,” and could provide insight into disease progression, Biggs explains.
Fast Company reporter Melissa Locker writes that CSAIL researchers have developed a system that allows wireless devices to sense a person’s movement through walls. Locker explains that the technology was created as a way to help those who are elderly, as it could be used to “monitor diseases like Parkinson’s and multiple sclerosis and provide a better understanding of disease progression.”
Boston Herald reporter Lindsay Kalter writes that MIT researchers have developed a wireless ingestible sensor that could one day be used to diagnose and treat disease. “The most exciting thing is that we can wirelessly control tiny implants even though they have no batteries at all,” says Prof. Fadel Adib.
Researchers at MIT have developed a device “that can receive power and communicate wirelessly from inside the body,” which could eventually be used for drug delivery, to treat disease or to monitor overall health, reports Allen Cone for UPI. "Having the capacity to communicate with these systems without the need for a battery would be a significant advance," said research affiliate Gio Traverso.
In a WBUR segment about how technology is increasingly being used to assist seniors and caregivers, Rachel Zimmerman highlights Rendever, an MIT spinout, and speaks with Prof. Paul Osterman, Prof. Dina Katabi and Dr. Joseph Coughlin about their work. Zimmerman explains that Coughlin believes “a mix of smart devices and other personal services,” will help people age well.
In an article for Scientific American about the future of robotics, Prof. Emeritus Rodney Brooks highlights Prof. Dina Katabi’s work developing devices that use wireless signals to detect a person’s emotions.
Boston Magazine reporter Jamie Ducharme writes that CSAIL researchers have developed a device that can measure walking speed using wireless signals. The device can “also measure stride length, which may come in handy when studying conditions that are characterized by small steps, such as Parkinson’s disease.”
Rick Shaffer highlights WiTricity, an MIT spinout, in a Boston Herald article about affordable, easily accessible alternative energy. The company is developing wireless charging pads for electric and hybrid vehicles, which will prevent people from “forgetting to plug a charging cord into their vehicle when they return home.”
In this video, Wired spotlights how Prof. Michael Strano and his team developed spinach plants that can detect explosives in groundwater. Strano explains that in the future he thinks people will be “surprised about what you can do with a living plant.”
Writing for The Boston Globe, Sacha Pfeiffer highlights how MIT has partnered with Google, the City of Cambridge, Boston Properties, Alexandria Real Estate Equities and several other organizations to provide free high-speed Wi-Fi in Kendall Square and at the Newtowne Court and Washington Elms public housing developments.
Kevin Murnane of Forbes spotlights five innovations developed by CSAIL researchers in 2016. Murnane highlights an ingestible origami robot, a 3-D printed robot with solid and liquid components, a robot that can assist with scheduling decisions, an artificial neural network that can explain its decisions, and an algorithm that can predict human interactions.
FOX 25 reporter Elizabeth Hopkins visited the lab of Prof. Michael Strano to learn more about his nanobionic spinach plant research. "What we've done is we've transformed a living plant into a chemical sensor,” Strano says.
Wired reporter Brian Barrett writes that MIT researchers have developed a new system that allows virtual reality headsets to operate wirelessly. The system uses “millimeter wave (mm wave) technology, a large band of spectrum whose potential has gone largely untapped,” Barrett explains.
Hal Hodson writes for New Scientist that MIT researchers have developed a system that allows virtual reality headsets to operate wirelessly. To solve the problem posed by sending vast amounts of data wirelessly, the researchers used a “different wireless technology called millimeter wave (mmWave), which is in a higher band of the frequency spectrum to that used by Wi-Fi.”