MIT researchers have created a new fabrication technique to create intricate, 3-D printed magnetic options that react to magnetic fields hitting them at different angles, reports Mark Wilson for Co.Design. In the future the structures, “could be placed in the human body, manipulated via wireless, harmless magnetism, and carry out intricate tasks like on-site drug delivery.”
Fast Company reporter Steven Melendez writes that CSAIL researchers have created a new system that allows a robot to detect human brainwave patterns so it knows when it made a mistake. Melendez explains that, “Teaching robots to understand human nonverbal cues and signals could make them safer and more efficient at working with people.”
MIT researchers have developed a system that allows people to use a combination of brain waves and muscle signals to stop and redirect a robot, writes John Biggs for TechCrunch. “The machine adapts to you, and not the other way around,” explains graduate student Joseph DelPreto.
Prof. Xuanhe Zhao and his colleagues have designed a 3D printer that can create shape-shifting soft materials. The group purposefully created the “materials and the method to be user friendly to enable a wide range of applications,” reports Fiona McMillan for Forbes.
MIT researchers have developed a system that “lets a person control a robotic arm with brainwaves and subtle hand gestures,” reports Jesus Diaz for Co.Design. According to Prof. Daniela Rus, the goal is “to develop robotic systems that are a more natural and intuitive extension of us.”
Engadget reporter Jon Fingas writes that MIT researchers have developed a tiny computer chip small enough to fit on a honeybee-sized drone that can help the drone navigate. The technology could eventually be applied to, “smart pills that navigate to where they're needed, or virtually any vehicle that may need to last for a very long time on one battery charge.”
Prof. Xuanhe Zhao speaks with WBUR about how he and his colleagues have developed a new technique to create soft, pliable structures that could carry out medical procedures within the human body. “Since the human body is soft, it's beneficial to develop a device that has a similar rigidity as soft tissues in the human body,” explains Zhao.
CNBC reporter Lora Kolodny writes about Spyce kitchen, an MIT startup that uses both humans and robots to make what it calls “complex meals.” “Spyce has a stated goal of not replacing human chefs, explains Kolodny, “but helping them work faster, and make delicious meals more consistently, in its restaurants.”
Boston Herald reporter Jordan Graham writes about Ori, a Media Lab spinout that aims to make apartments more functional and spacious through the use of robotic furniture. Founder and CEO Hasier Larrea, an MIT alumnus, explains that by using technology and robotics, “you can make a 300-square-foot apartment be much more functional than a traditional static 400-square-foot apartment.”
In this video, Mashable highlights a new method developed by MIT researchers to 3-D print soft robots that can crawl, fold and carry a pill. The team hopes the structures, which can be controlled with a magnet, could eventually be used as a medical device to take tissue samples or deliver treatments.
Lara Lewington reports for BBC Click on how MIT researchers have developed a technique to create 3-D printed soft structures that can be controlled with a magnet. Lewington explains that the structures could eventually be used in biomedical devices to “take images, extract samples, deliver drugs or even surround a blood vessel to control the pumping of blood.”
Researchers at MIT have created 3D-printed structures that can be controlled by a magnet. The structures included a tube that could squeeze shut, a sheet that could fold, and “a spider-like ‘grabber’ that could crawl, roll, jump, and snap together fast enough to catch a passing ball,” reports Mu Xuequan for Xinhua.
Gabriel Bousquet ’17 speaks to BBC Click’s Gareth Mitchell about the robot he designed for his graduate thesis that was modeled after an albatross. Bosquet envisions using the robot to better understand “the exchanges between the atmosphere and ocean and carbon dioxide,” in the Antarctic Ocean, in an effort to learn more about climate change.
Using magnetic nanoparticles that have been mixed into rubber, Associate Prof. Xuanhe Zhao has created “3D printed shapes that fold, morph, and move in the presence of a magnetic field,” reports Leah Crane for New Scientist. In the future, Zhao believes this work could have medical applications, “like assisting minimally invasive surgeries,” notes Crane.
In response to a reader’s question about self-driving cars, Mercury News reporter Gary Richards describes new technology in the works by MIT researchers to allow, “driverless cars to change lanes more like human drivers do.”