TechCrunch reporter Brian Heater spotlights how MIT researchers have developed a new approach to robotic gripping that incorporates reflexes to help grasp and sort objects. “The new system is built around an arm with two multi-joint fingers,” writes Heater. “There’s a camera on the base and sensors on the tips that record feedback. The system uses that data to adjust accordingly.”
Researchers at MIT have created a four-legged robot called DribbleBot, reports Caroline Goggin for WHDH. The robot “can dribble a soccer ball under the same conditions as humans, using onboard sensors to travel across different types of terrain.”
Popular Science reporter Andrew Paul spotlights how researchers from MIT CSAIL have developed a soccer-playing robot, dubbed DribbleBot, that can handle a variety of real-world terrains. “DribbleBot showcases extremely impressive strides in articulation and real-time environmental analysis. Using a combination of onboarding computing and sensing, the team’s four-legged athlete can reportedly handle gravel, grass, sand, snow, and pavement, as well as pick itself up if it falls.”
MIT researchers have created “Dribblebot,” a four-legged robot capable of playing soccer across varying terrain, reports Brian Heater for TechCrunch.
Researchers at MIT have created a four-legged robot capable of dribbling a soccer ball and running across a variety of terrains, reports Ross Cristantiello for Boston.com. “Researchers hope that they will be able to teach the robot how to lift a ball over a step in the future,” writes Cristantiello. “They will also explore how the technology behind DribbleBot can be applied to other robots, allowing machines to quickly transport a range of objects around outside using legs and arms.”
Pickle Robot, an MIT startup, has developed a container unloading robot, reports Brian Heater for TechCrunch. “Pickle has been single-mindedly focused on the specific problem since its inception, actually beginning life attempting to tackle the even more complex task of loading containers,” explains Heater.
MIT engineers have developed a new technique that enables bug-sized aerial robots to handle a sizeable amount of damage and still fly, reports Andrew Paul for Popular Science. “The new repair techniques could come in handy when using flying robots for search-and-rescue missions in difficult environments like dense forests or collapsed buildings,” writes Paul.
Postdoc Zach Patterson speaks with Mashable about how he and his colleagues are developing a soft robot inspired by a sea turtle that could potentially "offer a closer look at ocean life and assist in further studying aquatic creatures.” Patterson explains that the robotic turtle is meant to be a “platform for exploring the interaction between soft and rigid materials incorporated into a robotic structure.”
MIT researchers have constructed a mini city to test to safely test algorithms designed for autonomous vehicles, reports Mashable. “The idea of the mini city is that we have lots of cars going at the same time and we can actually test out new algorithms in a safe environment,” says graduate student Noam Buckman.
Prof. Daniela Rus, director of CSAIL, speaks with Scientific American reporter Nora Bradford about recent advancements in the field of soft robotics. “Building soft robots that can work, heal and grow independently could change many areas of human life,” says Rus. “Soft robot hands are enabling a new age for manufacturing.”
Researchers at MIT have developed a drone that can be controlled using hand gestures, reports Mashable. “I think it’s important to think carefully about how machine learning and robotics can help people to have a higher quality of life and be more productive,” says postdoc Joseph DelPreto. “So we want to combine what robots do well and what people do well so that they can be more effective teams.”
Researchers at MIT have developed underwater robotic structures that can contort into different shapes, reports Andrew Paul for Popular Science. “This ability is key in submersible robots, since it allows them to move through the water much more efficiently, as countless varieties of fish do in rivers, lakes, and the open ocean,” explains Paul.
CSAIL researchers are developing a drone that could be used to assist humans in search and rescue operations, reports Mashable. “If you are trying to detect someone in an avalanche and you can maybe just send a drone, and if they can find them out and then fly towards them and send a help signal. It would be probably be something that would be beneficial to people as an immediate application.”
MIT researchers have developed a new system for creating deformable underwater robots that can be used to build robots of varying shapes and sizes with both hard and soft elements, reports Brian Heater for TechCrunch. “The robot is largely hollow, built of modular voxels that can be assembled to create systems that are rigid in certain directions and soft in others,” Heater explains.
Prof. Daniela Rus, director of CSAIL, speaks with Popular Science reporter Charlotte Hu about the field of artificial intelligence, explaining the difference between AI, robotics and machine learning, and exploring the future of AI. “[AI algorithms] can do really extraordinary things much faster than we can. But the way to think about it is that they’re tools that are supposed to augment and enhance how we operate,” says Rus. “And like any other tools, these solutions are not inherently good or bad. They are what we choose to do with them.”