Using technology developed at MIT’s Lincoln Laboratory, the Artemis II astronauts are using lasers to send high-resolution video and images back to Earth, reports Hanna Ali for WBUR. Bryan Robinson, the leader of the Lincoln Laboratory Optical and Quantum Communications Group, explained that laser beams allow them to direct more energy at a target receiver. In other words, "you can communicate at higher data rates," Robinson said.
MassLive reporter John Micek writes about how the Artemis II astronauts are using optical communications technology developed at MIT Lincoln Laboratory to send high-resolution video and images of the lunar surface back to Earth.
The stunning images of the moon and Earth being shared by the Artemis II crew have been made possible thanks to new optical communications technology developed by researchers at MIT’s Lincoln Laboratory, reports Emily Maher for WCVB-TV. "It was just awe-inspiring to think humans haven't seen the Earth from pole-to-pole in over 50 years, and being part of helping to make that happen is very cool," said Corrie Smeaton, associate group leader of the Optical Engineering Group at Lincoln Lab.
Artemis II features laser communication technology developed by researchers at MIT’s Lincoln Laboratory, reports Mary Salanda for WCVB. “Known as the O2O, the Orion Artemis II Optical Communications System is mounted on the spacecraft and features a 4-inch telescope that relies on lasers to quickly transmit images from space, including from the far side of the moon.”
A new laser communication system developed by a team from MIT’s Lincoln Laboratory is aboard NASA’s Artemis II mission to the moon, reports Nick Stoico and Hannah Goeke for The Boston Globe. “It’s a culmination of a huge effort by a lot of people,” says Lincoln Lab Group Leader Bryan Robinson. “We’ve been waiting until now to get it off the ground.”
Onboard NASA’s Artemis II mission is an optical (laser) communication system developed by researchers from MIT’s Lincoln Laboratory , reports Steph Solis for Axios. The spacecraft will carry “an optical communication system that can produce 4K video in space during the roughly 10-day flight,” explains Solis.
MIT researchers have “achieved a breakthrough towards building scalable quantum computers,” reports Prabhat Ranjan Mishra for Interesting Engineering, using “cryoelectronics to control ion traps, a key step toward realizing scalable quantum computers.” The team says “this proof-of-principle experiment marks an important advancement toward building large-scale ion-trap quantum computing systems,” writes Mishra.
MIT is “taking a quantum leap with the launch of the new MIT Quantum Initiative (QMIT), reports State House News reporter Katie Castellani. “There isn't a more important technological field right now than quantum with its enormous potential for impact on both fundamental research and practical problems,” said President Sally Kornbluth during the launch event. “QMIT will help us to ask the right questions, identify the most critical problems and create a roadmap for developing quantum solutions that are both transformative and accessible.”
Governor Maura Healey has announced a new initiative aimed at boosting the defense sector in Massachusetts, reports Katie Lannan for GBH. The Massachusetts governor noted that research institutions like MIT Lincoln Lab and Draper have been leaders in defense technology for years, and new startups in fields like AI, cybersecurity and quantum technology also aim to contribute to defense needs. “We want to work together, we want to continue these investments in bigger and stronger ways, looking to keep America secure for another 250 years,” says Healey.
Researchers at MIT’s Lincoln Laboratory are developing “automated electric vessels to map the ocean floor and improve search and rescue missions,” reports Ramen Cromwell for Chronicle. "Ship-based echo sounders cover wide areas but with poor resolution, while undersea vehicles have resolution but search too slowly," says Andrew March, an assistant group leader in MIT Lincoln Laboratory’s Advanced Undersea Systems and Technology Group. "It's called a moonshot. We know less about Earth’s seabed than the moon's surface."
Vijay Gadepally, senior staff member at MIT Lincoln Lab, speaks with New York Times reporter Claire Brown about the impact of AI data centers on the electrical grid. “There’s a lot of things we can do to be better stewards of the power we currently have,” says Gadepally.
In an effort to develop non-invasive ways to treat depression, PTSD, brain tumors and other conditions, researchers from MIT Lincoln Lab are looking to better understand human consciousness, reports Steph Solis for Axios. “There's the goal to analyze how it could help understand or treat PTSD and mood disorders in veterans,” says Solis of the inspiration for this research, “and then there's the existential question that stumps neuroscientists — how does our human experience arise from brain activity?”
Noman Bashir, a fellow with the MIT Climate and Sustainability Consortium and a postdoc at CSAIL, speaks with Wired reporter Molly Taft about AI and energy consumption. Bashir explains that how quickly a model answers a question has a big impact on its energy use. “The goal is to provide all of this inference the quickest way possible so that you don’t leave their platform,” Bashir says. “If ChatGPT suddenly starts giving you a response after five minutes, you will go to some other tool that is giving you an immediate response.”
Vijay Gadepally, a senior scientist at MIT Lincoln Lab, discusses users can help conserve energy while using AI tools, reports Nicolás Rivero for The Washington Post. Gadepally notes that users can save energy by asking the AI to be concise when you don’t need long answers, as models use more energy for each word they process. “People often mistake these things as having some sort of sentience,” says Gadepally. “You don’t need to say ‘please’ and ‘thank you.’ It’s okay. They don’t mind.”
MIT researchers have developed a superconducting circuit that can increase the speed of quantum processing, reports Aamir Khollam for Interesting Engineering. “This device is a superconducting circuit designed to produce extremely strong nonlinear interactions between particles of light (photons) and matter (qubits),” explains Khollam. “This breakthrough could make operations up to 10 times faster, bringing fault-tolerant, real-world quantum computing a major step closer.”