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 by Jennifer Chu, MIT News Office Boston MA (SPX) Jun 14, 2022
Imagine a more sustainable future, where cellphones, smartwatches, and other wearable devices don't have to be shelved or discarded for a newer model. Instead, they could be upgraded with the latest sensors and processors that would snap onto a device's internal chip - like LEGO bricks incorporated into an existing build. Such reconfigurable chipware could keep devices up to date while reducing our electronic waste. Now MIT engineers have taken a step toward that modular vision with a LEGO-like design for a stackable, reconfigurable artificial intelligence chip. The design comprises alternating layers of sensing and processing elements, along with light-emitting diodes (LED) that allow for the chip's layers to communicate optically. Other modular chip designs employ conventional wiring to relay signals between layers. Such intricate connections are difficult if not impossible to sever and rewire, making such stackable designs not reconfigurable. The MIT design uses light, rather than physical wires, to transmit information through the chip. The chip can therefore be reconfigured, with layers that can be swapped out or stacked on, for instance to add new sensors or updated processors. "You can add as many computing layers and sensors as you want, such as for light, pressure, and even smell," says MIT postdoc Jihoon Kang. "We call this a LEGO-like reconfigurable AI chip because it has unlimited expandability depending on the combination of layers." The researchers are eager to apply the design to edge computing devices - self-sufficient sensors and other electronics that work independently from any central or distributed resources such as supercomputers or cloud-based computing. "As we enter the era of the internet of things based on sensor networks, demand for multifunctioning edge-computing devices will expand dramatically," says Jeehwan Kim, associate professor of mechanical engineering at MIT. "Our proposed hardware architecture will provide high versatility of edge computing in the future." The team's results are published in Nature Electronics. In addition to Kim and Kang, MIT authors include co-first authors Chanyeol Choi, Hyunseok Kim, and Min-Kyu Song, and contributing authors Hanwool Yeon, Celesta Chang, Jun Min Suh, Jiho Shin, Kuangye Lu, Bo-In Park, Yeongin Kim, Han Eol Lee, Doyoon Lee, Subeen Pang, Sang-Hoon Bae, Hun S. Kum, and Peng Lin, along with collaborators from Harvard University, Tsinghua University, Zhejiang University, and elsewhere.
Lighting the way In their new chip design, the researchers paired image sensors with artificial synapse arrays, each of which they trained to recognize certain letters - in this case, M, I, and T. While a conventional approach would be to relay a sensor's signals to a processor via physical wires, the team instead fabricated an optical system between each sensor and artificial synapse array to enable communication between the layers, without requiring a physical connection. "Other chips are physically wired through metal, which makes them hard to rewire and redesign, so you'd need to make a new chip if you wanted to add any new function," says MIT postdoc Hyunseok Kim. "We replaced that physical wire connection with an optical communication system, which gives us the freedom to stack and add chips the way we want." The team's optical communication system consists of paired photodetectors and LEDs, each patterned with tiny pixels. Photodetectors constitute an image sensor for receiving data, and LEDs to transmit data to the next layer. As a signal (for instance an image of a letter) reaches the image sensor, the image's light pattern encodes a certain configuration of LED pixels, which in turn stimulates another layer of photodetectors, along with an artificial synapse array, which classifies the signal based on the pattern and strength of the incoming LED light.
Stacking up The team found that the chip correctly classified clear images of each letter, but it was less able to distinguish between blurry images, for instance between I and T. However, the researchers were able to quickly swap out the chip's processing layer for a better "denoising" processor, and found the chip then accurately identified the images. "We showed stackability, replaceability, and the ability to insert a new function into the chip," notes MIT postdoc Min-Kyu Song. The researchers plan to add more sensing and processing capabilities to the chip, and they envision the applications to be boundless. "We can add layers to a cellphone's camera so it could recognize more complex images, or makes these into healthcare monitors that can be embedded in wearable electronic skin," offers Choi, who along with Kim previously developed a "smart" skin for monitoring vital signs. Another idea, he adds, is for modular chips, built into electronics, that consumers can choose to build up with the latest sensor and processor "bricks." "We can make a general chip platform, and each layer could be sold separately like a video game," Jeehwan Kim says. "We could make different types of neural networks, like for image or voice recognition, and let the customer choose what they want, and add to an existing chip like a LEGO." This research was supported, in part, by the Ministry of Trade, Industry, and Energy (MOTIE) from South Korea; the Korea Institute of Science and Technology (KIST); and the Samsung Global Research Outreach Program.
Research Report:"Reconfigurable heterogeneous integration using stackable chips with embedded artificial intelligence"
A quantum drum that stores quantum states for record-long times Copenhagen, Denmark (SPX) Jun 10, 2022 Researchers at the Niels Bohr Institute, University of Copenhagen, have improved the coherence time of a previously developed quantum membrane dramatically. The improvement will expand the usability of the membrane for a variety of different purposes. With a coherence time of one hundred milliseconds, the membrane can for example store sensitive quantum information for further processing in a quantum computer or network. The result has now been published in Nature Portfolio. b>The quantum drum is ... read more
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