"Scientists have built a “microwave brain” chip that processes information at radar-like speeds while sipping power. It could revolutionize how AI and communication devices operate, from smartwatches to satellites. Credit: Shutterstock" (ScitechDaily, Cornell’s Tiny “Microwave Brain” Chip Could Transform Computing and AI)
"Though the chip is still experimental, the researchers are optimistic about its scalability. They are experimenting with ways to improve its accuracy and integrate it into existing microwave and digital processing platforms." (ScitechDaily, Cornell’s Tiny “Microwave Brain” Chip Could Transform Computing and AI)
Cornell University’s new microwave microchip can be a new. Revolutionary tool for signal detection, signal processing, and especially in nano- and AI-technology. The new microchip processes data using microwave fields and their interactions. This makes the new, miniature microchips possible. The microwave-based microchips can turn the networks more effective. Than they ever have been before. The high-power microchip can perform calculations on mobile devices. And that means those new microchips allow the creation of new, pocket-sized computers.
That doesn’t need. To take contact and share information with servers. This thing makes networks more effective. These kinds of microchips can also make it possible to create more intelligent. Small-sized robots. Than ever before. Miniature microchips can control things like drone swarms. But also. Human-shaped robots can use the network-based architecture. This means that the robot’s brains are the microchips that are around the body.
"The chip’s performance comes from its architecture, which functions as a neural network—a system inspired by the human brain. It uses interconnected electromagnetic modes within tunable waveguides to recognize patterns and adapt to incoming information. Unlike standard neural networks that rely on digital operations and clock-timed instructions, this system operates in the analog microwave range, enabling it to process data streams in the tens of gigahertz, far exceeding the speed of most digital processors." (ScitechDaily, Cornell’s Tiny “Microwave Brain” Chip Could Transform Computing and AI)
Those microwave-based systems allow the creation of new. And effective, non-centralized data-operating solutions. Those solutions can be modular systems that are local and mobile. The next-generation quantum network can involve thousands of small calculation units. Microwaves can travel through the air in the form of coherent maser beams. Microwave amplification by stimulated emission of radiation, a maser. It can make it possible. To create a very. Highly focused, coherent communication method. The maser beam is similar to a laser. But the difference is that.
A maser- or microwave beam travels through walls. The microwave frequencies are immune to jammers that operate in radio frequencies. If those maser beams travel in nanotubes, that makes the system even freer from disturbance. The non-centralized system can have a service time when it should find the solution. If there is no solution, the system calls more data units to work on that problem. The microwave-based systems. Don’t need lots of power. and can operate nanomachines.
As well as large systems. Non-centralized computing can make it possible to create the real-life T-1000 robot. The robot uses artificial robot cells that can go together and change the shape of the structure. These kinds of robot amoebas can make missions in places where regular robots cannot operate. The entire structure can involve millions of small-sized robots that can operate separately or as a whole.
https://scitechdaily.com/cornells-tiny-microwave-brain-chip-could-transform-computing-and-ai/
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