Semiconductor breakthrough to accelerate 6G development
12 March 2024
Image: Ryan Young/Cornell University
Ever-smaller devices will be able to operate at the higher frequencies demanded by 6G technology, thanks to the development of 3D reflector microchips.
The next generation of wireless communication not only requires greater bandwidth at higher frequencies – it also needs a little extra time. The new chip adds a necessary time delay so signals sent across multiple arrays can align at a single point in space – without disintegrating.
The majority of current wireless communications, such as 5G phones, operate at frequencies below 6GHz.
Technology companies have been aiming to develop a new wave of 6G cellular communications that use frequencies above 20GHz, where there is more available bandwidth, which means more data can flow, at a faster rate. 6G is expected to be 100 times faster than 5G.
However, since data loss through the environment is greater at higher frequencies, one crucial factor is how the data is relayed. Instead of relying on a single transmitter and a single receiver, most 5G and 6G technologies use a more energy-efficient method: a series of phased arrays of transmitters and receivers.
"Every frequency in the communication band goes through different time delays," said Bal Govind of Cornell University.
"The problem we're addressing is decades old – that of transmitting high-bandwidth data in an economical manner so signals of all frequencies line up at the right place and time."
"It's not just building something with enough delay, it's building something with enough delay where you still have a signal at the end," said senior author Alyssa Apsel, Professor of Engineering.
"The trick is that we were able to do it without enormous loss."
Govind worked with postdoctoral researcher and co-author Thomas Tapen to design a complementary metal-oxide-semiconductor (CMOS) that could tune a time delay over an ultra-broad bandwidth of 14GHz, with as high as one degree of phase resolution.
"Since the aim of our design was to pack as many of these delay elements as possible," Govind said, "we imagined what it would be like to wind the path of the signal in three-dimensional waveguides and bounce signals off of them to cause delay, instead of laterally spreading wavelength-long wires across the chip."
The team engineered a series of these 3D reflectors strung together to form a "tuneable transmission line."
The resulting integrated circuit occupies a 0.13mm2 footprint that is smaller than phase shifters, yet nearly doubles the channel-capacity – i.e., data rate – of conventional wireless arrays. By boosting the projected data rate, the chip could provide faster service, getting more data to smartphone users.
"The big problem with phased arrays is this trade-off between trying to make these things small enough to put on a chip and maintain efficiency," Apsel said.
"The answer that most of the industry has landed on is, 'Well, we can't do time delay, so we're going to do phase delay.' And that fundamentally limits how much information you can transmit and receive. They just sort of take that hit.
"I think one of our major innovations is really the question: do you need to build it this way?" Apsel said. "If we can boost the channel capacity by a factor of 10 by changing one component, that is a pretty interesting game-changer for communications."