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CMOS-based transceiver looks beyond 5G applications at 300 GHz

A team of scientists at the Tokyo Institute of Technology and NTT have developed a CMOS-based transceiver for wireless communications at the 300 GHz band, looking at applications that go beyond 5G.

The design looks to address the challenges of operating CMOS technology at its practical limit and represents the first wideband CMOS phased-array system to operate at such elevated frequencies.

Communication at these higher frequencies is able to deliver much greater data rates and is able to take advantage of underutilized portions of the electromagnetic spectrum. Many applications beyond 5G, as well as the IEEE802.15.3d standard for wireless communications, call for transmitters and receivers capable of operating close to or above 300 GHz.

Current CMOS technology is not entirely suitable for such elevated frequencies. Near 300 GHz, amplification becomes considerably difficult and although a few CMOS-based transceivers for 300 GHz have been proposed, they either lack enough output power, can only operate in direct line-of-sight conditions, or require a large circuit area to be implemented.

To address these issues, scientists at the Tokyo Institute and NTT have proposed an innovative design for a 300 GHz CMOS-based transceiver. Their work will be presented in the Digests of Technical Papers in the 2021 IEEE ISSCC (International Solid-State Circuits Conference), a conference where the latest advances in solid-state and integrated circuits are exposed.

One of the key features of the proposed design is that it is bidirectional; a great portion of the circuit, including the mixer, antennas, and local oscillator, is shared between the receiver and the transmitter. This means the overall circuit complexity and the total circuit area required are much lower than in unidirectional implementations.

It also uses four antennas in a phased array configuration, by contrast existing solutions for 300 GHz CMOS transmitters use a single radiating element, which limits the antenna gain and the system's output power. An additional advantage is the beamforming capability of phased arrays, which allows the device to adjust the relative phases of the antenna signals to create a combined radiation pattern with custom directionality. The antennas used are stacked "Vivaldi antennas," which can be etched directly onto PCBs, making them easy to fabricate.

The proposed transceiver uses a subharmonic mixer, which is compatible with a bidirectional operation and requires a local oscillator with a comparatively lower frequency. However, this type of mixing results in low output power, which led the team to resort to an old yet functional technique to boost it.

Professor Kenichi Okada from Tokyo Tech, said, "Outphasing is a method generally used to improve the efficiency of power amplifiers by enabling their operation at output powers close to the point where they no longer behave linearly - that is, without distortion. In our work, we used this approach to increase the transmitted output power by operating the mixers at their saturated output power."

Another notable feature of the new transceiver is its excellent cancellation of local oscillator feedthrough (a "leakage" from the local oscillator through the mixer and onto the output) and image frequency (a common type of interference for the method of reception used).

The entire transceiver has been implemented in an area as small as 4.17 mm2. It achieved maximum rates of 26 Gbaud for transmission and 18 Gbaud for reception, outclassing most state-of-the-art solutions.

Commenting on the results, Okada said, "Our work demonstrates the first implementation of a wideband CMOS phased-array system that operates at frequencies higher than 200 GHz."

Author
Neil Tyler

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