The transmitter features exceptional output power and energy efficiency while supporting data rates of up to 56Gb/s per channel. It is a key component of a 4-way beamforming transceiver chip currently being developed by imec’s researchers, with which they aim to support the deployment of next-generation, short-range wireless services at frequencies above 100GHz.
Next-generation short-range wireless applications, boasting data rates in the tens of gigabits per second, usher in an era of opportunity. Whether it's data centres in search of wireless fail-safe mechanisms, fixed wireless access (FWA) deployments, or wireless hotspots enabling extended reality (XR) experiences, they are all converging on the sub-THz bands between 100 and 300GHz.
The ample bandwidth offered by these frequencies is just one of the essential features. In addition, their shorter wavelengths allow for smaller antennas, enabling increasingly compact access points and handheld devices. Finally, the high sensing resolution will prove invaluable in future applications (gaming, smart buildings, Industry 5.0) where communication and sensing are intertwined.
“Yet, when CMOS technology ventures into the realm of 100GHz and beyond, it encounters various obstacles. The first challenge is to achieve sufficient output power to overcome the higher pathloss at these frequencies. It’s also much more difficult to realise wideband circuitry with good dynamic range and acceptable power consumption. These challenges are at the heart of our novel CMOS-based D-band beamforming transmitter,” explained Joris Van Driessche, program manager at imec.
The transmitter, part of a 4-way beamforming transceiver architecture, operates in the 120-145GHz frequency range. Designed using a 22nm FD-SOI process, each transmitter channel occupies an area of 1.17x0.3mm² and consumes 232mW of power.
And with a Pout of 3dBm for 16QAM modulation and 2dBm for 64QAM modulation, imec’s implementation is claimed to be one of the top performers among CMOS D-band transceivers in terms of transmitted output power.
By implementing beamforming in the local oscillator circuit to steer high-gain narrow beams in specific directions, in combination with a zero-IF transceiver architecture, imec's transmitter reduces the number of components in the signal path.
As such, the dynamic range of the signal path is preserved, and a wide RF bandwidth can be achieved. In addition, imec's design features a wideband analogue baseband section covering channel bandwidths up to 14GHz, enabling high data rates (up to 56Gb/s per channel) across a broad frequency range.
Joris Van Driessche: “And yet another unique feature of our chip is its completeness. Unlike competing solutions, ours seamlessly integrates LO beamforming and a full analogue baseband section across all four channels, along with the complete RF chain and beamforming functionality. To our knowledge, this is a significant first.”
This research is part of imec’s Advanced RF program, which aims to enable next-generation, high-data-rate wireless and high-resolution sensing applications by addressing challenges from the device level, up to the system level.
