Transceiver chipset enables the development of low-power, high-data rate solutions for true mobile devices
Imec, in collaboration with Panasonic Corporation (Japan), has presented at the IEEE International Solid-State Circuits Conference (ISSCC2013) a 60GHz radio transceiver chipset with low power consumption, that delivers high data rates over short distances. Imec drastically boosted the link budget of the system by introducing beamforming into the radio architecture. This multi-Gbit 60GHz chipset paves the way toward small size, low-power, low-cost, high-data rate solutions for battery-operated consumer devices, such as smart phones and tablets.
The prototype chipset consists of a receiver and a transmitter chip, and these are based on a direct conversion architecture combined with an on-chip phased-array architecture. This makes it suited for implementation in 40nm low-power digital CMOS technology targeting low-cost, mass market production. The receiver and transmitter chips are implemented for 4 antenna paths, but they are easily extendible to more antenna paths thanks to the beamforming at analog baseband, rather than at RF. The chip size is kept low through the use of lumped components even at 60GHz, and very compact mm-wave CMOS layout techniques. The transmitter chip consumes 584mW and the receiver chip 400mW at 1.1V power supply. The chipset is integrated with a 4 antenna array in a compact module and demonstrated in a wireless link. With QPSK modulation, a data rate of 2.31Gbps is obtained, and with QAM16 modulation, a data rate of 4.62Gbps is achieved. No bit errors were found when transmitting packets of 32,768 symbols over a distance of 3.6m with QPSK modulation and 0.7m with QAM16 modulation. Thanks to the beamforming a 3dB scan angle range around 120º is achieved with 11dBi antenna gain.
The imec receiver and transmitter chips are designed for the IEEE802.11ad standard. The receiver and transmitter chipset has been tested with a IEEE 802.11ad PHY/MAC baseband chip developed by Panasonic, demonstrating the complete system for IEEE 802.11 applications. The beamforming functionality is also verified in these system tests.