Sean T. Nicolson

A Zero-IF 60 GHz 65 nm CMOS Transceiver With Direct BPSK Modulation Demonstrating up to 6 Gb/s Data Rates Over a 2 m Wireless Link

This paper presents a directly modulated, 60 GHz zero-IF transceiver architecture suitable for single-carrier, low-power, multi-gigabit wireless links in nanoscale CMOS technologies. This mm-wave front end architecture requires no upconversion of the baseband signals in the transmitter and no analog-to-digital conversion in the receiver, thus minimizing system complexity and power consumption. All circuit blocks are realized using sub-1.0 V topologies, that feature only a single high-frequency transistor between the supply and ground, and which are scalable to future 45 nm, 32 nm, and 22 nm CMOS nodes. The transceiver is fabricated in a 65 nm CMOS process with a digital back-end. It includes a receiver with 14.7 dB gain and 5.6 dB noise figure, a 60 GHz LO distribution tree, a 69 GHz static frequency divider, and a direct BPSK modulator operating over the 55-65 GHz band at data rates exceeding 6 Gb/s. With both the transmitter and the receiver turned on, the chip consumes 374 mW from 1.2 V which reduces to 232 mW for a 1.0 V supply. It occupies 1.28 times 0.81 mm2. The transceiver and its building blocks were characterized over temperature up to 85^deg C and for power supplies down to 1 V. A manufacturability study of 60 GHz radio circuits is presented with measurements of transistors, the low-noise amplifier, and the receiver on slow, typical, and fast process splits. The transceiver architecture and performance were validated in a 1-6 Gb/s 2-meter wireless transmit-receive link over the 55-64 GHz range.

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This paper presents a complete 0.13 μm SiGe BiCMOS technology fully dedicated to millimeter-wave applications, including a high-speed (230/280 GHz fT/fMAX) and medium voltage SiGe HBT, thick-copper back-end designed for high performance transmission lines and inductors, 2 fF/μm2 high-linearity MIM capacitor and complementary double gate oxide MOS transistors. Details are given on HBT integration, reliability and models as well as on back-end devices models.

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This paper reviews recent research conducted at the University of Toronto on the development of CMOS transceivers aimed at operation in the 90-170-GHz range. Unique nanoscale CMOS issues related to millimeter-wave circuit design in the 65-nm node and beyond are addressed with an emphasis on transistor and top-level layout issues, low-voltage circuit topologies, and design flow. A Doppler transceiver and two receivers fabricated in a 65-nm GPLP CMOS technology are described, along with a single pole, double throw antenna switch with better than 5-dB insertion loss and 25-dB isolation in the entire 110-170-GHz band. The first receiver has an IQ architecture with a fundamental frequency voltage-controlled oscillator, and is intended for wideband passive imaging applications at 100 GHz. The measured noise figure and downconversion gain are 7-8 and 10.5 dB, respectively, while the 3-dB bandwidth extends from 85 to 100 GHz. The second receiver has double-sideband architecture, operates in the 135-145-GHz range (the highest for CMOS receivers), and features an 8-dB gain LNA, a double-balanced Gilbert cell mixer, and a dipole antenna. The 90-94-GHz Doppler transceiver, the highest frequency reported to date in CMOS, is intended for the remote monitoring of respiratory functions. A Doppler shift of 30 Hz, produced by a slow-moving (4.8 cm/s) target located at a distance of 1 m, was measured with a transmitter output power of approximately + 2 dBm and a phase noise of -90 dBc/Hz at 1 MHz offset. The range correlation effect is demonstrated for the first time in CMOS by measuring the phase noise of the received baseband signal at 10-Hz offset, clearly indicating that 1/f noise has been canceled and it does not pose a problem in short-range applications, where neither a phase-locked loop nor a frequency divider are needed.

m SiGe BiCMOS Technology Fully Dedicated to mm-Wave Applications

This paper presents a complete 2.5-V 77-GHz chipset for Doppler radar and imaging applications fabricated in SiGe HBT and SiGe BiCMOS technologies. The chipset includes a 123-mW single-chip receiver with 24-dB gain and an IP1 dB of -21.7 dBm at 76-GHz local oscillator (LO) and 77-GHz RF, 4.8-dB double-sideband noise figure at 76-GHz LO and 1-GHz IF, and worst case -98.5 dBc/Hz phase noise at 1-MHz offset over the entire voltage-controlled oscillator tuning range at room temperature. Monolithic spiral inductors and transformers result in a receiver core area of 450 mum times 280 mum. For integration of an entire 77-GHz transceiver, a power amplifier with 19-dB gain, +14.5-dBm saturated output power, and 15.7% power-added efficiency is demonstrated. Frequency divider topologies for 2.5-V operation are investigated and measurement results show a 105-GHz static frequency divider consuming 75 mW, and a 107-GHz Miller divider consuming 33 mW. Measurements on all circuits confirm operation up to 100 deg C. Low-power low-noise design techniques for each circuit block are discussed.

Nanoscale CMOS Transceiver Design in the 90–170-GHz Range

This paper presents the first single-chip direct-conversion 77-85 GHz transceiver fabricated in SiGe HBT technology, intended for Doppler radar and millimeter-wave imaging, particularly within the automotive radar band of 77-81 GHz. A 1.3 mm times 0.9 mm 86-96 GHz receiver is also presented. The transceiver, fabricated in a 130 nm SiGe HBT technology with fT/fMAX of 230/300 GHz, consumes 780 mW, and occupies 1.3 mm times 0.9 mm of die area. Furthermore, it achieves 40 dB conversion gain in the receiver at 82 GHz, a 3 dB bandwidth extending from 77 to 85 GHz at 25degC, and covering the entire 77-81 GHz band up to 100degC, record 3.85 dB DSB noise figure measured at 82 GHz LO and 1 GHz IF, and an IP1dB of -35 dBm. The transmitter provides + 11.5 dBm of saturated output power at 77 GHz, and a divide64 static frequency divider is included on-die. Successful detection of a Doppler shift of 30 Hz at a range of 6 m is shown. The 86-96 GHz receiver achieves 31 dB conversion gain, a 3 dB bandwidth of 10 GHz, and 5.2 dB DSB noise figure at 96 GHz LO and 1 GHz IF, and -99 dBc/Hz phase noise at 1 MHz offset. System-level layout and integration techniques that address the challenges of low-voltage transceiver implementation are also discussed.

A Low-Voltage SiGe BiCMOS 77-GHz Automotive Radar Chipset

This paper describes a single-chip, 70-80 GHz wireless transceiver utilizing a direct mm-wave QPSK modulator. The transceiver was fabricated in a 130 nm SiGe BiCMOS technology and can operate at data rates in excess of 18 Gb/s. The peak gain of the zero-IF receiver is 50 dB, the double sideband noise figure remains below 7 dB, while the 3-dB receive-chain bandwidth extends from DC to over 6 GHz. The differential transmitter achieves a maximum output power of +9 dBm. The total power consumption of the 1.9 mm × 1.1 mm transceiver is 1.2 W from 1.5, 2.5 and 3.3 V power supplies, including the 4 × 20-Gb/s PRBS generator.

Single-Chip W-band SiGe HBT Transceivers and Receivers for Doppler Radar and Millimeter-Wave Imaging

This paper presents a 1.2 V, 100 mW, 140 GHz receiver with on-die antenna in a 65 nm General Purpose (GP) CMOS process with digital back-end. The receiver has a conversion loss of 15-19 dB in the 100-140 GHz range with 102 GHz LO, and occupies a die area of only 580 mum times 700 mum including pads. The LNA achieves 8 dB gain at 140 GHz, 10 GHz bandwidth, at least -1.8 dBm of saturated output power, and maintains 3 dB gain at 125 degC. The on-chip antenna, which meets all density fill requirements of 65 nm CMOS, has -25 dB gain, and occupies 180 mum times 100 mum of die area. Additionally, design techniques which maximize the millimeter-wave performance of CMOS devices are discussed.

An 18-Gb/s, Direct QPSK Modulation SiGe BiCMOS Transceiver for Last Mile Links in the 70–80 GHz Band

This paper discusses the design of 77-106 GHz Colpitts VCOs fabricated in two generations of SiGe BiCMOS technology, with MOS and HBT varactors, and with integrated inductors. Based on a study of the optimal biasing conditions for minimum phase noise, it is shown that VCOs can be used to monitor the mm-wave noise performance of SiGe HBTs. Measurements show a 106 GHz VCO operating from 2.5 V with phase noise of -101.3 dBc/Hz at 1 MHz offset, which delivers +2.5 dBm of differential output power at 25degC, with operation verified up to 125degC. A BiCMOS VCO with a differential MOS-HBT cascode output buffer using 130 nm MOSFETs delivers +10.5 dBm of output power at 87 GHz.

A 1.2V, 140GHz receiver with on-die antenna in 65nm CMOS

This paper presents a step-by-step methodology for simultaneous noise and input impedance matching in CMOS and SiGe W-band LNAs. This technique yields either increased gain or reduced power dissipation. Additionally, techniques to determine the optimum layout for MOSFETs in mm-wave LNAs are discussed. Measurement results in 90nm CMOS show a 1-stage 1.8V, 78GHz LNA with 3.8dB gain and 16mW power dissipation, and a 1.8V, 2-stage 94GHz LNA with 4.8dB gain, and 30mW power dissipation. In all cases S11 and S22 are lower than -10 dB

Design and Scaling of W-Band SiGe BiCMOS VCOs

This paper presents a complete 0.13 mum SiGe BiCMOS technology fully dedicated to millimeter-wave applications, including a high-speed (230/280GHz fT/fMAX) and medium voltage SiGe HBT, thick-copper back-end designed for high performance transmission lines and inductors, 2fF/mum2 high-linearity MIM capacitor and complementary double gate oxide MOS transistors.