Abstract
This paper presents a variable-gain amplifier (VGA) in the 68–78 GHz range. To reduce DC power consumption, the drain voltage was set to 0.5 V with competitive performance in the gain and the noise figure. High-Q shunt capacitors were employed at the gate terminal of the core transistors to move input matching points for easy matching with a compact transformer. The four stages amplifier fabricated in 40-nm bulk complementary metal oxide semiconductor (CMOS) showed a peak gain of 24.5 dB at 71.3 GHz and 3‑dB bandwidth of more than 10 GHz in 68–78 GHz range with approximately 4.8-mW power consumption per stage. Gate-bias control of the second stage in which feedback capacitances were neutralized with cross-coupled capacitors allowed us to vary the gain by around 21 dB in the operating frequency band. The noise figure was estimated to be better than 5.9 dB in the operating frequency band from the full electromagnetic (EM) simulation.
Highlights
For the past few years, automotive radar sensing systems have been massively studied for autonomous cars and relative applications
Most recently, unified V2X and radar systems operating in E-band (60 GHz–90 GHz) allocated for radar sensing have been reported [1,2]
The unified V2X and radar system demands more advanced radio frequency (RF) frontends to accommodate all requirements for each operation modes
Summary
For the past few years, automotive radar sensing systems have been massively studied for autonomous cars and relative applications. A vehicle-to-everything (V2X) system connecting vehicles with vehicles, pedestrians, infrastructure, and networks is believed to another essential technology for future intelligent vehicle applications. Most recently, unified V2X and radar systems operating in E-band (60 GHz–90 GHz) allocated for radar sensing have been reported [1,2]. The unified V2X and radar system demands more advanced radio frequency (RF) frontends to accommodate all requirements for each operation modes. Receiver frontends need to have very high sensitivity for the sensing mode and large gain tunability for the data link mode. Massive phased-array configuration [3] at mm-wave frequencies requires all function blocks to consume less energy with compact occupying area even for variable-gain amplifiers (VGAs).
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