A 1.5 mW 26.2–32.2 GHz divide-by-4 injection-locked frequency divider in 130 nm CMOS process

Abstract

This paper presents a novel divide-by-4 injection-locked frequency divider (ILFD) which is able to work with either a differential input signal or an identical input signal at the dual- port input. It consists of two cascaded divide-by-2 LC-resonance ILFDs. By using dual-injection technique only (both direct injection and tail injection), the locking range of the proposed divide-by-2 ILFDs is enhanced. Meanwhile only NMOS transistor is used in the proposed circuit to minimize the power consumption. At the same time, their structure is optimized for the divide-by-4 ILFD. Simulation is done with 130 nm RF-CMOS process. Without any tuning varactors, at the input power of 0 dBm the maximum locking range of the divider-by-4 ILFD can be achieved respectively at 26.2∼30.2GHz (13.7%) with differential input signal, and at 25.9∼30.6GHz (16.2%) with identical input signal. Its dc power consumption is less than 1.5 mW from a 0.8 V supply voltage which is very attractive.