Abstract :
A harmonic injection-locked divider (HILD) is effective for realizing a low-power phase-locked loop (PLL) circuit because the high-frequency output of a voltage-controlled oscillator (VCO) is down-converted into a low-frequency signal instantaneously. Conventional resonator-based HILDs, however, occupy a large chip area and exhibit a narrow locking range because either an LC or short-stub resonator is required. Ring-oscillator-based HILDs, on the other hand, operate at a relatively low frequency, again with a narrow locking range. In this study, a new HILD based on three-phase harmonic injection locking is proposed, which realizes a small chip area, a low power consumption, and a wide locking range. As a result of fabrication with 0.18 μm CMOS, a divide-by-three HILD is realized with a power consumption of 43 μW, a maximum operating frequency of 6 GHz, and a locking range of 80% at a supply voltage of 0.7 V. The core size is 10.8 μm x 10.5 μm.
Keywords :
CMOS integrated circuits; MMIC oscillators; frequency dividers; phase locked loops; CMOS divide-by-3 frequency divider; PLL; frequency 6 GHz; low-power phase-locked loop; power 43 μW; power 43 muW; ring-oscillator-based HILD; short-stub resonator; size 0.18 μm; three-phase harmonic injection locking; voltage 0.7 V; voltage-controlled oscillator; Circuits; Energy consumption; Frequency conversion; Injection-locked oscillators; Inverters; MOS devices; Phase locked loops; Ring oscillators; Voltage; Voltage-controlled oscillators;
