Title :
A 96-GHz Oscillator by High-Q Differential Transmission Line loaded with Complementary Split-Ring Resonator in 65-nm CMOS
Author :
Wei Fei ; Hao Yu ; Yang Shang ; Deyun Cai ; Junyan Ren
Author_Institution :
Sch. of Electr. & Electron. Eng., Nanyang Technol. Univ., Singapore, Singapore
Abstract :
A 96-GHz CMOS oscillator is demonstrated in this brief with the use of a high-Q metamaterial resonator. The proposed metamaterial resonator is constructed by a differential transmission line (T-line) loaded with complementary split-ring resonator engraved on the T-line. A negative real part of permittivity, i.e., , is observed near the resonance frequency, which introduces a sharp stopband and, thus, leads to a high-Q resonance. This brief is the first in literature to explore CMOS on-chip metamaterial resonator for oscillator design at the millimeter-wave frequency region. Compared with the existing oscillators with a LC-tank-based resonator at around 100 GHz, the proposed 96-GHz oscillator with high- metamaterial resonator shows much lower phase noise of 111.5 dBc/Hz at 10-MHz offset and figure-of-merit of 182.4 dBc/Hz.
Keywords :
CMOS analogue integrated circuits; MIMIC; Q-factor; integrated circuit design; microwave metamaterials; millimetre wave oscillators; phase noise; CMOS on-chip metamaterial resonator; CMOS oscillator design; LC-tank-based resonator; T-line; complementary split-ring resonator; frequency 96 GHz; high-Q metamaterial resonator; high-Q resonance; high-differential transmission line; millimeter-wave frequency region; permittivity; phase noise; resonance frequency; size 65 nm; CMOS integrated circuits; Magnetic materials; Metamaterials; Phase noise; Resonant frequency; System-on-chip; 65-nm CMOS; High-$Q$ complementary split-ring-resonator (CSRR) oscillator; metamaterial; millimeter (MM)-wave integrated circuit (IC);
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2013.2240813
