Title :
A subharmonic self-oscillating mixer with integrated antenna for 60-GHz wireless applications
Author :
Sironen, Mikko ; Qian, Yongxi ; Itoh, Tatsuo
Author_Institution :
Dept. of Electr. Eng., California Univ., Los Angeles, CA, USA
fDate :
3/1/2001 12:00:00 AM
Abstract :
A balanced integrated-antenna self-oscillating mixer at 60 GHz is presented in this paper. The modal radiation characteristics of a dual-feed planar quasi-Yagi antenna are used to achieve RF-local oscillator (RF-LO) isolation between closely spaced frequencies. The balanced mixer is symmetric, inherently broad band, and does not need an RF balun. Pseudomorphic high electron-mobility transistors are used in a 30-GHz push-pull circuit to generate the second harmonic and a 30-GHz dielectric resonator was used to stabilize the fundamental oscillation frequency. This allows the possibility of building a balanced low-cost self-contained antenna integrated receiver with low LO leakage for short-range narrow-band communication. Phase locking can be done with half of the RF frequency. The circuit exhibits a conversion loss less than 15 dB from 60 to 61.5 GHz, radiation leakage of -26 dBm at 60 GHz, and IF phase noise of -95 dBc/Hz at 100-kHz offset
Keywords :
HEMT circuits; Yagi antenna arrays; antenna radiation patterns; dielectric resonators; millimetre wave antenna arrays; millimetre wave circuits; millimetre wave mixers; phase locked oscillators; 60 GHz; IF phase noise; RF-local oscillator isolation; closely spaced frequencies; conversion loss; dielectric resonator; dual-feed planar quasi-Yagi antenna; fundamental oscillation frequency; millimetre-wave mixers; modal radiation characteristics; phase locking; pseudomorphic high electron-mobility transistors; push-pull circuit; radiation leakage; second harmonic; short-range narrow-band communication; subharmonic self-oscillating mixer; Bandwidth; Circuits; Dielectric resonator antennas; Dielectric substrates; Impedance matching; Mixers; Optical feedback; Oscillators; Radio frequency; Receiving antennas;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
