Title :
A Blocker-Tolerant Inductor-Less Wideband Receiver With Phase and Thermal Noise Cancellation
Author :
Hao Wu ; Mikhemar, Mohyee ; Murphy, David ; Darabi, Hooman ; Chang, Mau-Chung Frank
Author_Institution :
Dept. of Electr. Eng., Univ. of California, Los Angeles, Los Angeles, CA, USA
Abstract :
A wideband receiver architecture with simultaneous phase and thermal noise cancellation greatly relaxes the traditional trade-offs between noise, out-of-band linearity, LO phase noise and power consumption. The architecture employs thermal noise cancelling and avoids voltage gain at blocker frequencies, and exploits the symmetry of phase noise to cancel the reciprocal mixing products in the presence of either single-tone or modulated blockers. The resulting design in 28 nm CMOS has 2 dB noise figure from 100 MHz to 2.8 GHz. Without using any inductors on-chip including the RF VCO, the receiver´s NF is below 14 dB under either a 0 dB CW blocker or a -10 dBm WCDMA blocker.
Keywords :
CMOS integrated circuits; code division multiple access; integrated circuit design; interference suppression; microwave integrated circuits; phase noise; power consumption; radio receivers; radiofrequency interference; radiofrequency oscillators; telecommunication power management; thermal noise; voltage-controlled oscillators; CMOS; CW blocker; LO phase noise; RF VCO; WCDMA blocker; blocker frequencies; blocker-tolerant inductorless wideband receiver; frequency 100 MHz to 2.8 GHz; noise figure; noise figure 2 dB; out-of-band linearity; phase noise cancellation; power consumption; receiver NF; size 28 nm; thermal noise cancellation; voltage gain; voltage-controlled oscillators; wideband receiver architecture; Mixers; Noise cancellation; Phase noise; Receivers; Thermal noise; Wideband; Blocker-tolerant; VCO figure-of-merit; current-mode; gain compression; injection locking; modulated blocker; multi-phase; phase noise cancellation; receiver; reciprocal mixing; ring oscillator; software-defined radio (SDR); thermal noise cancellation; wideband;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2015.2458956
