Analysis and Design of a Multi-Core Oscillator for Ultra-Low Phase Noise

Journal article (2016)

Authors

S.A.R. Ahmadi Mehr Electronics -

M. Tohidian Electronics -

R.B. Staszewski University College Dublin

Research Group

Electronics () (TU Delft)

DOI: https://doi.org/10.1109/TCSI.2016.2529218

Topology Network analysis Phase noise Coupled oscillators CMOS integrated circuits Phase noise Power demand Inductance Inductors LC circuits MMIC oscillators Field effect MMIC Network synthesis RF oscillator Current 39 mA to 59 mA Digital CMOS technology Dualcore LC-tank oscillator Frequency 4.07 GHz to 4.91 GHz High swing class-C topology Multicore oscillator Phase noise reduction Ultralow phase noise Voltage 2.15 V Basestation (BTS) LC-tank Class-C oscillator Figure of merit (FoM)

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Published Date

11-03-2016

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Microelectronics

Research Group

Electronics

Abstract

In this paper, we exploit an idea of coupling multiple oscillators to reduce phase noise (PN) to beyond the limit of what has been practically achievable so far in a bulk CMOS technology. We then apply it to demonstrate for the first time an RF oscillator that meets the most stringent PN requirements of cellular basestation receivers while abiding by the process technology reliability rules. The oscillator is realized in digital 65-nm CMOS as a dualcore LC-tank oscillator based on a high-swing class-C topology. It is tunable within 4.07-4.91 GHz, while drawing 39-59 mA from a 2.15 V power supply. The measured PN is -146.7 dBc/Hz and -163.1 dBc/Hz at 3 MHz and 20 MHz offset, respectively, from a 4.07 GHz carrier, which makes it the lowest reported normalized PN of an integrated CMOS oscillator. Straightforward expressions for PN and interconnect resistance between the cores are derived and verified against circuit simulations and measurements. Analysis and simulations show that the interconnect resistance is not critical even with a 1% mismatch between the cores. This approach can be extended to a higher number of cores and achieve an arbitrary reduction in PN at the cost of the power and area.

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