Title :
A single LC tank self-compensated CMOS oscillator with frequency stability of ±100ppm from −40°C to 85°C
Author :
Sinoussi, N. ; Hamed, A. ; Essam, M. ; El-Kholy, A. ; Hassanein, A. ; Saeed, M. ; Helmy, A. ; Ahmed, A.
Abstract :
This work presents a new all CMOS Self-Compensated Oscillator (SCO) that is highly stable across temperature and is utilized as a reference clock source. The new architecture utilizes an innovative phase shift technique that adjusts the phase of the tank at a specific Temperature Null (TNULL) phase where the frequency deviation across temperature is minimized. The single LC tank architecture used in the new oscillator reduces die area significantly compared to a previously reported dual LC tank architecture. The new oscillator achieves a total frequency stability of ±100ppm across temperature (-40-85°C), supply (3.0-3.6V) and load (0-15pF). CMOS output frequencies from 1-133MHz can be produced with a 2.8ps rms period jitter and 7mA current consumption at 25MHz output.
Keywords :
CMOS analogue integrated circuits; UHF oscillators; SCO; TNULL phase; current 7 mA; dual LC tank architecture; frequency 1 MHz to 133 MHz; frequency deviation; frequency stability; innovative phase shift technique; reference clock source; single LC tank self-compensated CMOS oscillator; temperature -40 degC to 85 degC; temperature null phase; time 2.8 ps; voltage 3.0 V to 3.6 V; CMOS integrated circuits; Impedance; Oscillators; Stability criteria; Temperature measurement; Temperature sensors; Thermal stability; LC oscillator; XO replacement; reference clock; self-compensated oscillator; temperature null;
Conference_Titel :
Frequency Control Symposium (FCS), 2012 IEEE International
Conference_Location :
Baltimore, MD
Print_ISBN :
978-1-4577-1821-2
DOI :
10.1109/FCS.2012.6243676
