Abstract :
An overview on the use of microelectromechanical systems (MEMS) technologies for timing and frequency control is presented. In particular, micromechanical RF filters and reference oscillators based on recently demonstrated vibrating on-chip micromechanical resonators with Q´s >10,000 at 1.5 GHz, are described as an attractive solution to the increasing count of RF components (e.g., filters) expected to be needed by future multi-band wireless devices. With Q´s this high in on-chip abundance, such devices might also enable a paradigm-shift in the design of timing and frequency control functions, where the advantages of high-Q are emphasized, rather than suppressed (e.g., due to size and cost reasons), resulting in enhanced robustness and power savings. With even more aggressive 3D MEMS technologies, even higher on-chip Q´s have been achieved via chip-scale atomic physics packages, which so far have achieved Q´s >107 using atomic cells measuring only 10 mm3 in volume, consuming just 5 mW of power, all while still allowing Allan deviations down to 10-11 at one hour.
Keywords :
Q-factor; UHF filters; atomic clocks; micromechanical resonators; 1.5 GHz; 5 mW; MEMS technology; frequency control; micromechanical RF filters; micromechanical resonators; multiband wireless devices; quality factor; reference oscillators; timing control; Atomic measurements; Cost function; Frequency control; Microelectromechanical systems; Micromechanical devices; Oscillators; Radio frequency; Resonator filters; Robust control; Timing;
