Title :
Gereration of microwaves with ultra-low phase-noise from an optical clock
Author :
Hollberg, L. ; Diddams, S. ; Bartels, A. ; McFerran, J. ; Ivanov, E. ; Wilpers, G. ; Oates, C.W. ; Oskay, W.H. ; Bergquist, J.C.
Author_Institution :
Nat. Inst. of Stand. & Technol., Boulder, CO
Abstract :
Frequency stabilized lasers have significant advantages for generating microwave signals with unprecedented stability and ultralow phase-noise. We report the optical generation of 10 GHz microwave signals with phase-noise close to the carrier that is > 40 dB better than achieved with state-of-the-art microwave sources and high quality microwave synthesizers. The method uses stable lasers locked to optical resonators that have extremely high Q´s and the frequency can be steered in the longer term to atomic resonances. An optical frequency divider is implemented with a femtosecond laser based optical frequency comb, which coherently divides the optical frequency to the microwave range
Keywords :
Q-factor; frequency dividers; high-speed optical techniques; laser frequency stability; laser mode locking; microwave generation; microwave photonics; optical noise; phase noise; 10 GHz; frequency stabilized lasers; high Q; laser locking; microwave generation; microwave synthesizers; optical clock; optical frequency comb; optical frequency divider; ultralow phase-noise; Atom optics; Clocks; Frequency conversion; Laser stability; Masers; Microwave generation; Optical frequency conversion; Optical resonators; Signal generators; Ultrafast optics;
Conference_Titel :
Microwave Photonics, 2004. MWP'04. 2004 IEEE International Topical Meeting on
Conference_Location :
Ogunquit, ME
Print_ISBN :
0-7803-8491-1
DOI :
10.1109/MWP.2004.1412140
