Title :
Optical parametric division
Author :
Wong, N.C. ; Lee, D.
Author_Institution :
MIT, Cambridge, MA, USA
Abstract :
A novel concept of optical frequency division based on an efficient, one-step parametric downconversion process is described. An input optical frequency is halved by phase locking the beat frequency of the two subharmonic outputs of an optical parametric oscillator to a microwave frequency source. The approach was demonstrated in a tunable KTP optical parametric oscillator whose phase-locked beat-note linewidth was at the Hz level. A wideband phase modulator that matched the optical and microwave phase velocities was fabricated to facilitate difference frequency measurements. A modulation index of 0.36 with a microwave power of 0.5 W was obtained at 12.4 GHz. When the modulator was enclosed in an optical cavity to enhance the modulation, it generated a fifth order sideband at 62 GHz with 0.1 % sideband power. A new method for measuring optical frequencies from the UV to the near-IR relative to the cesium clock is also described
Keywords :
frequency measurement; frequency synthesizers; measurement standards; optical frequency conversion; optical modulation; optical parametric oscillators; phase-locked loops; 0.5 W; 1 to 2 micron; 12.4 GHz; Cs clock; KTiOPO4; beat frequency; difference frequency measurements; microwave frequency source; microwave power; modulation index; one-step parametric downconversion process; optical frequency division; optical frequency measurement; optical parametric oscillator; phase locking; phase-locked divider; subharmonic outputs; tunable oscillator; wideband phase modulator; Clocks; Frequency conversion; Frequency measurement; Microwave frequencies; Microwave oscillators; Nonlinear optics; Optical modulation; Phase modulation; Power generation; Wideband;
Conference_Titel :
Frequency Control Symposium, 1992. 46th., Proceedings of the 1992 IEEE
Conference_Location :
Hershey, PA
Print_ISBN :
0-7803-0476-4
DOI :
10.1109/FREQ.1992.270038
