Author :
Ivanov, E.N. ; Hollberg, L. ; Diddams, S.A.
Author_Institution :
Dept. of Phys., Western Australia Univ., Crawley, WA, Australia
Abstract :
The femtosecond laser is a key element of a coherent link between optical and microwave domains. Such a link has already enabled measurements of optical frequencies with an accuracy of a current time standard, the caesium beam microwave ´clock´ (S.A. Diddams et al., Phys. Rev. Lett. vol. 84, pp. 5102-5105, 2000; T. Udem et al., ibid., vol. 86, p. 4996, 2001). Making use of a femtosecond laser, it is also possible to transfer the frequency stability of an optical ´clock´ to radio frequencies. This may result in redefinition of a ´second´ when optical frequency standards supersede their microwave counterparts in terms of accuracy (J.L. Hall et al., IEEE J. Quantum Electron., vol. 37, no. 12, pp. 1482-1492, 2001; L. Hollberg et al., ibid., vol. 37, no. 12, pp. 1502-1513, 2001). In this work we discuss the basic noise mechanisms affecting the frequency stability of a microwave signal produced with a femtosecond laser, including power-to-phase conversion in the photodetector and laser beam-pointing fluctuations.
Keywords :
fluctuations; frequency stability; frequency standards; laser mode locking; microwave generation; optical harmonic generation; optical pulse generation; phase noise; photodetectors; caesium beam microwave clock; coherent optical-microwave domain link; femtosecond laser; laser beam-pointing fluctuations; microwave frequency standards; microwave signal frequency stability; microwave signal generation; noise mechanisms; optical frequency measurements; optical frequency standards; photodetector power-to-phase conversion; time standard; Frequency; Laser noise; Laser stability; Masers; Microwave generation; Noise generators; Signal analysis; Signal generators; Stability analysis; Ultrafast optics;
