A novel numerical model for passively mode-locked solid-state lasers
- 1 April 1983
- journal article
- Published by Institute of Electrical and Electronics Engineers (IEEE) in IEEE Journal of Quantum Electronics
- Vol. 19 (4) , 562-566
- https://doi.org/10.1109/JQE.1983.1071910
Abstract
Numerical computer models could be of high value in testing ideas for improving passive mode locking. Most of the known models for solid-state lasers lack realistic quantitative results, however. A new model is presented, using a rate-equation approach which has been refined to include interference effects by using field amplitudes and phases instead of energies. Also, the saturable absorber is treated by rate equations. With this model, a rather complete description of the pulse evolution is possible. The influence of various parameters on the mode-locking quality is calculated. The model is also capable of reliably describing processes based mainly on interference effects, like the action of external subresonators.Keywords
This publication has 12 references indexed in Scilit:
- Generation of optical pulses shorter than 0.1 psec by colliding pulse mode lockingApplied Physics Letters, 1981
- Observation of the influence of external feed-back on passive mode-lockingOptics Communications, 1979
- Nanosecond pulse generation from a self-injected laser-pumped dye laser using a novel cavity-flipping techniqueOptics Letters, 1978
- Optimization of passively mode-locked giant pulse lasersIEEE Journal of Quantum Electronics, 1978
- Fluctuations in mode-locking threshold due to statistics of spontaneous emissionIEEE Journal of Quantum Electronics, 1975
- The fluctuation model of a passively mode-locked laserIEEE Journal of Quantum Electronics, 1975
- Power and halfwidth of first laser spikeOptics Communications, 1974
- Fluctuation mechanism of ultrashort pulse generation by laser with saturable absorberIEEE Journal of Quantum Electronics, 1972
- Ultrashort-Pulse Generation by-Switched LasersPhysical Review B, 1970
- Mathematical Analysis of Random NoiseBell System Technical Journal, 1945