Pulse compression by coupled-cavity mode-locking: numerical modelling

Author

Boardman, A.D. ; Steele, A. ; Wilkins, M.

Author_Institution

Dept. of Phys., Salford Univ., UK

fYear

1989

fDate

32654

Abstract

The behaviour of a composite laser is simulated numerically but the model for the main cavity explicitly uses synchronous pumping as the mode-locking mechanism of the main cavity. This brings the model closer to the actual experimental conditions. The use of an optical fibre (with both normal and anomalous dispersion) in the control cavity can be simulated by numerical solutions of the nonlinear Schrodinger (NLS) equation. The behaviour of a semiconductor diode amplifier used as the external mode-locking element may be modelled as a mapping from the input to the output pulse of the control cavity which incorporates, in a simple way, the effect of saturable amplification

Keywords

high-speed optical techniques; laser cavity resonators; laser mode locking; numerical analysis; optical fibres; anomalous dispersion; composite laser; control cavity; coupled-cavity mode-locking; input pulse; main cavity; mapping; mode-locking mechanism; nonlinear Schrodinger equation; normal dispersion; numerical modelling; optical fibre; output pulse; pulse compression; saturable amplification; semiconductor diode amplifier; synchronous pumping;

fLanguage

English

Publisher

iet

Conference_Titel

Applications of Ultrashort Pulses for Optoelectronics, IEE Colloquium on

Conference_Location

London

Type

conf

Filename

198533