Abstract
The equation of motion for the coupled cavities of additive-pulse mode locking is solved with the eigenvalue method. The pulse evolution and self-starting condition for passive operation is analyzed. It is shown that the laser configuration is equivalent to an intracavity interferometer, and a phase modulation across the pulse is the essential element for the mode locking. With the method developed in this paper, transient pulse evolution of an initial seed pulse can be calculated and thereby optimized. It is found that the pulse shortening rate is linear with respect to the number of round-trips. The durations for the initial pulse to shorten to steady state is proportional to its initial width and inversely proportional to the nonlinear coefficient. The effect of dynamic gain saturation on the self-starting condition is also analyzed. The result shows that it would be difficult to achieve self-starting additive-pulse mode locking in the color-center and dye lasers due to their large emission cross sections. Single-cavity configurations of additive-pulse modelocking are proposed. It is shown that they are mathematically equivalent to the couple-cavity one.
Original language | English |
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Pages (from-to) | 562-568 |
Number of pages | 7 |
Journal | IEEE Journal of Quantum Electronics |
Volume | 28 |
Issue number | 2 |
DOIs | |
State | Published - Feb 1992 |