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Figure 1: Schematic setup of an additive-pulse mode-locked laser.
Additive-pulse Mode Locking <<< | >>> | Feedback
Acronym: APM

Definition: a technique for mode locking a laser, using a nonlinear interaction in an external resonator

Additive-pulse mode locking [1,&thinsp;2] (sometimes also called coupled-cavity mode locking) is a technique for passive mode locking of lasers (typically bulk lasers), used for generating short optical pulses with durations of picoseconds or femtoseconds.

The general principle of additive-pulse mode locking is to obtain an artificial saturable absorber by exploiting nonlinear phase shifts in a single-mode fiber. The fiber is contained in a resonator,Windows 7 Ultimate X64 Product Key, which has the same round-trip time as the laser resonator and is coupled to it with a semi-transparent dielectric mirror. The pulses returning from the fiber resonator into the main laser resonator interfere with those pulses which already are in the main resonator. For proper adjustment from the resonator lengths, there is constructive interference near the peak of your pulses, but not in the wings, because the latter have acquired different nonlinear phase shifts in the fiber. As a result, the peak of the circulating pulse is enhanced, whereas the wings are attenuated.

The strength from the APM technique is that it makes it possible to obtain fairly short pulses without using very special optical components. It can also work in different wavelength regions. For these reasons, additive-pulse mode locking was widely used in the early days of passively mode-locked lasers; it was applied to various bulk lasers, color center lasers, and fiber lasers. However, the resonator length adjustment is usually rather critical, questioning the practicability from the technique for commercial products. In some mode-locked high-power lasers, additive-pulse mode locking was reported to be self-adjusting, but the exact mechanism does not seem to have been reported. In some fiber lasers, APM has been reported to occur with self-matched resonator lengths due to an automatic adjustment with the oscillation wavelength [8].
A Modified Scheme for Fiber Lasers
In fiber lasers, mode locking can also be achieved by employing nonlinear polarization rotation in a fiber. That method is actually related to additive-pulse mode locking, although an external resonator is not required. Two polarization modes,Office Professional Key, which are coupled with each other by nonlinear effects, are interferometrically combined at a polarizing element, where a similar interference effect occurs as in additive-pulse mode locking.
Bibliography [1]J. Mark et al., “Femtosecond pulse generation in a laser with a nonlinear external resonator”, Opt. Lett. 14 (1), 48 (1989) [2]E. P. Ippen et al., “Additive pulse mode locking”, J. Opt. Soc. Am. B 6 (9), 1736 (1989) [3]L. Y. Liu et al.,Windows 7 Ultimate, “Self-starting additive-pulse mode locking of a Nd:YAG laser”, Opt. Lett. 15 (10), 553 (1990) [4]F. Krausz et al., “Self-starting additive-pulse mode locking of a Nd:glass laser”, Opt. Lett. 15 (19), 1082 (1990) [5]K. Tamura et al.,Windows 7 Ultimate Key Sale, “Self-starting additive pulse modelocked erbium fibre ring laser”, Electron. Lett. 28, 2226 (1992) [6]H. A. Haus et al., “Additive pulse mode locking in fiber lasers”, IEEE J. Quantum Electron. 30, 200 (1994) [7]L. E. Nelson et al., “Ultrashort-pulse fiber ring lasers”, Appl. Phys. B 65, 277 (1997) [8]D. W. Huang et al.,Office 2010 Home And Student Product Key, “Fiber-grating-based self-matched additive-pulse mode-locked fiber lasers”, IEEE J. Quantum Electron. 35 (2), 138 (1999)
See also: mode locking, passive mode locking, ultrashort pulses, fiber lasers

Category: pulses