Yang, Chih ChungChih ChungYangKiang, Yean-WoeiYean-WoeiKiangLee, Jiun-HawJiun-HawLeeWang, Jyh-YangJyh-YangWangChen, Horng-ShyangHorng-ShyangChenHsu, Chih-WeiChih-WeiHsuLai, Jiann-ChangJiann-ChangLaiWang, Ding-AnDing-AnWangChen, Chih-ChangChih-ChangChen2009-03-182018-07-062009-03-182018-07-0620010277786Xhttp://ntur.lib.ntu.edu.tw//handle/246246/145857http://ntur.lib.ntu.edu.tw/bitstream/246246/145857/1/07.pdfhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-0035779047&doi=10.1117%2f12.444951&partnerID=40&md5=ca6e0fbc7923d45461a5a350b32bdda3Gain saturation and the induced refractive index variation in semiconductor optical amplifiers (SOAs) have been widely used for many optoelectronics operations, including frequency conversion, phase conjugation, switching, modulation, and laser mode locking. In this paper, we report the experimental and numerical results of using gain saturation in SOAs for all-optical switching and novel laser mode locking configurations. For all-optical switching, we fabricated an all-SOA nonlinear optical loop mirror and implemented efficient power-dependent switching in both cw and pulse modes. Also, numerical modeling was also conducted to show consistent trends with experimental data. For novel laser mode-locking configurations, we demonstrated numerically efficient operation of mode-locked semiconductor laser with multi-mode interference SOA structures. With the nonlinear coupling process, it was found that efficient pulse compression could be achieved, implying that stable mode locking is feasible. Also, with a ring cavity colliding-pulse mode locking can be implemented.application/pdf207975 bytesapplication/pdfen-USGain saturation; Laser mode locking; Nonlinear optical loop mirror; Semiconductor optical amplifier[SDGs]SDG7Laser mode locking; Light interference; Mathematical models; Mirrors; Nonlinear optics; Optical fiber coupling; Semiconducting aluminum compounds; Semiconducting gallium arsenide; Semiconductor device manufacture; Semiconductor device structures; Semiconductor quantum wells; Switching functions; All-optical switching; Multi-mode interference; Nonlinear coupling process; Nonlinear optical effects; Semiconductor optical amplifier; Semiconductor lasersconference paper10.1117/12.4449512-s2.0-0035779047http://ntur.lib.ntu.edu.tw/bitstream/246246/145857/1/07.pdf