Progress in photonic integrated chaotic semiconductor laser (Invited)

Mengmeng Chai; Lijun Qiao; Mingjiang Zhang; Xiaojing Wei; Qiang Yang; Hongchun Xu

doi:10.3788/IRLA20201066

Journals >Infrared and Laser Engineering >Volume 49 >Issue 12 >Page 20201066 > Article

Infrared and Laser Engineering
Vol. 49, Issue 12, 20201066 (2020)

Progress in photonic integrated chaotic semiconductor laser (Invited)

Mengmeng Chai¹, Lijun Qiao², Mingjiang Zhang¹, Xiaojing Wei¹, Qiang Yang², and Hongchun Xu³

Author Affiliations

¹Key Laboratory of Advanced Transducers and Intelligent Control System of Ministry of Education, Taiyuan University of Technology, Taiyuan 030024, China

²Key Laboratory of Advanced Transducers and Intelligent Control System of Ministry of Education, Taiyuan University of Technology, Taiyuan 030024, China

³Accelink Technology Co. Ltd., Wuhan 430205, China

show less

DOI: 10.3788/IRLA20201066 Cite this Article

Mengmeng Chai, Lijun Qiao, Mingjiang Zhang, Xiaojing Wei, Qiang Yang, Hongchun Xu. Progress in photonic integrated chaotic semiconductor laser (Invited)[J]. Infrared and Laser Engineering, 2020, 49(12): 20201066 Copy Citation Text

show less

Fig. 1. [in Chinese]

Download full size | View in the Article

Fig. 2. [in Chinese]

Download full size | View in the Article

Fig. 3. [in Chinese]

Download full size | View in the Article

Fig. 4. [in Chinese]

Download full size | View in the Article

Fig. 5. [in Chinese]

Download full size | View in the Article

Fig. 6. [in Chinese]

Download full size | View in the Article

Fig. 7. [in Chinese]

Download full size | View in the Article

Fig. 8. [in Chinese]

Download full size | View in the Article

Fig. 8. [in Chinese]

Download full size | View in the Article

Fig. 9. [in Chinese]

Download full size | View in the Article

Fig. 10. [in Chinese]

Download full size | View in the Article

Fig. 11. [in Chinese]

Download full size | View in the Article

Fig. 12. [in Chinese]

Download full size | View in the Article

Method	External cavity	Year	Institute	Band width	Length	Performance
Optical feedback	SOA+phase+straight waveguide	2008	University of Athens （Greece）	20.0 GHz	1.065 cm	Typical single optical feedback
	Phase+SOA	2013	Southwest University; Institute of Semiconductors, Chinese Academy of Science （China）	26.5 GHz	780 μm
	Multi-feedback with air gap	2010	Weierstrass Institute for Applied Analysis and Stochastics （Germany）	7.0 GHz	10.705 mm	Multi-dimension chaos
	Two SOAs+straight waveguide	2011	NTT Communication Science Laboratories （Japan）		10.55 mm	The feedback intensity can be coarse and fine tuned
	Ring waveguide	2011	NTT Communication Science Laboratories （Japan）	10.0 GHz	3.5 mm×3.5 mm	Strong optical feedback
	Two-dimension external cavity	2014	Kanazawa University （Japan）	5.0 GHz	230 μm×1 mm	A long time delay can be achieved with the small area
	Short cavity	2017	Taiyuan University of Technology （China）	5.9 GHz	14-pin butterfly packaging	Hybrid integrated，easy to implement

Mutual injection	Straight waveguide	2014	Tsinghua University （China）		1200 μm
	Y-type waveguide	2017	Saitama University （Japan）		11 mm	Can be used for chaotic synchronization
	Random grating	2020	Taiyuan University of Technology （China）	13.1 GHz	5.9 mm~2.09 cm	Broad bandwidth and time delay signature suppressed

Table 1. 典型光子集成混沌半导体激光器

Download Citation

Save the article for my favorites

Paper Information