英文信息

Cheng Wang

Associate Professor

Graduated School: INSA-Rennes, France

Tel: 021-20685263

Office: SIST, 3-330

E-mail: wangcheng1@shanghaitech.edu.cn

Homepage: https://sist.shanghaitech.edu.cn/wangcheng1_en/main.htm

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Research Area: Semiconductor lasers; AI optical computing chips; optical communication; laser lidar

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Dr. Cheng Wang is tenured Associate Professor (Principal Investigator) at ShanghaiTech University. He received the Ph.D. degree in Optoelectronics from Institut National des Sciences Appliquées de Rennes, France in 2015. He joined ShanghaiTech University in 2016, after half-year stay at City University of Hong Kong as Senior Research Assistant. He was a visiting researcher at Télécom ParisTech (2013-2015), Technische Universität Berlin (2013), and Politecnico di Torino (2014), respectively.

Dr. Wang's research interests include AI optical computing, semiconductor lasers, optical communications, and advanced lidars. He is Associate Editor of Optics Express (2025-), editorial advisory board member of APL Machine Learning (2024-), and technical program committee member of SPIE Photonics West (2020-). He was technical program committee member of International Symposium on Physics and Applications of Laser Dynamics (2018), and symposium co-chair of IEEE Optoelectronics Global Conference (2021).

Email: wangcheng1@shanghaitech.edu.cn

Phone: +86-2120685263

Address: Office 3-330, SIST, ShanghaiTech University, Middle Huaxia Road 393, Pudong, Shanghai 201210, China

Research Interests

Quantum Dot Laser

A quantum dot laser is an advanced semiconductor laser that uses quantum dots as the active laser medium in its light emitting region. In comparison with the conventional quantum well and bulk laser diodes, quantum dot lasers have shown improvements in many performances, including low lasing threshold and high temperature stability. Quantum dot lasers are expected as next-generation optical sources for high-speed optical communication networks. In addition, the lasers are suitable for developing photonic integrated circuits on silicon.

Quantum Cascade Laser

Unlike typical interband sermiconductor lasers, quantum cascade lasers are unipolar devices and the laser emission is achieved through intersubband transition in a repeated stack of semiconductor multiple quantum well heterostructures. The lasing wavelengths spread from mid- to far-infrared portions of the electromagnetic spectrum. The lasers have wide applications in gas spectroscopy, free space optical communication, terahertz imaging and so on.

Interband Cascade Laser

Like quantum cascade lasers, interband cascade laser also employs the gain cascading structures to recycle carriers. However, the laser emission relies on interband transtion of type-II quantum well heterostructures. Interband cascade lasers is power efficient device, and hence suitable for battery-powered equipments for gas sensing in the mid-infrared spectral range.

Photonic Reservoir Computer

Photonic reservoir computer is an advanced recurrent neural network. It is featured with fast training speed and low training cost, because only weights in the output layer require training. In addition, optical computing has merits of high speed, low latency, and high energy efficiency. Photonic reservoir computer is professional at dealing with various time-dependent tasks, including chaotic system prediction, communication signal processing, and speech recognition.

Anti-interference Chaos Lidar

Chaos lidar utilizes random laser chaos sequences to detect targets through the cross-correlation between the back-scattered chaos signal from the target and the local reference one. Owing to the random nature of laser chaos, chaos lidars have excellent anti-jamming and anti-interference capabilities. Chaos lidar is able to realize sub-centimeter accuracy as well as sub-centimeter precision, for ranging distances up to hundreds of meters.

Research Projects

Shanghai Eastern Talent, Optoelectronic Science and Technology, 2026-2029.
Science and Technology Commission of Shanghai Municipality, Deep photonic reservoir edge computing chips, 2024-2026.
Science and Technology Commission of Shanghai Municipality, “Deep-parallel photonic reservoir computer based on semiconductor lasers,” 2024-2026.
National Natural Science Foundation of China, Chaos synchronization and secure communication based on mid-infrared interband cascade lasers, 2025-2028.
ShanghaiTech University, Large-scale deep reservoir computing network based on quantum dot lasers, 2022-2024.
Natural Science Foundation of Shanghai, Spectral linewidth of mid-infrared interband cascade lasers, 2020-2023.
National Natural Science Foundation of China, Optical Noise of InAs/GaAs quantum dot lasers eptaxially grown on Ge / Si, 2019-2021.
Shanghai Pujiang Program, Nonlinear dynamics of quantum cascade lasers subject to optical injection, 2017-2019.
Shanghai Eastern Scholar, Electronic Science and Technology, 2017-2020.
ShanghaiTech University, Startup Fund, 2016-2022.

Journals

2026

67-P. L. Wang, Y. B. Peng, K. L. Lin, Z. H. Jiang, B. Chen, S. Hu, W. Huang, and C. Wang*, Linewidth broadening factor and relative intensity noise of interband cascade lasers grown on InAs substrate, Appl. Phys. Lett. 128, 053301 (2026).

2025

66-B. Liu, C. Silvestri, K. Zhou, X. Ma, S. Wu, Z. Li, W. Wan, Z. Zhang, Y. Zhang, J. Peng, H. Zeng, C. Wang, M. Brambilla, L. Columbo, and H. Li, Terahertz semiconductor laser chaos, Nature Communications 16, 9985 (2025). arXiv.2410.20099
65-H. F. Guo, Z. C. Sun, Y. W. Shen, R. Q. Li, X. Li, and C. Wang*, 20-GHz bandwidth optical activation function based on a semiconductor laser, Opt. Lett. 50, 5805 (2025). arXiv: 2507.00468
64-K. L. Lin, P. L. Wang, Y. B. Peng, S. Yu. C. Cao, C. T. Lee, Q. Gong, F. Y. Lin, W. Huang, C. Wang*, Mid-infrared laser chaos lidar, Opt. Express 33, 26306 (2025).
63-R. Q. Li, Y. W. Shen, Z. K. Niu, G. Xu, J. Yu. X. He, L. Yi, and C. Wang*, Deep photonic reservoir computer for nonlinear equalization of 16-QAM signals, APL Mach. Learn. 3, 026113 (2025).
62-L. Qu, Q. Chu, W. Wang, Z. Jin, F. Gui, F. He, J. Wang, Y. Yao, X. Xu, C. Wang, and J. Duan, Optical noise suppression in epitaxial quantum dot lasers on silicon under mutual injection locking, Opt. Express 33, 8184 (2025).

2024

61-L. Qu, Q. Chu, W. Wang, Z. Jin, S. Ding, C. Wang, X. Xu, J. Wang, and J. Duan, Improvement of optical noise in optical-injection-locked quantum dot lasers epitaxially grown on silicon by reducting external carrier noise, J. Phys. Photon. 6, 045021 (2024).
60-Q. Nie, Y. Peng, Q. Chen, N. Liu, Z. Wang, C. Wang*, and W. Ren*, Agile cavity ringdown spectroscopy enabled by moderate optical feedback to a quantum cascade laser, Opto-Electron. Advances 7, 240077 (2024). IF=15.3
59-Y. B. Peng, Z. Dai, K. L. Lin, P. L. Wang, Z. SHen, B. Chen, F. Grillot, and C. Wang*, Broadband chaos of an interband cascade laser with 6-GHz bandwidth, Opt. Lett. 49, 3142 (2024).
58-K. L. Lin, P. L. Wang, Y. B. Peng, Y. Deng, and C. Wang*, Nonlinear dynamics of an interband cascade laser with optical injection, Opt. Express 32,16722 (2024).
57-[Patent] C. Wang, X. He, J. Yu, X. P. Liu, R. Q. Li, Y. W. Shen, Nonlinear equalizer of coherent optical communcation systems based on photonic reservoir computer (2024).
56-G. T. Liu, Y. W. Shen, R. Q. Li, J. Yu, X. He, and C. Wang*, Optical ReLU-like activation function based on a semiconductor laser with optical injection, Opt. Lett. 49, 818 (2024). arXiv: 2311.01080

2023

55-Z. Jin, H. Huang, Y. Zhou, S. Zhao, S. Ding, C. Wang, Y. Yao, X. Xu, F. Grillot, and J. Duan, Reflection sensitity of dual-sate quantum dot lasers, Photon. Research 11, 1713 (2023).
54-Y. W. Shen, R. Q. Li, G. T. Liu, J. Yu, X. He, L. Yi, and C. Wang*, Deep photonic reservoir computing recurrent network, Optica 10, 1745 (2023). IF=10.4. News in media: MIT Technology Review (https://www.mittrchina.com/news/detail/12894). arXiv:2309.05246
53-R. Q. Li, Y. W. Shen, B. D. Lin, J. Yu. X. He, and C. Wang*, Scalable wavelength-multiplexing photonic reservoir computing, APL Machine Learning 1, 036105 (2023). Editor’s Pick. arXiv: 2305.14927
52-[Patent] C. Wang, X. He, J. Yu, G. T. Liu, An optical nonlinear neuron based on semiconductor lasers (2023).
51-Y. Peng, S. Liu, V. Kovanis, and C. Wang*, Uniform spike trains in optically injected quantum cascade oscillators, Chaos 33, 123127 (2023).
50-J. Y. Tang, B. D. Lin, G. T. Liu, Y. W. Shen, R. Q. Li, J. Yu, X. He, and C. Wang*, Asynchronous photonic time-delay reservoir computing, Opt. Express 31, 2456 (2023).
49-B. D. Lin, Y. W. Shen, J. Y. Tang, J. Yu, X. He, and C. Wang*, Deep time-delay reservoir computing with cascading injection-locked lasers, IEEE J. Sel. Top. Quantum Electron. 29, 7600408 (2023).

2022

48-X. Liao, X. Wang, K. Zhou, W. Guan, Z. Li, X. Ma, Ch. Wang, J. C. Cao, C. Wang*, and H. Li, Terahertz quantum cascade laser frequency combs with optical feedback, Opt. Express 30, 35937 (2022).
47-Y. B. Peng, B. B. Zhao, and C. Wang*, Nonlinear dynamics of a quantum cascade laser with optical injection, Opt. Express 30, 27593 (2022).
46-[Patent] C. Wang, X. He, J. Yu, B. D. Lin, J. Y. Tang, Method and system of deep reservoir optical computing based on semiconductor lasers, 202210280738.2 (2022).
45-X. Y. Li, Z. F. Fan, Y. Deng, and C. Wang*, 30-kHz linewidth interband cascade laser with optical feedback, Appl. Phys. Lett. 120, 171109 (2022).
44-Y. Deng, Z. F. Fan, B. B. Zhao, X. G. Wang, S. Zhao, J. Wu,, F. Grillot, and C. Wang*, Mid-infrared hyperchaos of interband cascade lasers, Light: Science & Applications 11, 7 (2022). IF=20.3
43-J. Y. Tang, B. D. Lin, J. Yu, X. He, and C. Wang*, Parallel time-delay reservoir computing with quantum dot lasers, IEEE. J. Quantum Electron. 58, 8100109 (2022).
42-B. B. Zhao, X. G. Wang, and C. Wang*, Low-frequency oscillations in quantum cascade lasers with tilted optical feedback, IEEE J. Sel. Top. Quantum Electron. 28, 1800207 (2022).

2021

41-B. B. Zhao, Y. B. Peng, X. G. Wang, and C. Wang*, Modulation characteristics of period-one oscillations in quantum cascade lasers, Appl. Sci. 11, 11730 (2021).
40-Z. F. Fan, Y. Deng, C. Ning, S. M. Liu, and C. Wang*, Differential gain and gain compression of an overdamped interband cascade laser, Appl. Phys. Lett. 119, 081101 (2021).
39-X. Y. Zhou, X. G. Wang, B. B. Zhao, Q. F. Liao, and C. Wang*, Frequency noise reduction of delay-coupled quantum cascade lasers, Opt. Express 29, 9030 (2021).
38-X. G. Wang, B. B. Zhao, V. Kovanis, and C. Wang*, Nonlinear dynamics of a quantum cascade laser with tilted optical feedback, Phys. Rev. A 103, 023528 (2021).

2020

37-Y. G. Zhou, J. Duan, F. Grillot, and C. Wang*, Optical noise of dual-state lasing quantum dot lasers, J. Quantum Electron. 56, 2001207 (2020).
36-J. Duan, Y. G. Zhou, B. Dong, H. Huang, J. C. Norman, D. Jung, Z. Zhang, C. Wang, J. E. Bowers, and F. Grillot, Effect of p-doping on the intensity noise of epitaxial quantum dot lasers on silicon, Opt. Lett. 45, 4887 (2020).
35-Y. Deng, B. B. Zhao, X. G. Wang, and C. Wang*, Narrow-linewidth characteristics of interband cascade lasers, Appl. Phys. Lett. 116, 201101 (2020).
34-B. B. Zhao, X. G. Wang, and C. Wang*, Strong optical feedback stabilized quantum cascade laser, ACS Photon. 7, 1255 (2020).
33-X. G. Wang, B. B. Zhao, F. Grillot, and C. Wang*, Spectral linewidth reduction of quantum cascade lasers by strong optical feedback, J. Appl. Phys. 127, 073104 (2020).
32-Y. Deng and C. Wang*, Rate equation modeling of interband cascade lasers on modulation and noise dynamics, IEEE J. Quantum Elelctron. 56, 2300109 (2020).

2019

30-Y. Deng, B. B. Zhao, and C. Wang*, Linewidth broadening factor of an interband cascade laser, Appl. Phys. Lett. 115, 181101 (2019).
29-[Review] C. Wang and Y. G. Zhou, Dynamics of InAs/GaAs quantum dot lasers epitaxially grown on Ge or Si substrate, Journal of semiconductors 40, 101306 (2019).
28-B. B, Zhao, X. G. Wang, and C. Wang*, Relative intensity noise of a mid-infrared quantum cascade laser: Insensitivity to optical feedback, Optics Express 27, 26639 (2019).
27-B. B. Zhao, V. Kovanis, and C. Wang*, Tunable frequency comb generation using period-one limit cycles of quantum cascade lasers, IEEE J. Sel. Top. Quantum Electron. 25, 1900207 (2019).
26-Y. G. Zhou, J. Duan, H. Huang, X. Y. Zhao, C. F. Cao, Q. Gong, F. Grillot, and C. Wang*, Intensity noise and pulse oscillations of an InAs/GaAs quantum dot laser on Germanium, IEEE J. Sel. Top. Quantum Electron. 25, 1900110 (2019).
25-Y. Deng, B. B. Zhao, Y. T. Gu, and C. Wang*, Relative intensity noise of continuous-wave interband cascade laserat room temperature, Opt. Lett. 44, 1375 (2019).

2018

24-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang*, and F. Grillot, Carrier-noise enhanced relative intensity noise of quantum dot lasers, IEEE J. Quantum Electron. 54, 2001407 (2018).
23-Y. G. Zhou, X. Y. Zhao, C. F. Cao, Q. Gong, and C. Wang*, High optical feedback tolerance of InAs/GaAs quantum dot lasers on germanium, Opt. Express 26, 28131 (2018).
22-X. G. Wang, B. B. Zhao, F. Grillot, and C. Wang*, Frequency noise suppression of optical injection-locked quantum cascade lasers, Opt. Express 26, 15167 (2018).
21-J. Duan, H. Huang, Z. G. Lu, P. J. Poole, C. Wang, and F. Grillot, Narrow spectral linewidth in InAs/InP quantum dot distributed feedback lasers, Appl. Phys. Lett. 112, 121102 (2018).
20-X. G. Wang, F. Grillot and C. Wang*, Rate equation modeling of the frequency noise and the intrinsic spectral linewidth in quantum cascade lasers, Opt. Express 26, 2325 (2018).

2017

19-Y. G. Zhou, C. Zhou, C. F. Cao, J. B. Du, Q. Gong, and C. Wang*, Relative intensity noise of InAs quantum dot lasers epitaxially grown on Ge, Opt. Express 25, 28817 (2017).

2016

18-C. Wang, J. -P. Zhuang, F. Grillot, and S. -C. Chan, Contribution of off-resonant states to the phase noise of quantum dot lasers, Opt. Express 24, 29872 (2016).
17-[Book Chapter] J. Even, C. Wang, and F. Grillot, From basic physical properties of InAs/InP quantum dots to state-of-the-art lasers for 1.55 µm optical. communications: an overview, in Semiconductor Nanocrystals and Metal Nanoparticles: Physical Properties and Device Applications (CRC Press, 2016).
16-C. Wang, K. Schires, M. Osiński, P. J. Poole, and F. Grillot, Thermally insensitive determination of the linewidth broadening factor in nanostructured semiconductor lasers using optical injection locking, Nature Scientific Reports 6, 27825 (2016).
15-C. Wang, R. Raghunatahn, K. Schires, S. –C. Chan, L. F. Lester, and F. Grillot, “Optically injected InAs/GaAs quantum dot laser for tunable photonic microwave generation,” Opt. Lett. 41, 1153 (2016).

2015

14-C. Wang, M. E. Chabi, H. M. Huang, D. Erasme, P. J. Poole, J. Even, and F. Grillot, “Frequency-dependent linewidth enhancement factor of optical injection-locked quantum dot/dash laser,” Opt. Express 23, 21761 (2015).
13-I. Aldaya, C. Gosset, C. Wang, G. Campuzano, F. Grillot, and G. Castanon, “Periodic and aperiodic pulse generation using optically injected DFB laser,” IET Electron. Lett. 51, 280 (2015).

2014

12-C. Wang, M. Osiński, J. Even, and F. Grillot, “Phase-amplitude coupling characteristics in directly modulated quantum dot lasers,” Appl. Phys. Lett. 105, 221114 (2014).
11-C. Wang, B. Lingnau, K. Lüdge, J. Even, and F. Grillot, “Enhanced dynamic performance of quantum dot semiconductor lasers operating on the excited state,” IEEE J. Quantum Electron. 50, 723 (2014).
10-C. Wang, F. Grillot, F. Y. Lin, I. Aldaya, T. Batte, C. Gosset, E. Decerle, and J. Even, “Nondegenerate four-wave mixing in a dual-mode injection-locked InAs/InP(100) nanostructure laser,” IEEE Photon. Journal 6, 1500408 (2014).
9-C. Wang, F. Grillot, and J. Even, “Analysis of frequency chirp of self-injected nanostructure semiconductor lasers,” IET Optoelectron. 8, 51 (2014).
8-C. Gosset, I. Aldaya, C. Wang, H. Huang, X. You, J. Even, G. Campuzano, and F. Grillot, “Self-referenced technique for monitoring and analyzing the non-linear dynamics of semiconductor lasers,” Opt. Express 22, 16528 (2014).

2013

7-C. Wang, F. Grillot,V. I. Kovanis, J. D. Bodyfelt, and J. Even, “Modulation properties of optically injection-locked quantum cascade lasers,” Opt. Lett. 38, 1975 (2013).
6-C. Wang, F. Grillot, V. Kovanis, and J. Even, “Rate equation analysis of injection-locked quantum cascade lasers,” J. Appl. Phys. 113, 063104 (2013).
5-F. Grillot, C. Wang*, N. A. Naderi, and J. Even, “Modulation properties of self-injected quantum-dot semiconductor diode lasers,” IEEE J. Sel. Topics in Quantum Electron.19, 1900812 (2013).

2012

4-C. Wang, F. Grillot, and J. Even, “Impacts of wetting layer and excited state on the modulation response of quantum-dot lasers,” IEEE J. Quantum Electon. 48, 1144 (2012).
3-X. Yu, C. Wang*, F. Chen, R. P. Yan, Y. F. Ma, and X. D. Li, “Performance improvement of high repetition rate electro-optical cavity-dumping Nd:GdVO4 laser,” Appl. Phys. B 106, 309 (2012).

2011

2-X. Yu, C. Wang*, F. Chen, R. P. Yan, Y. F. Ma, X. D. Li, and J. B. Peng, “Comparison of electro-optical and acousto-optical Q-switched, high repetition rate Nd:GdVO4 laser,” Laser Phys. 21, 442 (2011).

2010

1-X. Yu, C. Wang*, F. Chen, R. P. Yan, X. D. Li, J. B. Peng, and J. H. Yu, “High repetition rate, high peak power acousto-optical Q-switched 946 nm Nd:YAG laser,” Laser Phys. 20, 1783 (2010).

Conferences

2026

90-Y. W. Shen, R. Q. Li, Z. C. Sun, and C. Wang, Deep photonic reservoir computer for fiber nonlinearity compensation of coherent signals, SPIE Photonics Europe, Strasbourg, France, Apr. 2026.
89-[Invited] Cheng Wang, Deep photonic reservoir computing AI processor and applications, USQS, Sanya, Jan. 2026.

2025

88-[Invited] Cheng Wang, Deep photonic reservoir computer and its applications in optical communication, ICWOC, Chengdu, July, 2025.
87-Y. Song, H. F. Guo, Y. W. Shen, G. H. Situ, C. Wang*, Ghost imaging reconstruction based on deep photonic reservoir computer, Forum on Photonic Integrated Circuits, Wuhan, Aug. 2025.
86-Y. B. Peng, P. L. Wang, K. L. Lin, W. Huang, and C. Wang*, Linewidth broadening factor and relative intensity noise of an InAs-based interband cascade laser, MIOMD XVII, Vienna, Austria, July, 2025.

2024

85-[Invited] Cheng Wang, Parallel-deep photonic reservoir computer and its applications in optical communication, ICNP, Shanghai, Nov. 2024.
84-Y. W. Shen, R. Q. Li, G. Xu, J. Yu, X. He, L. Yi, and C. Wang*, Deep photonics reservoir computer for the fiber nonlinearity compensation of 16-QAM signals, ISPALD, Saitama, Japan, Nov. 2024.
83-[Invited] Cheng Wang, Deep photonic reservoir computer and its application in nonlinear equalization of optical communication, Advanced Photonics: The Intelligent Photonics Forum, Hangzhou, Nov. 2024.
82-[Invited] Cheng Wang, Photonic reservoir computer and its application in optical communication, CNCC, Hengdian, Oct. 2024.
81-[Invited] Cheng Wang, Deep photonic reservoir computer and its application in optical communication, MOTA, Shanghai, Oct. 2024.
80-[Invited] Cheng Wang, Mid-infrared chaos laser and chaos lidar, CIOP, Xi'an, Aug. 2024.
79-[Invited] Cheng Wang, Deep photonic reservoir computer and applications, Microwave Photonics Technology & Applications, Changchun, Aug. 2024.
78-G. T. Liu, Y. W. Shen, R. Q. Li, J. Yu, X. He, and C. Wang*, Broadband optical activation function based on injection-locked semiconductor lasers, CLEO-PR, Incheon, Korea, Aug. 2024.
77-K. L. Lin, P. L. Wang, Y. B. Peng, P. Wang, W. Huang, and C. Wang*, Mid-infrared chaos lidar based on an interband cascade laser, CLEO-PR, Incheon, Korea, Aug. 2024.
76-[Invited] Cheng Wang, Nonlinear equalizer based on photonic reservoir computer, Optics Frontier, Hangzhou, Apr. 2024.
75-[Invited] Cheng Wang, Mid-infrared laser chaos and chaos lidar, Piers, Chengdu, Apr. 2024.

2023

74-[Invited] Cheng Wang, Scalable parallel and deep photonic reservoir computer, Photonic & Advanced Intelligent System Workshop (PAIS & Wiley), Dec. 2023.
73-[Invited] Cheng Wang, Scalable parallel and deep photonic reservoir computing, ISPALD, Metz, France, Nov. 2023.
72- Y. B. Peng, K. L. Lin, P. L. Wang, Q. Gong, B. Chen, F. Grillot, and C. Wang*, Mid-infrared chaos and chaotic lidar based on interband cascade lasers, ISPALD, Metz, France, Nov. 2023.
71-[Invited] Cheng Wang, Mid-infrared laser chaos and chaotic lidar, IEEE Optoelectronics Global conference, Shenzhen, Sep. 2023.
70-[Invited] Cheng Wang, Asynchronous, parallel, deep photonic reservoir computing and its applications, Forum on Photonic Integrated Circuits, Xiamen, Aug., 2023.
69-[Invited] 王成，“储备池光计算,” 光子学公开课，第141期，中国光学学会，2023年6月.
68-G. T. Liu, Y. W. Shen, R. Q. Li, J. Yu, X. He, and C. Wang*, All-optical activation function based on a semiconductor laser, IEEE Summer Topicals, Sicily, Italy, July, 2023.
67-Y. W. Shen, B. D. Lin, R Q. Li, J. Yu, X. He, and C. Wang*, Parallel photonic reservoir computing based on wavelength multiplexing, IEEE Summer Topicals, Sicily, Italy, July, 2023.

2022

66-[Invited] C. Wang, Wide and deep reservoir computing based on semiconductor lasers, Computational Imaging Conference, Shanghai, Oct. 2022.

65-[Invited] C. Wang, Mid-infrared hyperchaos of interband cascade lasers, Forum of Young Scientists in Optics, Fuzhou, Sep., 2022.
64-J. Y. Tang, B. D. Lin, J. Yu, X. He, and C. Wang*, Asynchronous time-delay reservoir computing based on laser dynamics, IEEE Photonics Conference, Vancouver, Canada, Nov., 2022.
63-[Invited] C. Wang, Hyperchaos of interband cascade lasers, International Conference on Information Optics and Photonics, Xi’an, China, July, 2022.
62-B. D. Lin, J. Y. Tang, J. Yu, X. He, and C. Wang*, Deep reservoir computing based on injection-locked quantum dot lasers, CLEO PacificRim, Sapporo, Japan, July, 2022.
61-Y. B. Peng, B. B. Zhao, and C. Wang*, Stability and instability of a quantum cascade laser subject to optical injection, SPIE Photonics Europe, Strasbourg, France, April, 2022.
60-X. G. Wang, and C. Wang*, Nonlinear dynamics modeling of quantum cascade lasers with tilted optical feedback, SPIE Photonics Europe, Strasbourg, France, April, 2022.
59-X. Y. Li, Z. F. Fan, Y. Deng, and C. Wang*, Narrow-linewidth interband cascade lasers subject to optical feedback, SPIE Photonics Europe, Strasbourg, France, April, 2022.
58-B. B. Zhao, Y. B. Peng, X. G. Wang, and C. Wang*, Period-one oscillations of quantum cascade lasers for modulation spectroscopy applications, SPIE Photonics West, San Francisco, US, January, 2022.

2021

57-Y. Deng, Z. F. Fan, and C. Wang*, “Mid-infrared chaos generation with interband cascade lasers,” International Semiconductor Laser Conference, Potsdam, Germany, October, 2021.
56-Y. Deng, C. Ning, Z. F. Fan, S. M. Liu, and C. Wang*, “Differential gain and gain compression of interband cascade lasers,” International Semiconductor Laser Conference, Potsdam, Germany, October, 2021.
55-[Invited] C. Wang, Emerging nonlinear dynamics of mid-infrared semiconductor lasers, International Conference on Information Optics and Photonics, Xi’an, July, 2021.
54-[Invited] C. Wang, Dynamics and nonlinear dynamics of interband cascade lasers, Applied Optics and Photonics China, Beijing, July, 2021.
53-[Invited] C. Wang, Stability and instability of quantum cascade lasers subject to optical feedback, SPIE Photonics West, March, 2021.
52-J. Y. Tang, X. M. He, and C. Wang, Wavelength division multiplexing reservoir computer using quantum dot lasers with delayed optical feedback, SPIE Photonics West, March, 2021.
51-Y. Deng, Z. F. Fan, and C. Wang, Optical feedback induced nonlinear dynamics in an interband cascade laser, SPIE Photonics West, March, 2021.
50-X. Y. Zhou, X. G. Wang, B. B. Zhao, and C. Wang, Optical noise properties of mutually coupled quantum cascade lasers, SPIE Photonics West, March, 2021.

2020

49-X. G. Wang, B. B. Zhao, and C. Wang, Destabilization of Quantum Cascade Lasers Using Tilted Optical Feedback, IEEE Photon. Conference, September, 2020.
48-Y. Deng, Z. F. Fan, and C. Wang, “Optical noise of interband cascade lases subject to optical feedback,” IEEE Photon. Conference, September, 2020.
47-J. Duan, Y. G. Zhou, H. Huang, B. Dong, C. Wang, and F. Grillot, Dynamic properties of two-state lasing quantum dot laser for feedback resistant applications, NUSOD, September, 2020.
46-Y. G. Zhou, S. Zhu, K. M. Lau, and C. Wang, Self-generated chaos in a free-running Fabry-Perot quantum dot laser, CLEO-PR, August, 2020.
45-Y. Deng and C. Wang, Spectral linewidth of a distributed feedback interband cascade laser, CLEO-PR, August, 2020.
44-B. B. Zhao, X. G. Wang, and C. Wang, Spectral linewidth narrowing of a quantum cascade laser by strong optical feedback, SPIE Photonics West, San Francisco, US, Februray, 2020.
43-Y. Deng, C. Wang, Sub-threshold linewidth broadening factor of a 3.4 μm interband cascade laser operated at room temperature, SPIE Photonics West, San Francisco, US, Februray, 2020.

2019

42-X. G. Wang, B. B. Zhao, and C. Wang*, “Frequency noise reduction of quantum cascade lasers using optical feedback,” IEEE Photon. Conference, San Antonio, US, September, 2019.
41-B. B. Zhao, Y. T. Gu, and C. Wang*, “Linewidth broadening factor of an interband cascade laser operated above threshold,” IEEE Photon. Conference, San Antonio, US, September, 2019.
40-X. G. Wang, B. B. Zhao, and C. Wang*, “Optical feedback effects on the relative intensity noise of a mid-infrared quantum cascade laser,” IEEE Photon. Conference, San Antonio, US, September, 2019.
39-Y. Zhou, J. Duan H. Huang, C. Cao, Q. Gong, F. Grillot, and C. Wang, Self-sustained pulse oscillations in a quantum dot laser monolithically grown on germanium, CLEO Europe, Munich Germany, June, 2019.
38-Y. Deng and C. Wang, Rate equation modeling of interband cascade lasers, CLEO Europe, Munich Germany, June, 2019.
37-Y. Deng, Y. T. Gu, B. B. Zhao, and C. Wang, Relative intensity noise of 3.4 μm interband cascade laser, CLEO Europe, Munich Germany, June, 2019.
36-B. B. Zhao and Cheng Wang, Optical frequency comb generation using quantum cascade lasers subject to optical injection, CLEO Europe, Munich Germany, June, 2019.

2018

35-Xing-Guang Wang and Cheng Wang, Noise of quantum cascade lasers with optical feedback, ISPALD, Hong Kong, China, December, 2018.
34-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang, and F. Grillot, Relative intensity noise properties of quantum dot lasers, Proc. of SPIE (2018).
33-Y. G. Zhou, C. F. Cao, J. Y. Yan, Q. Gong, and C. Wang*, Temperature and optical feedback sensitivity of the relative intensity noise of epitaxial quantum dot lasers on Ge, CLEO-PR, Hong Kong, July, 2018.
32-X. G. Wang, B. B. Zhao, and C. Wang*, Frequency noise reduction of injection-locked quantum cascade lasers, CLEO-PR, Hong Kong, July (2018).
31-J. Duan, X. G. Wang, Y. G. Zhou, C. Wang, and F. Grillot, Contribution des etas non-resonants au bruit relatif d’intensite dans les lasers à ilots quantiques, Optique, Toulouse, France, July, 2018.
30-Y. G. Zhou and C. Wang*, Pulse-amplitude modulation of optical injection-locked quantum-dot lasers, Proc. of SPIE 1052606 (2018).
29-J. Duan, H. Huang, K. Schires, P. J. Poole, C. Wang, and F. Grillot, Temperature dependence of spectral linewidth of InAs/InP quantum dot distributed feedback lasers, Proc. of SPIE 10553, 105530J (2018).

2017

28-C. Wang, Y. G. Zhou, Q. Gong, C. F. Cao, J. B. Du, and C. Zhou, Effects of epitaxial defect on the optical noise of InAs/GaAs quantum dot lasers monlithically grown on germanium, ISPALD, Paris, France, November, 2017.
27-X. G. Wang and C. Wang*, Langevin approach analysis of the frequency noise in quantum cascade lasers, Frontiers in Optics, Washington, US, September, 2017.
26-C. Wang, Modeling of period one oscillations in optically injected quantum cascade lasers, CLEO-PR, Singapore, August, 2017.
25-C. Zhou, Y. G. Zhou, J. B. Du, C. F. Cao, Q. Gong, and C. Wang*, Relative intensity noise of an InAs/GaAs quantum dot laser epitaxially grown on germanium, CIOP, Harbin, July, 2017.

2016

24-C. Wang and F. Grillot, Low phase noise quantum dot lasers for coherent communication networks, ACP Conference, Paper AF2A.55, Wuhan, China, November, 2016.
23-C. Wang, J. P. Zhuang, F. Grillot, and S. Z. Chan, Linewidth broadening factor in quantum dot lasers extracted by optical noise analysis, IS-PALD, Hsinchu, Taiwan, September, 2016.
22- [Invited] C. Wang, “New features of linewidth broadening factor in quantum dot lasers,” Light Conference (Young Scientist Forum), Changchun, China, July, 2016.

2015

21-C. Wang, Kevin Schires, Marek Osiński, Philip J. Poole, Jacky Even, and Frédéric Grillot, “A novel method for extracting the linewidth broadening factor of semiconductor lasers,” Frontiers in Optics/Laser Science Conference (FiO/LS), San Jose, California, USA, October, 2015.
20-C. Wang, M. Osiński, K. Schires, J. Even, and F. Grillot, “Modulation-frequency dependence of the phase-amplitude coupling in quantum dot lasers,” CLEO, San Jose, CA, May, 2015.
19-C. Wang, M. Osiński, J. Even, and F. Grillot, “Modulation-frequency dependent linewidth enhancement factor of quantum dot lasers,” SIOE, Cardiff, Wales, April, 2015.
18-C. Wang, M. Gioannini, I. Montrosset, J. Even, and F. Grillot, “Influence of inhomogeneous broadening on the dynamics of quantum dot lasers,” Proc. of SPIE 9357, 93570L, (2015).

2014

17-C. Wang, J. Even, and F. Grillot, “Near-threshold relaxation dynamics of a quantum dot laser,” Proc. of SPIE 9134, 913404 (2014).
16-C. Wang, F. Grillot, V. I. Kovanis, J. D. Bodyfelt, and J. Even, “Rate Equation Analysis of Frequency Chirp in Optically Injection-Locked Quantum Cascade Lasers,” Proc. of SPIE 8980, 898014 (2014).
15-C. Wang, F. Grillot, I. Aldaya, C. Gosset, T. Batte, E. Decerle, and J. Even, “Nondegenerate Four-Wave Mixing in a Dual-Mode Injection Locked InAs/InP(100) Quantum Dot Laser,” Proc. of SPIE 8980, 89801K (2014).
14-C. Wang, M. E. Chaibi, B. Lingnau, D. Erasme, K. Lüdge, P. Poole, J. G. Provost, J. Even, and F. Grillot, “Phase-amplitude coupling of optically injected nanostructure semiconductor lasers,” IEEE Photonics Conference (IPC), San Diego, California USA, October, 2014.
13-C. Wang, M. E. Chaibi, B. Lingnau, D. Erasme, K. Lüdge, P. Poole, J. G. Provost, J. Even, and F. Grillot, “Amplitude modulation and frequency chirp of an injection-locked quantum dash semiconductor laser,” IEEE International Semiconductor Laser Conference (ISLC), Palma de Mallorca, Spain, September, 2014.
12-C. Wang, B. Lingnau, E. Schöll, K. Lüdge, J. Even, F. Grillot, “High performance excited-state nanostructure lasers---modulation response, frequency chirp and linewidth enhancement factor,” CLEO: Applications and Technology, San Jose, California, United States, June, 2014.

2013

11-C. Wang, F. Grillot, and J. Even, “Intensity modulation response of injection-locked quantum cascade lasers,” Proc. of SPIE 8619, 86191Q (2013).
10-C. Wang, F. Grillot, and J. Even, “Impacts of carrier capture and relaxation rates on the modulation response of injection-locked quantum dot lasers,” Proc. of SPIE 8619, 861908 (2013).
9-C. Wang, F. Grillot, and J. Even, “Nonlinear dynamics and modulation properties of optically injected quantum cascade lasers,” CLEO/Europe, Munich, Germany, May, 2013.
8-C. Wang, F. Grillot, and J. Even, “From basic physical properties of InAs/InP quantum dots to state of the art semi-empirical modelling of 1.55 μm directly modulated QD lasers: an overview,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2013.
7-C. Wang, F. Grillot, and J. Even, “Self-injected quantum dot semiconductor lasers,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2013.

2012

6-C. Wang, F. Grillot, and J. Even, “Carrier escape from ground state and non-zero resonance frequency at low bias powers for semiconductor quantum-dot lasers,” Proc. of SPIE 8432, 843225 (2012).
5-C. Wang, F. Grillot, and J. Even, “Controlling the pre-resonance frequency dip in the modulation response of injection-locked quantum dot lasers,” Nonlinear Dynamics in Semiconductor Lasers (NDSL), Berlin, Germany, September, 2012.
4-C. Wang, F. Grillot, and J. Even, “Modelling the gain compression effects in semiconductor quantum-dot lasers through a new modulation transfer function,” IEEE Photonics Conference (IPC), CA, USA, September, 2012.
3-C. Wang, F. Grillot, and J. Even, “Nouvelle formulation de la function de transfer d’un laser à nanostructures quantiques pour les applications à la modulation haut-debit et aux phenomenes microscopiques non-lineaires,” Journées Nationales d'Optique Guidée (JNOG), Lyon, France, July, 2012.
2-C. Wang, F. Grillot, and J. Even, “Modulation response of semiconductor quantum dot lasers,” Semiconductor and Integrated Optoelectronics (SIOE), Cardiff, Wales, April, 2012.

2010

1-X. Yu, C. Wang, F. Chen, R. P. Yan, X. D. Li, and J. H. Yu, “100 kHz electro-optical Q-switched Nd:GdVO4 Laser,” ASOMT&CRST, Harbin, China, July, 2010.

1. Duan, Jianan;Zhou, Yueguang;Huang, Heming;Dong, Bozhang;Wang, Cheng;Grillot, Frederic#, Dynamic properties of two-state lasing quantum dot laser for external optical feedback resistant applications, 2020 INTERNATIONAL CONFERENCE ON NUMERICAL SIMULATION OF OPTOELECTRONIC DEVICES (NUSOD), 2020, 79-80

2. Bin-Bin Zhao;Cheng Wang#, Optical frequency comb generation using quantum cascade lasers subject to optical injection, CLEO EUROPE, 2019, 1

3. Zhao, Bin-Bin;Wang, Xing-Guang;Wang, Cheng#, Spectral linewidth narrowing of a quantum cascade laser by strong optical feedback, SPIE PHOTONICS WEST, 02 Mar 2020,

4. Wang, Xing-Guang;Zhao, Bin-Bin;Wang, Cheng#, Frequency noise reduction of quantum cascade lasers using optical feedback, IEEE PHOTON. CONFERENCE, 2019, 1-2

5. Wang, Xing-Guang;Zhao, Bin-Bin;Wang, Cheng#, Optical Feedback Effects on the Relative Intensity Noise of a Mid-Infrared Quantum Cascade Laser, 2019 IEEE PHOTONICS CONFERENCE (IPC), Sep 2019, 1-2

6. Zhao, Bin-Bin;Gu, Yi-Tian;Wang, Cheng#, Linewidth broadening factor of an interband cascade laser operated above threshold, IEEE PHOTON. CONFERENCE, 2019, 1-2

7. Xing-Guang Wang;Bin-Bin Zhao;Cheng Wang#, Frequency Noise Reduction of Injection-Locked Quantum Cascade Lasers, 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS PACIFIC RIM (CLEO-PR), Jul 2018, Part F113-CLEOPR 2018:1-2

8. Zhao, Bin-Bin;Peng, Yi-Bo;Wang, Xing-Guang;Wang, Cheng#, Period-one oscillations of quantum cascade lasers for modulation spectroscopy applications, SPIE PHOTONICS WEST, 2022,

9. Zhou, Yue-Guang;Zhu, Si;Lau, Kei May;Wang, Cheng#, Self-generaed chaos in a free-running Fabry-Perot quantum dot laser, 2020 CONFERENCE ON LASERS AND ELECTRO-OPTICS PACIFIC RIM (CLEO-PR), 2020,

10. Yue-Guang Zhou;Chun-Fang Cao;Jin-Yi Yan;Qian Gong;Cheng Wang;Yue-Guang Zhou;Chun-Fang Cao;Jin-Yi Yan;Qian Gong;Cheng Wang#, Temperature and Optical Feedback Sensitivity of the Relative Intensity Noise of Epitaxial Quantum Dot Lasers on Ge, 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS PACIFIC RIM (CLEO-PR), Jul 2018, Part F113-CLEOPR 2018:1-2

11. Zhou, Yueguang;Duan, Jianan;Grillot, Frederic;Wang, Cheng#, Optical Noise of Dual-State Lasing Quantum Dot Lasers, IEEE JOURNAL OF QUANTUM ELECTRONICS, Dec 2020, 56(6)

12. Deng, Yu;Wang, Cheng#, Spectral Linewidth of a Distributed Feedback Interband Cascade Laser, CLEO PR 2020, 03 Aug 2020,

13. Wang, Cheng#, Emerging nonlinear dynamics of mid-infrared semiconductor lasers, INTERNATIONAL CONFERENCE ON INFORMATION OPTICS AND PHOTONICS, Jul 2021,

14. Wang, Cheng#, Stability and instability of quantum cascade lasers subject to optical feedback, PROCEEDINGS OF SPIE - THE INTERNATIONAL SOCIETY FOR OPTICAL ENGINEERING, 2021, 11680

15. Deng, Yu;Fan, Zhuo-Fei;Wang, Cheng#, Mid-infrared chaos generation with interband cascade lasers, 2021 27TH INTERNATIONAL SEMICONDUCTOR LASER CONFERENCE (ISLC), 10 Oct 2021,

16. Jia-Nan Duan;Yue-Guang Zhou;Heming Huang;Bozhang Dong;Cheng Wang;F.Grillot#, Dynamic properties of two-state lasing quantum dot laser for feedback resistant applications, NUSOD, 08 Oct 2020,

17. Zhao, Binbin;Wang, Xingguang;Wang, Cheng#, Strong Optical Feedback Stabilized Quantum Cascade Laser, ACS PHOTONICS, 20 May 2020, 7(5):1255-1261

18. Wang, Xing-Guang;Wang, Cheng#, Nonlinear dynamics modeling of quantum cascade lasers with tilted optical feedback, SPIE PHOTONICS EUROPE, 2022, 12141

19. Wang, Xing-Guang;Zhao, Bin-Bin;Grillot, Frederic;Wang, Cheng#, Frequency noise suppression of optical injection-locked quantum cascade lasers, OPTICS EXPRESS, 11 Jun 2018, 26(12):15167-15176

20. Zhao, Bin-Bin;Kovanis, Vassilios;Wang, Cheng#, Tunable Frequency Comb Generation Using Quantum Cascade Lasers Subject to Optical Injection, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, 01 Nov 2019, 25(6)

21. Wang, Xing-Guang;Zhao, Bin-Bin;Deng, Yu;Wang, Cheng#, Destabilization of Quantum Cascade Lasers Using Tilted Optical Feedback, 2020 IEEE PHOTONICS CONFERENCE (IPC), 2020, #VALUE!

22. Deng, Yu;Zhao, Bin-Bin;Wang, Cheng#, Linewidth broadening factor of an interband cascade laser, APPLIED PHYSICS LETTERS, 28 Oct 2019, 115(18):181101

23. Wang, Cheng;Zhuang, Jun-Ping;Grillot, Frederic;Chan, Sze-Chun#, Contribution of off-resonant states to the phase noise of quantum dot lasers, OPTICS EXPRESS, 26 Dec 2016, 24(26):29873-29881

24. Deng, Yu;Li, Xiang-Yi;Fan, Zhuo-Fei;Wang, Cheng#, Narrow-linewidth interband cascade lasers subject to optical feedback, SPIE PHOTONICS EUROPE 2022, 25 May 2022,

25. Deng, Yu;Wang, Cheng#, Rate Equation Modeling of Interband Cascade Lasers, 2019 CLEO EUROPE, 23 Jun 2019, 1

26. Zhao, Bin-Bin;Wang, Xing-Guang;Zhang, Jinchuan;Wang, Cheng#, Relative intensity noise of a mid-infrared quantum cascade laser: insensitivity to optical feedback, OPTICS EXPRESS, 16 Sep 2019, 27(19):26639-26647

27. Wang, Xing-Guang;Grillot, Frederic;Wang, Cheng#, Rate equation modeling of the frequency noise and the intrinsic spectral linewidth in quantum cascade lasers, OPTICS EXPRESS, 05 Feb 2018, 26(3):2325-2334

28. Fan, Zhuo-Fei;Deng, Yu;Ning, Chao;Liu, Shu-Man;Wang, Cheng#, Differential gain and gain compression of an overdamped interband cascade laser, APPLIED PHYSICS LETTERS, 23 Aug 2021, 119(8):081101

29. Deng, Yu;Fan, Zhuo-Fei;Wang, Cheng#, Optical feedback induced nonlinear dynamics in an interband cascade laser, SPIE PHOTONICS WEST 2021, 05 Mar 2021, 11680:116800J

30. Tang, Jia Yan;Lin, Bao De;Yu, Jingyi;He, Xuming;Wang, Cheng#, Parallel time-delay reservoir computing with quantum dot lasers, IEEE JOURNAL OF QUANTUM ELECTRONICS, 01 Apr 2022, 58(2)

31. Deng, Yu;Fan, Zhuo-Fei;Wang, Cheng#, Optical Noise of Interband Cascade Lasers Subject to Optical Feedback, 2020 IEEE PHOTONICS CONFERENCE (IPC), 2020, #VALUE!

32. Zhou, Yue-Guang;Duan, Jianan;Huang, Heming;Zhao, Xu-Yi;Cao, Chun-Fang;Gong, Qian;Grillot, Frederic;Wang, Cheng#, Intensity Noise and Pulse Oscillations of an InAs/GaAs Quantum Dot Laser on Germanium, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, 01 Nov 2019, 25(6)

33. Zhao, Bin-Bin;Wang, Xing-Guang;Wang, Cheng#, Low-Frequency Oscillations in Quantum Cascade Lasers with Tilted Optical Feedback, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, 01 Feb 2022, 28(1)

34. Deng, Yu;Zhao, Bin-Bin;Gu, Yi-Tian;Wang, Cheng#, Relative intensity noise of a continuous-wave interband cascade laser at room temperature, OPTICS LETTERS, 15 Mar 2019, 44(6):1375-1378

35. Wang, Xing-Guang;Zhao, Bin-Bin;Deng, Yu;Kovanis, Vassilios;Wang, Cheng#, Nonlinear dynamics of a quantum cascade laser with tilted optical feedback, PHYSICAL REVIEW A, 22 Feb 2021, 103(2):023528

36. Deng, Yu;Fan, Zhuo Fei;Zhao, Bin Bin;Wang, Xing Guang;Zhao, Shiyuan;Wu, Jiagui;Grillot, Frédéric;Wang, Cheng#, Mid-infrared hyperchaos of interband cascade lasers, LIGHT-SCIENCE & APPLICATIONS, Dec 2022, 11(1):7

37. Li, Xiang-Yi;Fan, Zhuo-Fei;Deng, Yu;Wang, Cheng#, 30-kHz linewidth interband cascade laser with optical feedback, APPLIED PHYSICS LETTERS, 25 Apr 2022, 120(17):171109

38. Deng, Yu;Wang, Cheng#, Sub-threshold linewidth broadening factor of a 3.4 μm interband cascade laser operated at room temperature, SPIE PHOTONICS WEST 2020, 02 Mar 2020, 11274:1127422

39. Deng, Yu;Zhao, Bin-Bin;Wang, Xing-Guang;Wang, Cheng#, Narrow linewidth characteristics of interband cascade lasers, APPLIED PHYSICS LETTERS, 18 May 2020, 116(20):201101

40. Yue-Guang Zhou;Si Zhu;Kei-May Lau;Cheng Wang#, Self-generated chaos in a free-running Fabry-Perot quantum dot laser, CLEO PR, 2020,

41. Wang, Cheng;Schires, Kevin;Osiński, Marek;Poole , Philip J.;Grillot, Frédéric#, Thermally insensitive determination of the linewidth broadening factor in nanostructured semiconductor lasers using optical injection locking, SCIENTIFIC REPORTS, 15 Jun 2016, 6(27825)

42. Wang, Cheng;Grillot, Frederic#, Low Phase Noise Quantum Dot Lasers for Coherent Communication Networks, 2016 ASIA COMMUNICATIONS AND PHOTONICS CONFERENCE (ACP), 2016, 2016-November

43. Tang, Jia-Yan;He, Xu-Ming;Wang, Cheng#, Wavelength division multiplexing reservoir computer using quantum dot lasers with delayed optical feedback, SPIE PHOTONICS WEST, 2021,

44. Deng, Yu;Wang, Cheng#, Rate Equation Modeling of Interband Cascade Lasers on Modulation and Noise Dynamics, IEEE JOURNAL OF QUANTUM ELECTRONICS, Apr 2020, 56(2):2300109

45. Duan, Jianan;Wang, Xing-Guang;Zhou, Yue-Guang;Wang, Cheng;Grillot, Frederic#, Relative intensity noise properties of quantum dot lasers, SEMICONDUCTOR LASERS AND APPLICATIONS VIII, 2018, 10812

46. Zhao, Binbin;Peng, Yibo;Wang, Xingguang;Wang, Cheng#, Modulation characteristics of period-one oscillations in quantum cascade lasers, APPLIED SCIENCE, Dec 2021, 11(24):11730

47. Zhou, Xiang-Yu;Wang, Xing-Guang;Zhao, Bin-Bin;Liao, Qi-Feng;Wang, Cheng#, Frequency noise reduction of delay-coupled quantum cascade lasers, OPTICS EXPRESS, 15 Mar 2021, 29(6):9030-9042

48. Zhou, Xiang-Yu;Wang, Xing-Guang;Zhao, Bin-Bin;Wang, Cheng#, Optical noise properties of mutually coupled quantum cascade lasers, SPIE PHOTONICS WEST, 2021,

49. Wang, Cheng#, Dynamics and nonlinear dynamics of interband cascade lasers, APPLIED OPTICS AND PHOTONICS CHINA, Jul 2021,

50. Wang, Xing-Guang;Zhao, Bin-Bin;Grillot, Frederic;Wang, Cheng#, Spectral linewidth reduction of quantum cascade lasers by strong optical feedback, JOURNAL OF APPLIED PHYSICS, 21 Feb 2020, 127(7)

51. Zhou, Yue-Guang;Zhao, Xu-Yi;Cao, Chun-Fang;Gong, Qian;Wang, Cheng#, High optical feedback tolerance of InAs/GaAs quantum dot lasers on germanium, OPTICS EXPRESS, 15 Oct 2018, 26(21):28131-28139

52. Duan, J.;Huang, H.;Lu, Z. G.;Poole, P. J.;Wang, C.;Grillot, F.#, Narrow spectral linewidth in InAs/InP quantum dot distributed feedback lasers, APPLIED PHYSICS LETTERS, 19 Mar 2018, 112(12)

53. Deng, Yu;Ning, Chao;Fan, Zhuo-Fei;Liu, Shu-Man;Wang, Cheng#, Differential gain and gain compression of interband cascade lasers, 2021 27TH INTERNATIONAL SEMICONDUCTOR LASER CONFERENCE (ISLC), 10 Oct 2021,

54. Duan, Jianan;Wang, Xing-Guang;Zhou, Yue-Guang;Wang, Cheng;Grillot, Frederic#, Carrier-Noise-Enhanced Relative Intensity Noise of Quantum Dot Lasers, IEEE JOURNAL OF QUANTUM ELECTRONICS, Dec 2018, 54(6)

55. Wang, Xing-Guang;Zhao, Bin-Bin;Deng, Yu;Wang, Cheng#, Destabilization of Quantum Cascade Lasers Using Tilted Optical Feedback, 2020 IEEE PHOTONICS CONFERENCE (IPC), 28 Sep 2020,

56. Deng, Yu;Fan, Zhuo-Fei;Wang, Cheng#, Optical Noise of Interband Cascade Lasers Subject to Optical Feedback, 2020 IEEE PHOTONICS CONFERENCE (IPC), 28 Sep 2020,

57. Duan, Jianan;Zhou, Yueguang;Dong, Bozhang;Huang, Heming;Norman, Justin C.;Jung, Daehwan;Zhang, Zeyu;Wang, Cheng;Bowers, John E.;Grillot, Frederic#, Effect of p-doping on he intensity noise of epitaxial quantum dot lasers on silicon, OPTICS LETTERS, 01 Sep 2020, 45(17):4887-4890

58. Deng, Yu;Gu, Yi-Tian;Zhao, Bin-Bin;Wang, Cheng#, Relative intensity noise of 3.4 μm interband cascade laser, 2019 CLEO EUROPE, 23 Jun 2019, 1

59. Zhou, Yue-Guang;Zhou, Cheng;Cao, Chun-Fang;Du, Jiang-Bing;Gong, Qian;Wang, Cheng#, Relative intensity noise of InAs quantum dot lasers epitaxially grown on Ge, OPTICS EXPRESS, 13 Nov 2017, 25(23):28817-28824

60. Wang, Cheng;Raghunathan, Ravi;Schires, Kevin;Chan, Sze-Chun;Lester, Luke F.;Grillot, Frédéric#, Optically injected InAs/GaAs quantum dot laser for tunable photonic microwave generation, OPTICS LETTERS, 15 Mar 2016, 41(6):1153-1156

61. Cheng Wang#, Stability and instability of quantum cascade lasers subject to optical feedback, SPIE PHOTONICS WEST, 2021,

62. Peng, Yi-Bo;Zhao, Bin-Bin;Wang, Cheng#, Stability and instability of a quantum cascade laser subject to optical injection, SPIE PHOTONICS EUROPE 2022, 25 May 2022,

63. Zhao, Bin-Bin;Peng, Yi-Bo;Wang, Xing-Guang;Wang, Cheng#, Period-one oscillations of quantum cascade lasers for modulation spectroscopy applications, PROCEEDINGS OF SPIE - THE INTERNATIONAL SOCIETY FOR OPTICAL ENGINEERING, 2022, 11995

64. Liao, Xiaoyu;Wang, Xingguang;Zhou, Kang;Guan, Wen;Ziping, L.I.;Ma, Xuhong;Wang, Chenjie;Cao, J.C.;Wang, Cheng;Li, Hua#, Terahertz quantum cascade laser frequency combs with optical feedback, OPTICS EXPRESS, 26 Sep 2022, 30(20):35937-35950

65. Peng, Yi-Bo;Zhao, Bin-Bin;Wang, Cheng#, Nonlinear dynamics of a quantum cascade laser with optical injection, OPTICS EXPRESS, 18 Jul 2022, 30(15):27593-27601

66. Deng, Yu;Gu, Yi-Tian;Zhao, Bin-Bin;Wang, Cheng#, Relative Intensity Noise of 3.4 mu m Interband Cascade Laser, 2019 CONFERENCE ON LASERS AND ELECTRO-OPTICS EUROPE & EUROPEAN QUANTUM ELECTRONICS CONFERENCE (CLEO/EUROPE-EQEC), 2019,

67. Wang, Xing-Guang;Zhao, Bin-Bin;Wang, Cheng#, Frequency Noise Reduction of Injection-Locked Quantum Cascade Lasers, 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS PACIFIC RIM, CLEO-PR 2018, 02 Jul 2018,

68. Zhou, Yue-Guang;Cao, Chun-Fang;Yan, Jin-Yi;Gong, Qian;Wang, Cheng#, Temperature and Optical Feedback Sensitivity of the Relative Intensity Noise of Epitaxial Quantum Dot Lasers on Ge, 2018 CONFERENCE ON LASERS AND ELECTRO-OPTICS PACIFIC RIM, CLEO-PR 2018, 02 Jul 2018, Part F113-CLEOPR 2018:1-2

69. Wang, Cheng;Grillot, Frédéric#, Low phase noise quantum dot lasers for coherent communication networks, ASIA COMMUNICATIONS AND PHOTONICS CONFERENCE, ACP, 01 Nov 2016, 2016-November

70. Deng, Yu;Fan, Zhuo-Fei;Zhao, Bin-Bin;Wang, Xing-Guang;Zhao, Shiyuan;Wu, Jiagui;Grillot, Frédéric;Wang, Cheng#, Mid-infrared hyperchaos of interband cascade lasers, LIGHT: SCIENCE AND APPLICATIONS, 01 Dec 2022, 11(1)

71. Li, Xiang-Yi;Fan, Zhuo-Fei;Deng, Yu;Wang, Cheng#, 30-kHz linewidth interband cascade laser with optical feedback, APPLIED PHYSICS LETTERS, 25 Apr 2022, 120(17)

72. Tang, Jia-Yan;Lin, Bao-De;Yu, Jingyi;He, Xuming;Wang, Cheng#, Asynchronous Time-Delay Reservoir Computing Based on Laser Dynamics, 2022 IEEE PHOTONICS CONFERENCE, IPC 2022 - PROCEEDINGS, 2022, 2022-January

73. Lin, Bao-De;Shen, Yi-Wei;Tang, Jia-Yan;Yu, Jingyi;He, Xuming;Wang, Cheng#, Deep Time-Delay Reservoir Computing With Cascading Injection-Locked Lasers, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, 01 Nov 2023, 29(6)

74. Tang, Jia-Yan;Lin, Bao-De;Shen, Yi-Wei;Li, Rui-Qian;Yu, Jingyi;He, Xuming;Wang, Cheng#, Asynchronous photonic time-delay reservoir computing, OPTICS EXPRESS, 16 Jan 2023, 31(2):2456-2466

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