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    Journals >Laser & Optoelectronics Progress >Volume 58 >Issue 7 >Page 0714008 > Article
    • Laser & Optoelectronics Progress
    • Vol. 58, Issue 7, 0714008 (2021)
    Design of High Stability Control System for Chaotic Semiconductor Lasers
    Wenmin Xu1, Qiang Yang1, Xing Wang1, Mengmeng Chai2, Mingjiang Zhang1、2、*, Jianzhong Zhang1, Lijun Qiao1, Tao Wang1, and Shaohua Gao2
    Author Affiliations
  • 1Key Laboratory of Advanced Transducers and Intelligent Control System, Ministry of Education and Shanxi Province, Taiyuan University of Technology, Taiyuan , Shanxi 030024, China
  • 2College of Physics and Optoelectronics, Taiyuan University of Technology, Taiyuan , Shanxi 030024, China
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    DOI: 10.3788/LOP202158.0714008 Cite this Article Set citation alerts
    Wenmin Xu, Qiang Yang, Xing Wang, Mengmeng Chai, Mingjiang Zhang, Jianzhong Zhang, Lijun Qiao, Tao Wang, Shaohua Gao. Design of High Stability Control System for Chaotic Semiconductor Lasers[J]. Laser & Optoelectronics Progress, 2021, 58(7): 0714008 Copy Citation Text show less
    Schematic of current source 1
    Fig. 1. Schematic of current source 1
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    Schematic of current source 2
    Fig. 2. Schematic of current source 2
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    Temperature control circuit. (a) H bridge drive circuit; (b) temperature acquisition circuit
    Fig. 3. Temperature control circuit. (a) H bridge drive circuit; (b) temperature acquisition circuit
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    Structure diagram of fuzzy adaptive PID system
    Fig. 4. Structure diagram of fuzzy adaptive PID system
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    Experimental setup of chaotic semiconductor laser output performance test
    Fig. 5. Experimental setup of chaotic semiconductor laser output performance test
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    Output characteristics of chaotic semiconductor laser. (a) Optical spectrum; (b) frequency spectrum;(c)time series;(d)ACF
    Fig. 6. Output characteristics of chaotic semiconductor laser. (a) Optical spectrum; (b) frequency spectrum;(c)time series;(d)ACF
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    Dynamic distributions of output characteristics of chaotic semiconductor lasers change with current and temperature. (a) Bandwidth; (b) time delay characteristic distribution
    Fig. 7. Dynamic distributions of output characteristics of chaotic semiconductor lasers change with current and temperature. (a) Bandwidth; (b) time delay characteristic distribution
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    Current source circuit module
    Fig. 8. Current source circuit module
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    Output current stability of current source 1. (a) Output current is 20.00 mA; (b) output current is 40.00 mA
    Fig. 9. Output current stability of current source 1. (a) Output current is 20.00 mA; (b) output current is 40.00 mA
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    Output current stability of current source 2. (a) Output current is 20.00 mA; (b) output current is 40.00 mA; (c) output current is 80.00 mA; (d) output current is 100.00 mA
    Fig. 10. Output current stability of current source 2. (a) Output current is 20.00 mA; (b) output current is 40.00 mA; (c) output current is 80.00 mA; (d) output current is 100.00 mA
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    Output stability of current source 1 at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
    Fig. 11. Output stability of current source 1 at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
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    Output stability of current source 2 at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
    Fig. 12. Output stability of current source 2 at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
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    Output current linearity of current source 1 and 2. (a) Output current linearity of current source 1;
    Fig. 13. Output current linearity of current source 1 and 2. (a) Output current linearity of current source 1;
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    Output optical power stability of the chaotic semiconductor laser. (a) Test results driven by current source 1; (b) test results driven by current source 2
    Fig. 14. Output optical power stability of the chaotic semiconductor laser. (a) Test results driven by current source 1; (b) test results driven by current source 2
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    Output optical spectrum of chaotic semiconductor laser driven by developed current source.(a) Test results driven by current source 1; (b) test results driven by current source 2
    Fig. 15. Output optical spectrum of chaotic semiconductor laser driven by developed current source.(a) Test results driven by current source 1; (b) test results driven by current source 2
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    Temperature control circuit module
    Fig. 16. Temperature control circuit module
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    Output wavelength tuning of chaotic laser from 18.0 ℃ to 40.0 ℃
    Fig. 17. Output wavelength tuning of chaotic laser from 18.0 ℃ to 40.0 ℃
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    Output wavelength tuning of chaotic laser from 24.0 ℃ to 25.0 ℃
    Fig. 18. Output wavelength tuning of chaotic laser from 24.0 ℃ to 25.0 ℃
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    Laser temperature fluctuation and central wavelength drift at 25.0 ℃. (a) Temperature fluctuation;
    Fig. 19. Laser temperature fluctuation and central wavelength drift at 25.0 ℃. (a) Temperature fluctuation;
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    Laser temperature fluctuation at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
    Fig. 20. Laser temperature fluctuation at different ambient temperatures. (a) Ambient temperature is 10.0 ℃; (b) ambient temperature is 20.0 ℃; (c) ambient temperature is 30.0 ℃; (d) ambient temperature is 40.0 ℃
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    Rapid temperature regulation results based on fuzzy adaptive PID algorithm. (a) Rapid adjustment result of temperature from 18.0 ℃ to 25.0 ℃; (b) rapid adjustment result of temperature from 40.0 ℃ to 25.0 ℃
    Fig. 21. Rapid temperature regulation results based on fuzzy adaptive PID algorithm. (a) Rapid adjustment result of temperature from 18.0 ℃ to 25.0 ℃; (b) rapid adjustment result of temperature from 40.0 ℃ to 25.0 ℃
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    Wenmin Xu, Qiang Yang, Xing Wang, Mengmeng Chai, Mingjiang Zhang, Jianzhong Zhang, Lijun Qiao, Tao Wang, Shaohua Gao. Design of High Stability Control System for Chaotic Semiconductor Lasers[J]. Laser & Optoelectronics Progress, 2021, 58(7): 0714008
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