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    Journals >Acta Optica Sinica >Volume 43 >Issue 5 >Page 0513001 > Article
    • Acta Optica Sinica
    • Vol. 43, Issue 5, 0513001 (2023)
    Design and Analysis of Spectral Signal Acquisition System Based on Ultra-High Q Factor Optical Microcavity
    Ruitao Cai1, Mengyu Wang1、*, Yating Li1, Zhuang Guo1, Hailin Zhang1, Chengfeng Xie1、**, Lei Zhang2, Tao Wu1, and Yanjun Fu1
    Author Affiliations
  • 1Key Laboratory of Optoelectronic Information Science and Technology of Jiangxi Province, Nanchang Hangkong University, Nanchang 330063, Jiangxi, China
  • 2Department of Precision Machinery and Precision Instruments, University of Science and Technology of China, Hefei 230026, Anhui, China
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    DOI: 10.3788/AOS221453 Cite this Article Set citation alerts
    Ruitao Cai, Mengyu Wang, Yating Li, Zhuang Guo, Hailin Zhang, Chengfeng Xie, Lei Zhang, Tao Wu, Yanjun Fu. Design and Analysis of Spectral Signal Acquisition System Based on Ultra-High Q Factor Optical Microcavity[J]. Acta Optica Sinica, 2023, 43(5): 0513001 Copy Citation Text show less
    Overall program design of optical micro-cavity spectral signal acquisition system
    Fig. 1. Overall program design of optical micro-cavity spectral signal acquisition system
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    Architecture of DAQ-2204
    Fig. 2. Architecture of DAQ-2204
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    Overall software architecture of optical micro-cavity spectral signal acquisition system
    Fig. 3. Overall software architecture of optical micro-cavity spectral signal acquisition system
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    Acquisition workflow chart of optical micro-cavity spectral signal acquisition system
    Fig. 4. Acquisition workflow chart of optical micro-cavity spectral signal acquisition system
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    Basic function test results of optical micro-cavity spectral signal acquisition system. (a) Triangular wave acquired under RSE;(b) triangular wave acquired under NRSE; (c) triangular wave acquired under differential
    Fig. 5. Basic function test results of optical micro-cavity spectral signal acquisition system. (a) Triangular wave acquired under RSE;(b) triangular wave acquired under NRSE; (c) triangular wave acquired under differential
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    Stability test results of acquisition system. (a) Wave peak value as a function of time; (b) Allan variance of wave peak value varying with time
    Fig. 6. Stability test results of acquisition system. (a) Wave peak value as a function of time; (b) Allan variance of wave peak value varying with time
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    Experimental system of optical micro-cavity spectral signal acquisition
    Fig. 7. Experimental system of optical micro-cavity spectral signal acquisition
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    Results of spectral signal acquisition of fiber microsphere cavity. (a) Transmission spectrum of microsphere cavity; (b) top view of microsphere cavity when it is coupled; (c) first-order radial and first-order angular electric field pattern in meridional plane of microsphere cavity; (d) second-order radial and second-order angular electric field pattern in meridional plane of microsphere cavity; (e) Lorenz fit of mode which is pointed to with arrow in Fig. 8(a); (f) waveform frequency drift curve at lowest point of mode in Fig. 8(e)
    Fig. 8. Results of spectral signal acquisition of fiber microsphere cavity. (a) Transmission spectrum of microsphere cavity; (b) top view of microsphere cavity when it is coupled; (c) first-order radial and first-order angular electric field pattern in meridional plane of microsphere cavity; (d) second-order radial and second-order angular electric field pattern in meridional plane of microsphere cavity; (e) Lorenz fit of mode which is pointed to with arrow in Fig. 8(a); (f) waveform frequency drift curve at lowest point of mode in Fig. 8(e)
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    Results of experimental comparison. (a) Side view of silica microdisk cavity; (b) surface view of microdisk cavity under high magnification microscope; (c) internal mode distribution of microdisk cavity; (d) transmittance spectrum acquired by oscilloscope; (e)(f) Q-value analysis of transmission spectra acquired by oscilloscope; (g) transmission spectrum acquired by acquisition system; (h)(i) Q-factor analysis of transmission spectra collected by acquisition system
    Fig. 9. Results of experimental comparison. (a) Side view of silica microdisk cavity; (b) surface view of microdisk cavity under high magnification microscope; (c) internal mode distribution of microdisk cavity; (d) transmittance spectrum acquired by oscilloscope; (e)(f) Q-value analysis of transmission spectra acquired by oscilloscope; (g) transmission spectrum acquired by acquisition system; (h)(i) Q-factor analysis of transmission spectra collected by acquisition system
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    Ruitao Cai, Mengyu Wang, Yating Li, Zhuang Guo, Hailin Zhang, Chengfeng Xie, Lei Zhang, Tao Wu, Yanjun Fu. Design and Analysis of Spectral Signal Acquisition System Based on Ultra-High Q Factor Optical Microcavity[J]. Acta Optica Sinica, 2023, 43(5): 0513001
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    Paper Information
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