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http://dx.doi.org/10.3807/COPP.2021.5.2.147

A Ghost-Imaging System Based on a Microfluidic Chip  

Wang, Kaimin (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Han, Xiaoxuan (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Ye, Hualong (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Wang, Zhaorui (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Zhang, Leihong (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Hu, Jiafeng (School of Physics and Electronics, East China Normal University)
Xu, Meiyong (School of Electronic Engineering, Beijing University of Posts and Telecommunications)
Xin, Xiangjun (School of Electronic Engineering, Beijing University of Posts and Telecommunications)
Zhang, Dawei (Engineering Research Center of Optical Instrument and System, Ministry of Education and Shanghai Key Lab of Modern Optical System, University of Shanghai for Science and Technology)
Publication Information
Current Optics and Photonics / v.5, no.2, 2021 , pp. 147-154 More about this Journal
Abstract
Microfluidic chip technology is a research focus in biology, chemistry, and medicine, for example. However, microfluidic chips are rarely applied in imaging, especially in ghost imaging. Thus in this work we propose a ghost-imaging system, in which we deploy a novel microfluidic chip modulator (MCM) constructed of double-layer zigzag micro pipelines. While in traditional situations a spatial light modulator (SLM) and supporting computers are required, we can get rid of active modulation devices and computers with this proposed scheme. The corresponding simulation analysis verifies good feasibility of the scheme, which can ensure the quality of data transmission and achieve convenient, fast ghost imaging passively.
Keywords
Ghost imaging; Information reconstruction; Microfluidic chip;
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  • Reference
1 Z. Liu, S. Tan, J. Wu, E. Li, X. Shen, and S. Han, "Spectral camera based on ghost imaging via sparsity constraints," Sci. Rep. 6, 25718 (2016).   DOI
2 B. Luo, P. Yin, L. Yin, G. Wu, and H. Guo, "Orthonormalization method in ghost imaging," Opt. Express 26, 23093-23106 (2018).   DOI
3 P. A. Moreau, E. Toninelli, T. Gregory, and M. J. Padgett, "Ghost imaging using optical correlations," Laser Photonics Rev. 12, 1700143 (2018).   DOI
4 Y. Yu, C. Wang, J. Liu, J. Wang, M. Cao, D. Wei, H. Gao, and F. Li, "Ghost imaging with different frequencies through non-degenerated four-wave mixing," Opt. Express 24, 18290-18296 (2016).   DOI
5 T. Mao, Q. Chen, W. He, Y. Zou, H. Dai, and G. Gu, "Speckle-shifting ghost imaging," IEEE Photonics J. 8, 6900810 (2016).
6 K. Kuplicki, and K. W. C. Chan, "High-order ghost imaging using non-Rayleigh speckle sources," Opt. Express 24, 26766-26776 (2016).   DOI
7 D. B. Phillips, R. He, Q. Chen, G. M. Gibson, and M. J. Padgett, "Non-diffractive computational ghost imaging," Opt. Express 24, 14172-14182 (2016).   DOI
8 R. S. Bennink, S. J. Bentley, and R. W. Boyd, ""Two-photon" coincidence imaging with a classical source," Phys. Rev. Lett. 89, 113601 (2002).   DOI
9 J. Tang, D. Zou, M. Cheng, L. Deng, D. Liu, and M. Zhang, "Single-shot temporal ghost imaging based on orthogonal frequency-division multiplexing," IEEE Photonics Technol. Lett. 30, 1555-1558 (2018).   DOI
10 J. Tang, Y. Tang, K. He, L. Lu, D. Zhang, M. Cheng, L. Deng, D. Liu, and M. M. Zhang, "Computational temporal ghost imaging using intensity-only detection over a single optical fiber," IEEE Photonics J. 10, 7101809 (2018).
11 P. Ryczkowski, M. Barbier, A. T. Friberg, J. M. Dudley, and G. Genty, "Ghost imaging in the time domain," Nat. Photonics 10, 167-170 (2016).   DOI
12 Y. O-oka, and S. Fukatsu, "Differential ghost imaging in time domain," Appl. Phys. Lett. 111, 061106 (2017).   DOI
13 A. M. Paniagua-Diaz, I. Starshynov, N. Fayard, A. Goetschy, R. Pierrat, R. Carminati, and J. Bertolotti, "Blind ghost imaging," Optica 6, 460-464 (2019).   DOI
14 Y. Basati, O. R. Mohammadipour, and H. Niazmand, "Numerical and analytical analysis of a robust flow regulator in electroosmotic microfluidic networks," Chem. Eng. Sci. 210, 115232 (2019).   DOI
15 H. S. Rho, Y. Yang, L. W. M. M. Terstappen, H. Gardeniers, S. Le Gac, and P. Habibovic, "Programmable droplet-based microfluidic serial dilutor," J. Ind. Eng. Chem. 91, 231-239 (2020).   DOI
16 P. Liang, J. Ye, D. Zhang, X. Zhang, Z. Yu, and B. Lin, "Controllable droplet breakup in microfluidic devices via hydrostatic pressure," Chem. Eng. Sci. 226, 115856 (2020).   DOI
17 H. Lackey, D. Bottenus, M. Liezers, S. Shen, S. Branch, J. Katalenich, and A. Lines, "A versatile and low-cost chip-to-world interface: enabling ICP-MS characterization of isotachophoretically separated lanthanides on a microfluidic device," Anal. Chim. Acta. 1137, 11-18 (2020).   DOI
18 A. Kiss and A. Gaspar, "Fabrication of a microfluidic flame atomic emission spectrometer: a flame-on-a-chip," Anal. Chem. 90, 5995-6000 (2018).   DOI
19 D. Mark, S. Haeberle, G. Roth, F. von Stetten and R. Zengerle, "Microfluidic lab-on-a-chip platforms: requirements, characteristics and applications," Chem. Soc. Rev. 39, 1153-1182 (2010).   DOI
20 B. C. Lin, "Research and industrialization of microfluidic chip," Chin. J. Anal. Chem. 44, 491-499 (2016).
21 Z. Fang, and Q. Fang, "Developments and trends of microfluidic chip analytical systems," Mod. Sci. Instrum. 4, 3-6 (2001).
22 Z. Zhang, J. Pan, Y. Tang, Y. Xu, L. Zhang, Y. Gong, and L. Tong, "Optical micro/nanofibre embedded soft film enables multifunctional flow sensing in microfluidic chips," Lab Chip 20, 2572-2579 (2020).   DOI
23 T. Prangemeier, F.-X. Lehr, R. M. Schoeman, and H. Koeppl, "Microfluidic platforms for the dynamic characterisation of synthetic circuitry," Curr. Opin. Biotechnol. 63, 167-176 (2020).   DOI
24 M. N. Hossain, J. Justice, P. Lovera, A. O'Riordan, and B. Corbett, "Dual resonance approach to decoupling surface and bulk attributes in photonic crystal biosensor," Opt. Lett. 39, 6213-6216 (2014).   DOI
25 J. Raveendran and T. G. S. Babu, "Design and fabrication of a three layered microfluidic device for lab on a chip applications," Mater. Today: Proc. 5, 16286-16292 (2018).   DOI
26 J. Dietvorst, J. Goyvaerts, T. N. Ackermann, E. Alvarez, X. Munoz-Berbel, and A. Llobera, "Microfluidic-controlled optical router for lab on a chip," Lab Chip 19, 2081-2088 (2019).   DOI
27 T. Bian, Y. Dai, J. Hu, Z. Zheng, and L. Gao, "Ghost imaging based on asymmetric learning," Appl. Opt. 59, 9548-9552 (2020).   DOI
28 L. Zhang, Y. Hualong, and D. Zhang, "Study on the key technology of image transmission mechanism based on channel coding ghost imaging," IEEE Photonics J. 10, 6500913 (2018).
29 G. Wu, H. Mo, Z. Han, J. Li, D. Yang, and Q. Pen, "Sensitivity analysis of correspondence ghost imaging," Laser Phys. Lett. 17, 115205 (2020).   DOI
30 S. Zhao, X. Yu, L. Wang, W. Li, and B. Zheng, "Secure optical encryption based on ghost imaging with fractional Fourier transform," Opt. Commun. 474, 126086 (2020).   DOI
31 H. Wu, G. Zhao, R. Wang, H. Xiao, D. Wang, J. Liang, L. Cheng, and R. Liang, "Computational ghost imaging system with 4-connected-region-optimized Hadamard pattern sequence," Opt. Lasers Eng. 132, 106105 (2020).   DOI