Abstract
A hybrid multiplexing holographic velocimetry used for characterizing three-dimensional, three-component (3D–3C) flow behaviors in microscale devices was designed and tested in this paper. Derived from the concept of holographic particle image velocimetry (HPIV), a new experimental facility was realized by integrating a holographic technique with a state-of-the-art multiplexing operation based on a microPIV configuration. A photopolymer plate was adopted as an intermedium to record serial stereoscopic images in the same segment. The recorded images were retrieved by a scanning approach, and, afterwards, the distributions of particles in the fluid were analyzed. Finally, a concise cross-correlation algorithm (CCC) was used to analyze particle movement and, hence, the velocity field, which was visualized by using a chromatic technique. To verify practicability, the stereoscopic flow in a backward facing step (BFS) chamber was measured by using the new experimental setup, as well a microPIV system. The comparison indicated that the photopolymer-based velocimetry was practicable to microflow investigation; however, its accuracy needed to be improved.
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References
Arroyo PM, Andres N, Quintanilla M (2000) The development of full field interferometric methods for fluid velocimetry. Opt Laser Technol 32:535–542
Barnhart DH, Adrian RJ, Papen GC (1994) Phase conjugate holographic system for high resolution particle image velocimetry. Appl Opt 33:7159–7170
Chiu JJ, Wang DL, Chien S, Skalak R, Usami S (1998) Effects of disturbed flow on endothelial cells. J Biomech Eng 120:2–8
Chiu JJ, Chen CN, Lee PL, Yang CT, Chuang HS, Chien S, Usami S (2003) Analysis of the effect of disturbed flow on monocytic adhesion to endothelial cells. J Biomech 36:1883–1895
Chuang HS, Yang CT (2001) Micro flow measurement in a capillary with a diode laser micro-PIV. In: Proceedings of the 5th nano engineering and micro system technology workshop, Hsinchu, Taiwan, November 2001, pp 4-95–4-101
Chuang HS, Yang CT (2003) Evaluation of a micro-PIV based on a special calibration design. Technical report no. 073920029, Center for Measurement Standards, Industrial Technology Research Institute (CMS/ITRI), Taiwan
Clark KL (1973) Negations as failure, in logic and data bases. In: Gallaire H, Winker J (eds) Plenum Press, New York, pp 293–306
Coupland JM, Halliwell NA (1992) Particle image velocimetry: three-dimensional fluid velocity measurements using holographic recording and optical correlation. Appl Opt 31:1004–1008
Cuche E, Parquet P, Depeursinge C (1999) Simultaneous amplitude–contrast and quantitative phase–contrast microscopy by numerical reconstruction of Fresnel off-axis holograms. Appl Opt 38:6994–7001
Dubois F, Joannes L, Legros JC (1999) Improved three-dimensional imaging with a digital holography microscope with a source of partial spatial coherence. Appl Opt 38:7085–7094
Hinsch KD (2002) Holographic particle image velocimetry. Meas Sci Technol 13:R61–R72
Inoué S, Spring K (1997) Video microscopy: the fundamentals. Plenum Press, New York
Kawahashi M, Hirahara H (2001) A new technique of three-dimensional particle image detection by using color encoded illumination system. In: Proceedings of the 4th international symposium on particle image velocimetry (PIVOT), Göttingen, Germany, September 2001, pp 1061-1–1061-7
Ken YH, Lin SH, Hsiao YN (2003) Experimental characterization of phenanthrenequinone-doped poly(methylmethacrylate) photopolymer for volume holographic storage. Opt Eng 42(5):1390–1396
Lozano A, Kostas J, Soria J (1999) Use of holography in particle image velocimetry measurements of a swirling flow. Exp Fluids 27:251–261
Ovryn B (2000) Three-dimensional forward scattering particle image velocimetry applied to a microscopic field-of-view. Exp Fluids 29:S175–S184
Pan M, Meng H (2001) Digital in-line holographic PIV for 3D particulate flow diagnostics. In: Proceedings of the 4th international symposium on particle image velocimetry (PIVOT), Göttingen, Germany, September 2001, pp 1008-1–1008-7
Paraschis L, Sugiyama Y, Hesselink L (1999) Physical properties of volume holographic recording utilizing photo-initiated polymerization for nonvolatile digital data storage. SPIE 3802:72–83
Pu Y (2002) Holographic particle image velocimetry: from theory to practice. PhD thesis, pp 63–88
Pu Y, Meng H (2000) An advanced off-axis holographic particle image velocimetry (HPIV) system. Exp Fluids 29:184–197
Royer H (1997) Holographic and particle image velocimetry. Meas Sci Technol 8:1562–1572
Santiago JG, Wereley ST, Meinhart CD, Adrian RJ (1998) A micro particle image velocimetry system. Exp Fluids 25:316–319
Schnars U, Jüptner W (1994) Direct recording of holograms by a CCD target and numeral reconstruction. Appl Opt 33:179–181
Steenblik RA (1991) Stereoscopic process and apparatus using different deviation of different colors. US Patent no. 5002364
Waldman DA, Li H-YS, Cetin EA (1998) Holographic recording properties in thick films of ULSH-500 photopolymer. SPIE 3291:89–103
Xu W, Jericho MH, Meinertzhagen IA, Kreuzer HJ (2001) Digital in-line holography for biological applications. Proc Natl Acad Sci USA 98:11301–11305
Yang CT, Chuang HS, Chen, JY, Chiu JJ (2002) Microscopic flow behind a backward facing step—a model analysis for cell adhesion study. In: Proceedings of the 10th international symposium on flow visualization, Kyoto, Japan, August 2002, p 23
Zhang J, Tao B, Katz J (1997) Turbulent flow measurement in a square duct with hybrid holographic PIV. Exp Fluids 23:373–381
Acknowledgements
The authors are grateful for the support of the Ministry of Economic Affairs (MOEA), Taiwan. This paper also highly benefitted from the discussions with Prof. K.Y. Hsu and Prof. S.H Lin, who are faculty members of the National Chiao-Tung University, Taiwan.
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Yang, CT., Chuang, HS. Measurement of a microchamber flow by using a hybrid multiplexing holographic velocimetry. Exp Fluids 39, 385–396 (2005). https://doi.org/10.1007/s00348-005-1022-4
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DOI: https://doi.org/10.1007/s00348-005-1022-4