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Laser anemometry: a report on EUROMECH 36

Published online by Cambridge University Press:  29 March 2006

F. Durst ,
A. Melling  and
J. H. Whitelaw
F. Durst
Affiliation:
Department of Mechanical Engineering, Imperial College, London Present address; Sonderforschungsbereich 80, University of Karlsruhe.
A. Melling
Affiliation:
Department of Mechanical Engineering, Imperial College, London
J. H. Whitelaw
Affiliation:
Department of Mechanical Engineering, Imperial College, London
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Abstract

The 36th European Mechanics Colloquium (EUROMECH 36) which was held at Imperial College from 17 to 19 April 1972 was the first to be devoted to laser anemometry. It brought together European researchers whose primary interests included physics, electronics and fluid mechanics with the following purposes.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 56 , Issue 1 , 14 November 1972 , pp. 143 - 160
Copyright
© 1972 Cambridge University Press

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References

Adrian, R. J. & Goldstein, R. J. 1971 Analysis of a laser-Doppler anemometer. J. Phys. E, Sci. Instrum. 4, 505.Google Scholar
Anderson, R. E., Edlund, C. E. & Vanzant, B. W. 1971 Measurement of particle velocity at a shock front in water with a laser-Doppler meter. J. Appl. Phys. 42, 2741.Google Scholar
Angus, J. C., Morrow, D. L., Dunning, J. W. & French, M. J. 1969 Motion measurement by laser-Doppler techniques. Ind. Engng Chem. 61 (2), 9.Google Scholar
Baker, R. J. Optical frequency shifting devices for directionally sensitive laser-Doppler anemometers.
Baker, R. J., Bourpe, P. J. & Whitelaw, J. H. 1971 Measurements of instantaneous velocity in laminar and turbulent diffusion flames using an optical anemometer. Imperial College, Mech. Engng Dept. Rep. ET/TN/A/11 (to be published in J. Inst. Fuel).Google Scholar
Bertolotti, M., Crosignani, B., Daino, B. & Di Porto, P. 1971 The possibility of measuring spatial velocity correlation functions in a turbulent fluid by means of light scattering. J. Phys. A 4, L47.Google Scholar
Blake, K. A. The NEL laser velocimeter.
Blake, K. A. & Jesperson, K. I. 1972 The NEL laser velocimeter. NEL Rep. no. 510.Google Scholar
Bossel, H. H., Hiller, W. J. & Meier, G. E. A. Noise cancelling, self-aligning optical anemometers for multi-dimensional velocity measurements.
Bossel, H. H., Hiller, W. J. & Meier, G. E. A. 1972a Noise-cancelling signal difference method for optical velocity measurements. J. Phys. E, Sci. Instrum. to be published.Google Scholar
Bossel, H. H., Hiller, W. J. & Meier, G. E. A. 1972b Self-aligning comparison beam methods for one-, two- and three-dimensional optical velocity measurements. J. Phys. E, Sci. Instrum. to be published.Google Scholar
Bourke, P. J., Brown, C. G. & Drain, L. E. 1971 Measurements of Reynolds shear stress in water by laser anemometry. Disa Inf. 12, 21.Google Scholar
Bourke, P. J., Drain, L. E. & Moss, B. C. 1971 Measurements of spatial and temporal correlations of turbulence in water by laser anemometry. Disa Inf. 12, 17.Google Scholar
Bourquin, K. R. & Shigemoto, F. H. 1968 Investigation of air velocity by laser back-scatter. N.A.X.A. Tech. Note, D-4453.Google Scholar
Boutier, A. Design of an interferential velocimeter; application to gas and liquid flows.
Brayton, D. B., Kalb, H. T. & Crosswy, F. L. 1972 A two-component, dual-scatter laser-Doppler velocimeter with frequency burst signal readout. A.E.D.C. Rep. (submitted to Appl. Optics).Google Scholar
Cumxins, H. Z. & Knable, N. 1963 Single sideband modulation of coherent light by Bragg reflexion from acoustical waves. Proc. I.E.E.E. 51, 1246.Google Scholar
Davies, C. N. 1966 Aerosol Science. Academic.
Deighton, M. O. Design principles of a frequency tracker for laser anemometry.
Deighton, M. O. & Sayle, E. A. 1971 An electronic tracker for the continuous measurement of Doppler frequency from a laser anemometer. Disa Inf. 12, 5.Google Scholar
Denison, E. B. & Stevenson, W. H. 1970 Oscillatory flow measurements with a directionally sensitive laser velocimeter. Rev. Sci. Instrum. 41, 1475.Google Scholar
Denison, E. B., Stevenson, W. H. & Fox, R. W. 1971 Pulsating laminar flow measurements with a directionally sensitive laser velocimeter. A.I.Ch.E.J. 17, 781.Google Scholar
Di Porto, P., Crosignani, B. & Bertolotti, M. 1969 Statistical properties of light scattered by particles suspended in a turbulent fluid. J. Appl. Phys. 40, 5083.Google Scholar
Drain, L. E. Principles and practice of optical systems.
Drain, L. E. 1972 Coherent and noncoherent methods in Doppler optical beat velocity measurement. J. Phys. D5, 481.Google Scholar
Durxo, D. Optical measurements of instantaneous velocity in diffusion flames.
Durxo, D., Durst, F. & Whitelaw, J. H. 1972 Optical measurements in a pulsating flame. Imperial College, Mech. Engng Dept. Rep. ET/TN/A/14.Google Scholar
Durst, F. Scattering phenomena and their application in optical anemometry.
Durst, F. The application of optical anemometers.
Durst, F., Melling, A. & Whitelaw, J. H. 1972a The application of optical anemometry to measurement in combustion systems. Comb. & Flame, 18, 197.Google Scholar
Durst, F., Melling, A. & Whitelaw, J. H. 1972b Optical anemometer measurements in recirculating flows and flames. Disa Conf. on Fluid Dyn. Measurements in Indust. & Medical Environments. Paper, 11. 22.Google Scholar
Durst, F. & Whitelaw, J. H. 1971a Integrated optical units for laser anemometry. J. Phys. E. Sci. Instrum. 4, 804.Google Scholar
Durst, F. & Whitelaw, J. H. 1971b Measurements of mean velocity, fluctuating velocity, and shear stress using a single channel anemometer. Disa Inf. 12, 11.Google Scholar
Durst, F. & Whitelaw, J. H. 1971c Optimization of optical anemometers. Proc. Roy. Soc. A 324, 157.Google Scholar
Durst, F. Whitelaw, J. H. 1972 Theoretical considerations of significance to the design of optical anemometers. Imperial College, Mech. Eng. Dept. Rep. ET/TN/A/15.Google Scholar
Edwards, R. V., Angus, J. C., French, M. J. & Dunning, J. W. 1971 Spectral analysis of the signal from the laser-Doppler flow meter: time-independent systems. J. Appl. Phys. 42, 837.Google Scholar
Eliasson, B., Iten, P. & Dandliker, R. Analysis of Doppler flowmeters.
Foreman, J. W. 1967 Optical path length difference effects in photomixing with multimode gas laser radiation. Appl. Optics, 6, 821.Google Scholar
Fridhan, J. D., Huffaker, R. M. & Kinnard, R. F. 1968 Laser-Doppler system measures three-dimensional velocity vector and turbulence. Laser Focus, 4, 34.Google Scholar
Fristrom, R. M., Jones, A. R., Schwar, M. J. R. & Weinberg, F. J. Particle sizing by interference fringes.
George, W. K. & Lumley, J. L. 1971 The measurement of turbulence using a laser-Doppler velocimeter. I.S.A. Symp. on Plow. Paper, no. 5-2-58 (Pittsburgh).Google Scholar
Gillespie, A. B. The remote measurement of wind velocity and gustiness using back-scattered laser light.
Goldstein, R. J. & Hagen, W. F. Turbulent flow measurements utilizing the Doppler shift of scattered laser radiation. Phys. Fluids, 10, 1349.
Goldstein, R. J. & Kreid, D. K. 1971 Measurement of velocity proses in simulated blood by the laser-Doppler technique. I.S.A. Symp. on Flow. Paper, no. 4-2-95 (Pittsburgh).Google Scholar
Greated, C. Comparison of laser and hot-film anemometers for the measurement of turbulence statistics.
Greated, C. 1971 Resolution and back-scattering optic geometry of laser-Doppler systems. J. Phys. E 4, 585.Google Scholar
Green, H. L. & Lane, W. R. 1964 Particulate Clouds: Dusts, Smokes, and Mists. 2nd edn. London: E. & F. N. Spon.
Griverus, B. Measurement of velocity distribution in a two-dimensional jet at small Reynolds number flow.
Huffaker, R. M. 1970 Laser-Doppler detection systems for gas velocity measurement. Appl. Optics, 9, 1026.Google Scholar
Huffaicer, R. M., Fuller, C. E. & Lawrence, T. R. 1969 Application of laser-Doppler velocity instrumentation to the measurement of jet turbulence. S.A.E. Conference, Detroit.
Hughes, A. J. Long range anemometry using a CO2 laser.
Hughes, A. J., Jones, R., Pike, E. R. & O'Shaughnessy, J. 1972 CO2 laser anemometry in the atmosphere. RRE Newsletter & Res. Rev. 11, paper 16.Google Scholar
Hughes, A. J., Oliver, C. J., Pike, E. R. & Shaughnessy, J. 1970 Measurement of wind velocity by laser scattering. RRE Newsletter & Res. Rev. 9, paper 7.Google Scholar
Iten, P. D. Principles and practice of signal analysis.
Iten, P. D., Eliasson, B., Dandliker, R. 1971 Investigations and improvement of spectral and spatial resolution of a laser Doppler flowmeter. Ieee/ISO Conference on Laser Engineering and Applications, Washington (to be published in Appl. Optics).
Iten, P. D. & Mastner, J. 1971 A laser-Doppler velocimeter offering high spatial and temporal resolution. Brown Boveri Res. Rep. KLR-7107.Google Scholar
Jackson, D. A. & Paul, D. M. 1971 Measurement of supersonic velocity and turbulence by laser anemometry. J. Phys. E. Sci. Instrum. 4, 173.Google Scholar
James, R. N., Babcock, W. R. & Seifert, H. S. 1968 A laser-Doppler technique for the measurement of particle velocity A.I.A.A.J. 6, 160.Google Scholar
Jones, A. R. See Fristrom et al.
Lading, L. Analysis of signal-to-noise ratio of a laser anemometer. (See also RISØ N-Rep. N-15-72.)
Lading, L. 1971a Differential Doppler heterodyning technique. Appl. Optics, 10, 1943.Google Scholar
Lading, L. 1971b Two-phase flow measurements utilizing laser anemometry. RISØ M-reportGoogle Scholar
Lehmann, B. An experiment concerning the fringe-pattern model with regard to the two-beam dual scatter method.
Lehmann, B. 1968 Zur Diagnostik von Zweiphasen-stromungen 11. AER-Forschungsinstitut, 19, 11039.Google Scholar
Lennert, A. E., Trolinger, J. D. & Smith, F. H. 1972 Application of electro-optic techniques for jet and wake flow-field investigations. A.E.D.C. Rep.Google Scholar
Lewis, R. D., Foreman, J. W., Watson, H. J. & Thornton, J. R. 1968 Laser-Doppler velocimeter for measuring flow-velocity fluctuations. Phys. Fluids, 11, 433.Google Scholar
Mayo, W. T. 1970 Simplified laser-Doppler velocimeter optics. J. Phys. E. Sci. Instrum. 3, 235.Google Scholar
Mazumder, M. K. 1972 A symmetrical laser-Doppler velocity meter and its application to turbulence characterization. N.A.S.A. Contractor Rep. no. 2031.Google Scholar
Mazumder, M. K. & Wankum, D. L. 1970 SNR and spectral broadening in turbulence structure measurement using a CW laser. Appl. Optim, 9, 633.Google Scholar
Meier, G. E. A. See Bossel et al.
Melling, A. Doppler signal analysis with a phase-locked loop demodulator.
Melling, A. Principles and practice of particle production and measurement.
Melling, A. 1971 Scattering particles for laser anemometry in air: selection criteria and their realization. Imperial College, Dept. Mech. Engng Rep. ET/TN/B/7.Google Scholar
Meyers, J. F. 1971 Investigation of basic parameters for the application of a laser- Doppler velocimeter. A.I.A.A. Paper, no. 71-288.Google Scholar
Müller, A. Measurement of the sign of a velocity component from the phase difference of the two heterodyne signals.
Müller, A. 1970 Neue Elemente in der Technik der laser-Doppler Velocimeter. Appl. Optics, 9, 2393.Google Scholar
Oldengarm, J. Processing of signals from a laser-Doppler velocimeter.
Philbert, M. Particle velocity measurements by a photographic method using two pulsed lasers.
Pike, E. R., Jackson, D. A., Bourke, P. J. & Page, D. I. 1968 Measurement of turbulent velocities from the Doppler shift in scattered laser light. J. Phys. E, Sci. Instrum. 1, 111.Google Scholar
Raterink, H. J. Current development of a laser-Doppler anemometer a t the Institute of Applied Physics TNO-TH.
Riebold, W., Matthes, W. & Friz, G. Applications of correlation methods in two-phase flow investigations.
Rizzo, J. E. A laser-Doppler interferometer.
Rudd, M. J. 1972 Velocity measurements made with a laser doppler-meter on the turbulent pipe flow of a dilute polymer solution. J. Fluid Mech. 51, 673.Google Scholar
Schwar, M. J. R. & Weinberg, F. J. 1969 Laser techniques in combustion research. Comb. & Flame, 13, 335.Google Scholar
Testa, P. & Viti, M. Measuring and recording of rapidly variable liquid levels by means of a laser beam.
Thompson, D. H. 1968 A tracer-particle fluid velocity meter incorporating a laser. J. Phys. E, Sci. Instrum. 1, 929.Google Scholar
Vom Stein, H. D. & Pfeifer, H. J. 1972 Investigation of the velocity relaxation of micron-sized particles in shock waves using laser radiation. Appl. Optics, 11, 305.Google Scholar
Welch, N. E. & Tomme, W. J. 1967 Analysis of turbulence from data obtained with a laser velocimeter. A.I.A.A. Paper, no. 67-179.Google Scholar
Whitelaw, J. H. Integrated optical arrangements.
Wilmshurst, T. H. A real-time Doppler signal simulator incorporating velocity modulation and an autodyne tracking filter.
Wilmshurst, T. H. 1972 An autodyne signal processor for laser-Doppler anemometry. Submitted to J. Phys. E, Sci. Instrum.Google Scholar
Wilmshurst, T. H., Greated, C. & Manning, R. 1971 A laser fluid-flow velocimeter of wide dynamic range. J. Phys. E, Sci. Instrum. 4, 81.Google Scholar
Yanta, W. J. & Gates, D. F. Laser-Doppler velocimeter measurements in supersonic flow.
Yanta, W. J., Gates, D. F. & Brown, F. W. 1971 The use of a laser-Doppler velocimeter in supersonic flow. A.I.A.A. Paper, 71287.Google Scholar
Yeh, Y. & Cummins, H. Z. 1964 Localized flow measurements with an He-Ne laser spectrometer. Appl. Phys. Lett. 4, 176.Google Scholar