Abstract
A new method of measuring the slopes of a water surface covered with short waves is developed. A camera is placed far above the water surface looking downward so that it receives only approximately vertical rays of light emerging from the water surface from a source below. A large lens is positioned horizontally underwater. A plane light source in the form of a translucent colored screen is placed horizontally in the focal plane below this lens. Corresponding to each value of water surface slope, regardless of observer position, there is one and only one point of origin on the color screen from which light rays can enter the camera. When the color screen has a suitable two-dimensional color pattern, we are able to detect the gradient of the surface elevation throughout the field of view of the camera. This refraction slope detector has been used to find statistical properties of short wind waves in a wind-wave channel where a broad angular beam width of capillary ripples and short gravity waves contribute to the surface slopes. In these experiments waves were generated by winds ranging from 5 m/s to 10 m/s at a fetch of 24 m. The wavenumber spectra of short wave slopes have two distinguishing features: a dip at the capillary-gravity transition and steep slopes in the capillary range. Surface shapes resembling the shape of solitary capillary-gravity waves have been found from profiles of wave elevation deduced by integration of the elevation gradient.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Banner ML et al. (1989) Wavenumber spectra of short gravity waves. J Fluid Mech 198: 321–344
Barber NF (1949) A diffraction analysis of a photograph of the sea. Nature 164: 485
Crapper GD (1957) An exact solution for progressive capillary waves of arbitrary amplitude. J Fluid Mech 2(6): 532–540
Cox CS (1958) Measurement of slopes of high-frequency wind waves. J Marine Res 16, No 3: 199–225
Cox CS; Munk W (1954) Statistics of the sea surface derived from sun glitter. J Mar Res 13: 198–227
Dabiri D; Gharib M (1991) Digital particle image thermometry: The method and implementation. Exp Fluids 11: 77–96
Ebuchi N; Kawamura H; Toba Y (1987) Fine structure of laboratory wind-wave surfaces studies using an optical method. Boundary-Layer Meteology 39: 133–151
Hara T; Bock EJ; Lyzeuga G, In situ measurements of capillary-gravity wave spectra using a scanning laser slope gauge and microwave radars. In press J Geophys Res
Holthuijsen LH (1983) Stereophotography of ocean waves. Appl Ocean Res 5: 204–209
Jahne B; Wass S (1989) Optical measuring technique for small scale water surface waves, Advanced Optical Instrumentation for Remote Sensing of the Earth's Surface, SPIE conference proceedings 1129, pp. 122–128, Washington
Jahne B; Riemer Klaus S (1990) Two-dimensional wave number spectra of small-scale water surface waves. J Geophys Res v. 95, No. c7: 11531–11546
Kasevich RS (1975) Directional wave spectra from daylight scattering. J Geophys Res Vol. 80, No. 33: 4535–4541.
Keller W; Gotwols BL (1983) Two-dimensional optical measurement of wave slope. Appl Opt 22: 3476–3478
Longuet-Higgins MS (1960) Reflection and refraction at a random moving surface. I. Pattern and paths of specular points. J of the Optical Society of America: Vol 50, No. 9, 838–844
Longuet-Higgins MS (1989) Capillary-gravity waves of solitary type on deep water. J Fluid Mech 200: 451–478
Lubard SC et al. (1980) Optical image and laser slope meter intercomparisons of high-frequency waves. J Geophys Res v 85, No. c9: 4996–5002
Schooley AH (1954) A simple optical method for measuring the statistical distribution of water surface slopes. J of the Optical Society of America, Vol 44, No. 1: 37–40
Slepian D (1964) Prolate spheroidal wave functions, Fourier analysis and uncertainty — IV: Extensions to many dimensions; generalized prolate spheroidal functions. Bell Sys Tech J, 43, Nov., 3009–3057
Stilwell D (1969) Directional energy spectra of the sea from photographs. J Geophys Res 74: 1974–1986
Tober G; Anderson RC; Shemdin OH (1973) Laser instrument for detecting water ripple slopes. Appl Opt, 12(4): 788–794
Wu J et al. (1969) A multiple Purpose optical instrument for studies of short water waves. The review of scientific instrument, vol 40, No. 9:1209–1214
Author information
Authors and Affiliations
Additional information
We are especially grateful for the advice of Dr. M. Gharib on the use of the HSI color system. John Lyons provided expert help in the laboratory and materials for and advice on photography. We thank the staff of the SIO Hydraulics Laboratory for making the wind-wave channel available for our use, and the staff of UCSD library for enabling us to use the Barneyscanner photometer-digitizer. We thank an anonymous reviewer who pointed out a numerical error and improved the clarity of the text.
Rights and permissions
About this article
Cite this article
Zhang, X., Cox, C.S. Measuring the two-dimensional structure of a wavy water surface optically: A surface gradient detector. Experiments in Fluids 17, 225–237 (1994). https://doi.org/10.1007/BF00203041
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00203041