• Blanckaert, K., and U. Lemmin (2006), Means of noise reduction in acoustic turbulence measurement, J. Hydraul. Res., 44(1), 317.
  • Bowlin, J. B., J. L. Spiesberger, T. F. Duda, L. F. Freitag (1992), Ocean acoustical ray-tracing software RAY, Rep. WHOI-93-10, 49 pp., Woods Hole Oceanographic Institution, Woods Hole, Mass.
  • Dushaw, B. D., and J. A. Colosi (1998), Ray tracing for ocean acoustic tomography, Tech. Rep. TM 3-98, 31 pp., Applied Physics Laboratory, University of Washington, Seattle, Wash.
  • Fujita, I., and Y. Kunita (2011), Application of aerial LSPIV to the 2002 flood of the Yodo River using a helicopter mounted high density video camera, J. Hydro-Environ. Res., 5(4), 323331.
  • Kaneko, A., G. Yuan, N. Gohda, and I. Nakano (1994), Optimum design of the ocean acoustic tomography system for the sea of Japan, J. Oceanogr., 50, 281293.
  • Kantoush, S. A., A. J. Schleiss, T. Sumi, and M. Murasaki (2011), LSPIV implementation for environmental flow in various laboratory and field cases, J. Hydro-Environ. Res., 5(4), 263276.
  • Katsnelson, B. (2011), Fundamentals of Shallow Water Acoustics, Springer, New York.
  • Kawanisi, K. (2004), Structure of turbulent flow in a shallow tidal estuary, J. Hydraul. Eng-ASCE., 130(4), 360370.
  • Kawanisi, K., M. Razaz, A. Kaneko, and S. Watanabe (2010), Long-term measurement of stream flow and salinity in a tidal river by the use of the fluvial acoustic tomography system, J. Hydrol., 380(1–2), 7481.
  • Kawanisi, K., M. Razaz, K. Ishikawa, J. Yano, and M. Soltaniasl (2012), Continuous measurement of flow rate in a shallow gravel-bed river by a new acoustic system, Water Resour. Res., 48, W05547, doi:10.1029/2012WR012064.
  • Laenen, A., and W. Smith (1983), Acoustic Systems for the Measurement of Streamflow, iv, 26 p. U.S. Dep. of the Interior, Portland, Ore.
  • Le Coz, J., G. Pierrefeu, and A. Paquier (2008), Evaluation of river discharges monitored by a fixed side-looking Doppler profiler, Water Resour. Res., 44, W00D09, doi:10.1029/2008WR006967.
  • Mccutcheon, S. C. (1981), Vertical velocity profiles in stratified flows, J. Hydrol. Eng. Div.—ASCE., 107(8), 973988.
  • Medwin, H. (1975), Speed of sound in water—Simple equation for realistic parameters, J. Acoust. Soc. Am., 58(6), 13181319.
  • Munk, W., and C. Wunsch (1979), Ocean acoustic tomography—Scheme for large-scale monitoring, Deep Sea Res., Part A, 26(2), 123161.
  • Park, J. H., and A. Kaneko (2000), Assimilation of coastal acoustic tomography data into a barotropic ocean model, Geophys. Res. Lett., 27(20), 33733376.
  • Razaz, M., and K. Kawanisi (2011), Signal post-processing for acoustic velocimeters: Detecting and replacing spikes, Meas. Sci. Technol., 22(12), 125404.
  • Razaz, M., and K. Kawanisi (2012), Turbulence characteristics in the bottom layer of a shallow tidal channel, J. Turbulence, 13, N52.
  • Ruhl, C. A., and J. B. DeRose, Sacramento Regional Wastewater Treatment Plant (Calif.), California, Department of Water Resources, and Geological Survey (U.S.) (2004), Investigation of hydroacoustic flow-monitoring alternatives at the Sacramento River at Freeport, California results of the 2002–2004 pilot study, U.S. Geol. Surv. Sci. Invest. Rep., 2004–5172.
  • Simon, M. K., J. K. Omura, and B. K. Levitt (1985), Spread Spectrum Communications Handbook, McGraw-Hill, New York.
  • Sloat, J. V., W. S. Gain, St. Johns River Water Management District (Fla.), and Geological Survey (U.S.) (1995), Application of Acoustic Velocity Meters for Gaging Discharge of Three Low-Velocity Tidal Streams in the St. Johns River Basin, Northeast Florida, iv, 26 p. U.S. Dep. of the Inter., Tallahassee, Fla.
  • Zhu, X. H., C. Z. Zhang, Q. S. Wu, A. Kaneko, X. P. Fan, and B. Li (2012), Measuring discharge in a river with tidal bores by use of the coastal acoustic tomography system, Estuarine Coast Shelf Sci., 104, 5465.