Discharge estimation from surface-velocity observations by a maximum-entropy based method
Antonis D. Koussis, Panayiotis Dimitriadis, S. Lykoudis, Nikolaos Kappos, Dimitrios Katsanos, Ioannis Koletsis, Βasil E. Psiloglou, Evangelos Rozos, Katerina Mazi
Abstract
We develop a maximum-entropy method for streamflow estimation from surface velocities. Entropy maximization, with mean and variance constraints, yields a mass and momentum conserving, error-function-type velocity profile. That sigmoidal profile’s infinite branch shapes the hydrometrically critical free-surface region unphysically, so we derive approximate relationships of the ratio of the mean velocity V to the surface velocity vsurf, fv=V/vsurf, as function of β=Ev2/V2 (E = expectation); β is tightly estimable: β ≈ 1.01–1.15, fv ≈ 0.9–0.72. fv(β) is adaptable to the site geometry and roughness (i.e. to the local hydraulics, instead of the default fv = 0.86), improving the parsimonious discharge estimation from surface velocities. Laboratory data verify the concept. Tests at cross-sections of streams, with known variable bathymetry and roughness, demonstrate the method’s ability to estimate the discharge solely from surface-velocity observations, with ± 5% accuracy referenced to discharge determined from densely sampled in-stream velocities.