William L. Keith scite author profile

Turbulent boundary layer wall-pressure spectra from various experimental investigations and a recent numerical simulation are presented. The spectra are compared in nondimensional form with three commonly used scaling laws. Attenuations resulting from inadequate sensor spatial resolution are shown to be of primary importance at the higher frequencies. The dependence of the scaling laws on momentum thickness Reynolds number is discussed. The ratio of the outer to the inner boundary layer length scale is shown to provide insight into the observed trends in the spectra.

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Measurements and scaling of wall shear stress fluctuations

Colella

Keith

2003

Experiments in Fluids

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1?1 and 2?1 phase entrainment in a system of two coupled limit cycle oscillators

Keith

Rand

1984

J. Math. Biology

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Direct Measurements of Turbulent Boundary Layer Wall Pressure Wavenumber-Frequency Spectra

Abraham

Keith

1998

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Direct measurements of streamwise wavenumber-frequency spectra of turbulent wall pressure fluctuations were made in an acoustically quiet water tunnel. A linear array of evenly spaced flush mounted pressure sensors was used to measure the wall pressure field at 48 streamwise locations. This array provided over 24 dB of resolution (sidelobe rejection) in the wavenumber domain, leading to an accurate estimate of the “convective ridge” and part of the subconvective and low wavenumber portions of the spectrum at discrete frequencies. Boundary layer parameters, including the mean wall shear stress, boundary layer thickness, displacement thickness, and momentum thickness, were derived from mean streamwise velocity measurements for 8100 < Rθ < 16,700. Time and length scales derived from these parameters were used to nondimensionalize the measured spectra. The effectiveness of different scalings for nondimensionalizing the low and convective wavenumber regions at discrete frequencies was evaluated.

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High Reynolds number thick axisymmetric turbulent boundary layer measurements

Cipolla

Keith

2003

Experiments in Fluids

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William L. Keith

A Comparison of Turbulent Boundary Layer Wall-Pressure Spectra

Measurements and scaling of wall shear stress fluctuations

1?1 and 2?1 phase entrainment in a system of two coupled limit cycle oscillators

Direct Measurements of Turbulent Boundary Layer Wall Pressure Wavenumber-Frequency Spectra

High Reynolds number thick axisymmetric turbulent boundary layer measurements

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