Two-component inner--outer scaling model for the wall-pressure spectrum at high Reynolds number

Abstract

Wall-pressure fluctuations beneath turbulent boundary layers drive noise and structural fatigue through interactions between fluid and structural modes. Conventional predictive models for the spectrum--such as the widely accepted Goody model (AIAA Journal 42 (9), 2004, 1788--1794)--fail to capture the energetic growth in the low-frequency range that occurs at high Reynolds number, while at the same time over-predicting the variance. To address these shortcomings, two semi-empirical models are proposed for the wall-pressure spectrum in canonical turbulent boundary layers, pipes and channels for friction Reynolds numbers δ+ ranging from 180 to 47 000. The models are based on consideration of two spectral components that represent the contributions to the wall pressure fluctuations from inner-scale motions and outer-scale motions. The first model expresses the pre-multiplied spectrum as the sum of two overlapping log-normal components: an inner-scaled term that is δ+-invariant and an outer-scaled term whose amplitude broadens smoothly with δ+. Calibrated against large-eddy simulations, direct numerical simulations, and recent high-δ+ pipe data, it reproduces the inner-scaled peak and the emergence of an outer-scaled peak at large δ+. The second model, developed around newly available pipe data, uses theoretical arguments to prescribe the spectral shapes of the inner and outer components. Embedding the δ+-dependence in smooth asymptotic functions yields a formulation that varies continuously with δ+ and generalises beyond the calibration range. Both models capture the full spectrum and recover the observed logarithmic growth of its variance, providing a compact, physics-informed empirical representation for more accurate engineering predictions of wall-pressure fluctuations.