The low-frequency pressure fluctuations generated by a range of roughness configurations are explored for flows of roughness Reynolds numbers over 200 and blockage ratios above 73. Two-point analysis of the pressure fluctuations reveals that surfaces with high frontal solidity, $$\lambda$$ , and/or complex shear layer interactions near the elements, have structures which persist longer than structures on the smooth wall. A low-frequency pressure spectrum scaling based on the broadband convection velocity defect, $$U_{\text{e}}-{\overline{U}}_{\text{c}_{\text{b}}}$$ , is proven effective for all rough surfaces and the smooth wall. Here $$U_{\text{e}}$$ is the boundary layer edge velocity, and $${\overline{U}}_{\text{c}_{\text{b}}}$$ is the mean broadband convection velocity. A second scaling, which is more appropriate for a priori predictions, is also proposed. It uses the mean velocity defect, $$U_{\text{e}}-{\overline{U}}$$ (where $${\overline{U}}$$ is the mean boundary layer velocity), first proposed for velocity profiles by Zagarola and Smits (J Fluid Mech 373:33–79, 1998). Both scalings are effective because they are based on velocity defects proportional to the outer-layer shear stress which generates the pressure fluctuations. A re-examination of the outer-layer wall-similarity in the context of these new findings suggests that this concept is limited to a narrow range of turbulent boundary layer flows.

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