Flow-induced noise is a significant problem for air, road and marine vehicles as well as many other engineering applications. At low Mach numbers, large disparities in energy levels and length scales between the flow and the concomitant sound present unique challenges for acoustic predictions. This talk will start with a brief overview of computational methods for low-Mach-number flow-noise based on Lighthill’s theory and high-fidelity flow simulations, followed by a discussion of recent investigations of several aeroacoustic problems involving airframe and propeller noise. A study of rotor interaction with an axisymmetric turbulent boundary layer (TBL) at the tail-end of a body of revolution (BOR) will be highlighted. The TBL on the nose and midsection of the BOR is computed using wall-modeled LES whereas that in the acoustically important tail-cone section is wall resolved. This approach is shown to predict the turbulence statistics and sound-pressure spectra well compared with experimental data. Correlation and spectral analyses demonstrate rapidly growing turbulence structures in the decelerating tail-cone TBL whose interaction with successive rotor blades generates spectral humps and valleys in the broadband sound pressure spectra. The spatial and frequency characteristics of blade acoustic dipole sources will be discussed in relation to the turbulence properties of the boundary layer.