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Salvus excels in the large-scale computation of fully 3-D wavefields in realistic and complicated environments. In this use case, Salvus was used to investigate the character of vibrational strain signals recorded along an ocean bottom fiber-optic cable. High resolution surface and seabed topography, along with the accurate coupling of both viscoelastic and acoustic wavefields, are automatically included using our simple Python-based interface. Simulations such as these help researchers investigate new and exciting applications of distributed acoustic sensing (DAS). The following illustration highlights a few of the complexities Salvus handles - click on it to see a video of these waves propagating. All this readily scales from running on laptops, to GPU clusters all the way to big machines with thousands of cores. The simulation rendered above took less than a few minutes to run on a single GPU.
In seismology, advanced numerical methods model the propagation of seismic waves in realistic geological media.
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This case study shows the usage of Salvus for illustrating how different levels of attenuation in realistic materials influence the signals generated by material defects, thereby influencing the limits of detection.
