Spectral analyses of seismic waveforms have been used to estimate source parameters of earthquakes (corner frequency and stress drop) and medium heterogeneity (direct and coda attenuation). However, we often have a strong tradeoff, for example, between corner frequency and attenuation because both parameters control the high-frequency fall-off of each spectrum. We developed a new method to avoid the trade-off using two-step approaches and was able to estimate seismic attenuation with high resolution in space and time (Nakajima et al., JGR, 2013; Nakajima and Uchida, Nature Geoscience, 2018). In this talk, we will present two spectral analysis methods and show that they were able to reveal high-resolution 3D seismic attenuation model and temporal variation in attenuation. The former method will improve our understanding sub-surface attenuation structures associated with magmatism and fault heterogeneity, while the latter one will highlight the migration of fluids along the megathrust boundary and immediately below active volcanoes.