For several decades, pressure changes associated with tsunami generation have been observed in the case of large earthquakes, and the research on this phenomenon has been conducted. Past studies have reported that this change in atmospheric pressure (infrasound) is induced by the generation of a tsunami. Since infrasound propagates at a speed faster than that of a tsunami, it is expected to be applied to early detection of tsunamis. In other words, using infrasound as one of the observation targets for tsunami detection makes it possible to further improve the robustness and stability of tsunami detection. However, for this phenomenon, detailed numerical analysis considering the effects of wave sources and atmospheric environment based on actual physical phenomena has not been sufficiently studied. According to the frequency of tsunami occurrence, it is important to establish a highly reproducible numerical analysis method. Therefore, in this study, we implemented a three-dimensional large-scale propagation numerical analysis considering the wave source and atmospheric model, and numerically examined the infrasound induced by the tsunami. In this numerical experiment, tsunami-induced infrasound was compared and evaluated by removing the background atmospheric pressure trend from the observation results of the 2011 off the Pacific coast of Tohoku Earthquake. Through this research, it was clarified that a waveform close to the infrasound obtained in the field observation can be reproduced by numerical analysis employing the wave source and atmospheric environment models.