Dynamic earthquake rupture causes a mass redistribution around the fault, and the emitted propagating seismic waves are accompanied by bulk density perturbations. Both processes cause transient gravity changes before the arrival of P-waves. Such a pre-P gravity signal has been detected in previous studies on several huge earthquakes. However, the detections were limited to the signal's vertical component because of the high noise level in horizontal records. This study analyzed the dense tiltmeter array data in Japan to search for the signal's horizontal components from the 2011 Mw 9.1 Tohoku-Oki earthquake. Based on the synthetic waveforms for a realistic Earth model, we stacked the horizontal records and identified a signal that exceeded the noise level. We further performed a waveform inversion analysis to estimate the source parameters. The combination of the horizontal tiltmeter data and vertical broadband seismometer array data yielded a constraint on the earthquake's dip angle and magnitude in the ranges of 11.5°-15.3° and 8.75-8.92, respectively. Our results indicated that the analysis of the three components of the pre-P gravity signal avoids the inherent trade-off problem between the dip angle and seismic moment in determining the source mechanism of shallow earthquakes. Pre-P gravity signals opened a new observation window for earthquake sources.