Physical Wavelets (PWs) can describe the megathrust and significant earthquake (EQ) genesis processes to predict their focuses, fault movements, sizes, and rupture times up to three months in advance [1-4]. The time accuracies are within a day by real-time monitoring of the expected rupture processes.
Mathematical tool
The PWs in Fig. 1 can define the equations using cross-correlation with stochastic motion [1-4]. For example, the tool describes the 2011 Tohoku M9 EQ genesis process with the non-differentiable daily displacement time series collected at GPS stations in the subduction zone [2]. Denoting the geographic axis c by E (eastward), N (northward), and h (upward) in (E, N, h), the time series is {c}={d (c, 0 ), ., d (c, j ), .}. The j is the time in days. PWs define noise-free displacement D (c, τ), velocity V (c, τ), and acceleration A (c, τ) at time τ, as in Fig. 2a showing d (c, j) in green, D (c, τ) in red, V (c, τ) in black, and A (c, τ) in blue with parameter w = 200 and s = 300 in Fig. 1b. The V (c, τ) and A (c, τ) are in a relative scale from the graphical origin 0. The path in D (c, τ)-V (c, τ) has the upper half c-ward with positive V (c, τ). The lower half is the opposite c-ward and negative. The right half is c-ward of an offset origin. The path shows the M9 EQ genesis of 15 months, having the last 3 months of disaster prevention warning [1,2,4]. The genesis is a crustal bulge deformation process. The bulge evolved from the regular deformation of 1.5 mm/y up and 6 mm/y down on the west and east coast in Jan 2010. The initial phase S0 began with a uniformly increasing lifting force of A (h, τ)>0 on the east coast, as in Fig. 2a. The west coast of A (h, τ) > 0 followed in 6 months. By Jun 2010, the east coast lineally subsided by 2.8 mm, preparing a transition from regular deformation to a bulge-bending. A further linear subsidence of 3.1 mm started in June 2010 as S1 in Fig. 2a. The bulge-bending began pulling down the subducting oceanic plate, generating the D (E, τ) trend change in the plate motion at the 2010/07/11, as in Fig. 2b with w = 7 and s = 20. The lunar synodic tidal force loading appears as a periodic A (E, τ) of 30 days. The east coast pulling was a new external force to the tidal loading, gradually changing the amplitudes and phases of the periodic loading to the plate motion. Suppose an anomaly is a change comparable to the amplitudes of the observed fluctuations in {c} like d (E, τ) appearing in the changes in their phases and magnitudes at the trend change in Fig. 2b-2e. In that case, it will be indistinguishable from the background fluctuations. In such a case, a well-established power monitoring automatically detects the anomalous paths of D (E, τ)-V (E, τ) and D (E, τ)-A (E, τ) [1,2,4]. The power monitoring uses the kinetic energy rate change defined by PW (E, τ) = V (E, τ)×A (E, τ) > Th (threshold) with the current time j = τ + w + s as in Fig. 1b. The regular power 1 sets Th at level 2 in Fig. 2d for the unexpected [2,4].
The plate's speed reached the highest of V (E, τ) = – 0.69 mm/day on 22 Dec 2010, 3 times that on 11 Jul, as in Figs. 2b and 2e. The abnormal westward motion triggered the M7.9 EQ in the Pacific nearby the GPS station [2].
The linear upheaval of 1.2 mm on the east coast began in Nov 2010, as S2 in Fig. 2a. The upheaval decelerated V (E, τ) to zero on 25 Feb and reversed to the eastward of +0.06 mm/day on 8 Mar 2011, as in Figs. 2b and 2c. Thus, the tool could have provided the D (c, τ)-V (c, τ) path as the megathrust EQ and Tsunami real-time warning before the impending M9 EQ on 11 Mar 2011. However, there will be significant challenges to effectively informing societal decisions [2,5].
[1] Takeda, F. (2015) https://patents.google.com/patent/JP5798545B2/ja
[2] Takeda, F. (2021) https://doi.org/10.48550/arXiv.2107.02799
[3] Takeda, F. (2022) https://doi.org/10.48550/arXiv.2201.02815
[4] Takeda, F. (2022) https://doi.org/10.48550/arXiv.2208.09486
[5] https://www.epi21.org