REGARD: A new GNSS‐based real‐time finite fault modeling system for GEONET

Kawamoto, Satoshi; Ohta, Yusaku; Hiyama, Yohei; Todoriki, Masaru; Nishimura, Takuya; Furuya, Tomoaki; Sato, Yoichi; Yahagi, Toshihiro; Miyagawa, Kohei

doi:10.1002/2016jb013485

Cited by 62 publications

(46 citation statements)

References 95 publications

(157 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…A difference between seismic and geodetic early warning is that the GNSS observation can measure oscillations with lower frequencies and also permanent displacements. As a result, underestimating the earthquake size is less likely with the GNSS measurements [e.g., Blewitt et al , ; Ohta et al , ; Kawamoto et al , ] than using only seismograms, which, particular for short‐period seismograms, often underestimate the size of earthquakes with magnitude 8 or larger [e.g., Melgar et al , ]. In the case of the 2011 Tohoku‐oki earthquake ( M w =9.0), an immediate estimate of the magnitude using local short‐period seismograms only was M = 7.9, well below the actual size, leading to substantial underestimation of tsunami height and risk [ Ozaki , ].…”

Section: Early Warning and Quick Response To Earthquakes And Tsunamismentioning

confidence: 99%

Space geodetic tools provide early warnings for earthquakes and volcanic eruptions

Aoki

2017

JGR Solid Earth

View full text Add to dashboard Cite

Development of space geodetic techniques such as Global Navigation Satellite System and Synthetic Aperture Radar in last few decades allows us to monitor deformation of Earth's surface in unprecedented spatial and temporal resolution. These observations, combined with fast data transmission and quick data processing, enable us to quickly detect and locate earthquakes and volcanic eruptions and assess potential hazards such as strong earthquake shaking, tsunamis, and volcanic eruptions. These techniques thus are key parts of early warning systems, help identify some hazards before a cataclysmic event, and improve the response to the consequent damage.

show abstract

Section: Early Warning and Quick Response To Earthquakes And Tsunamismentioning

confidence: 99%

Space geodetic tools provide early warnings for earthquakes and volcanic eruptions

Aoki

2017

JGR Solid Earth

View full text Add to dashboard Cite

show abstract

“…So far, many aforementioned GNSS approaches and related publications are based on post-event processed data and implementation. To our knowledge, real-time inversion of earthquakes just using GNSS is only feasible in regions where there is a dense GNSS network (Kawamoto et al 2016(Kawamoto et al , 2017, while a global GNSS-based earthquake source inversion system has never been reported except post-event demonstration in simulated environment.…”

Section: Introductionmentioning

confidence: 99%

Automated GNSS and Teleseismic Earthquake Inversion (AutoQuake Inversion) for Tsunami Early Warning: Retrospective and Real-Time Results

Chen

Liu

Song

2019

Pure Appl. Geophys.

View full text Add to dashboard Cite

Rapid finite fault source determination is critical for reliable and robust tsunami early warnings. Near-field Global Navigation Satellite System (GNSS) observations have shown value to constrain the source inversion, but real-time GNSS stations are sparse along most of the active faults. Here we propose an automatic earthquake finite source inversion (AutoQuake Inversion) algorithm jointly using near-field (epicentral distance \ 1000 km) GNSS data and mid-range (epicentral distance from 30°to 45°) teleseismic P displacement waveforms. Neither the near-field GNSS nor the mid-range teleseismic data clip or saturate during large earthquakes, while the fast-traveling P-waves are still essential to constrain the source in regions where very few or no GNSS stations are available. Real-time determination of the fault geometry remains to be the main challenge for rapid finite source inversion. We adopt a strategy to use the predefined geometry Slab2 for earthquakes within it or to forecast a focal mechanism based on nearby historical events for earthquakes without Slab2 prior. The algorithm has been implemented successfully in the prototype of JPL's GPS-Aided Tsunami Early-Detection system and tested for many real events recently. This article provides the framework of the algorithm, documents the retrospective and real-time results, and discusses remaining challenges for future improvements.

show abstract

“…However, these methods estimate a point source that may be indirectly related to tsunamis, and are somehow difficult to accurately constrain the tsunami source dimension particularly for great earthquakes (Katsumata et al 2013;Hoshiba and Ozaki 2014). Earthquake-source estimation using Global Positioning System/Global Navigation Satellite System (GPS/GNSS) observations of land deformation will suitably constrain the source dimension with moment magnitude of nearshore (< 100 km from the coast) earthquakes (Melgar and Bock 2015;Kawamoto et al 2017). For greater earthquakes (M w > 8.5), in addition to the fault slip, seafloor failure due to strong ground motion likely causes a certain portion of tsunami (Kawamura et al 2014;Løvholt et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Measuring offshore tsunami currents using ship navigation records

Inazu

Ikeya

Waseda

et al. 2018

Prog Earth Planet Sci

View full text Add to dashboard Cite

We investigated ship navigation records known as Automatic Identification System (AIS) data near the source region of the 2011 Tohoku, Japan, tsunami. The AIS data of 16 ships in the offshore navigation could be compiled by about 40 min after the tsunami generation. Most of the AIS data showed notable deviation of the ship heading from the course over ground during the tsunami passage. There was good agreement in terms of amplitude/phase between the ship velocity and the simulated tsunami velocity in the direction normal to the ship heading. An equation of motion due to wave drag and inertia forces was examined for an offshore movable floating body. We explain that the ship movement in the direction normal to the heading immediately responds to the tsunami current, and relative velocity between the ship and the tsunami current asymptotically become zero. This indicates the movement velocity of navigating ships in the direction normal to the heading derived from AIS data will work as an offshore tsunami current meter. We examined the AIS data during the 2011 Tohoku tsunami and showed these data could be useful for tsunami source estimation and forecast. The AIS data in the current framework will possibly be a crowd-sourced tool for monitoring offshore tsunami current and tsunami forecast.

show abstract

REGARD: A new GNSS‐based real‐time finite fault modeling system for GEONET

Cited by 62 publications

References 95 publications

Space geodetic tools provide early warnings for earthquakes and volcanic eruptions

Space geodetic tools provide early warnings for earthquakes and volcanic eruptions

Automated GNSS and Teleseismic Earthquake Inversion (AutoQuake Inversion) for Tsunami Early Warning: Retrospective and Real-Time Results

Measuring offshore tsunami currents using ship navigation records

Contact Info

Product

Resources

About