The Compact Modeling of Seismo-Atmospheric Processes for the Complete Earth via Electromagnetically Equivalent Complex Network
Abstract
This research concerns itself with modeling the geo-data related to seismic and atmospheric processes as the self-optimization process of a compact electromagnetically equivalent device and developing a less accurate but fast models. The electromagnetically equivalent device model is extended as considering the whole Earth like a complete system. The crustal structures are considered as a complex network of distributed circuits involving open arrays of antennas, waveguides, cavities, transmission lines, attenuators, frequency converters, dividers, couplings in the electromagnetically equivalent device model of the complete system of Earth (EEDMCSE). The variations at the geo-data taken at any port of the EEDMCSE give some functional relationships on the electromagnetic characteristics of the distributed complex network explained above. The mappings said here are based on the transformations among both the temporal and the spatial variations of both geo-data and the electromagnetic characteristics of the distributed complex network. The temporal variations at the mappings of EEDMCSE at specific locations extract the mechanisms explaining the relationships among the characteristics of the distributed complex network and seismic phenomena of Earth in the future. A mapping is established between the parameter space of the geo-data and the characteristics of the electromagnetically equivalent device model. The temporal variations of the geo-data are correlated to the self-optimizing the specific characteristics of the electromagnetically equivalent device. The relationships said here give a possibility of predicting the geo-data. Using the inverses of the mappings generates the evaluations giving the predictability conditions involving restrictions. The inversion of the mapping exploits a fine model at predicting the natural iterations of the geo-data at future on both the region connected the port and some locations non-related to the port either geologically or seismically or phenomenologically relating to the earth. An application related to the earthquakes of Marmara Sea region is discussed.
- Publication:
-
AGU Fall Meeting Abstracts
- Pub Date:
- December 2013
- Bibcode:
- 2013AGUFM.S43A2508S
- Keywords:
-
- 0545 COMPUTATIONAL GEOPHYSICS Modeling;
- 4317 NATURAL HAZARDS Precursors;
- 4316 NATURAL HAZARDS Physical modeling;
- 7223 SEISMOLOGY Earthquake interaction;
- forecasting;
- and prediction