Abstract
The main issue, which has existed since the development of Single Layer Hierarchical Graph Neuron (SLHGN) started, is the representation for location data that will be fed to SLHGN structure. Similar issue, the double-value characteristics of the ordinary and current coordinate system have slowed down the enhancement of a sophisticated earthquake forecasting technology that uses SLHGN. To deal with the problem, a new way of representing locations on the earth, called Single Value Coordinate System (SVCS), has been researched and developed. Since the location of a potential earthquake—after being elaborated by the earthquake forecaster—is represented through esvecees (SVCS) values, people would have difficulties to understand and to locate it. To make the earthquake forecasting results be understandable and locatable for targeted people, those esvecees values should therefore be transformed into ordinary coordinates, which comprise longitude and latitude values. For that purpose, a technology for the transformation from esvecees values to ordinary coordinates have been successfully developed. The experiment results show that the location of a potential earthquake can now be gained as longitude and latitude values. This means that the earthquake forecasting using Single Layer Hierarchical Graph Neuron (SLHGN) is getting closer to its complete functionalities.
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References
McCarthy, J.J., Rowton, S., Moore, D., Pavlis, D.E., Luthcke, S.B., Tsaoussi, L.S.: GEODYN Systems Description Volume 1, Greenbelt: NASA GSFC (2015)
Jekeli, C.: Geometric Refernce System in Geodesy. Ohio State University, Columbus (2006)
Panou, G., Korakitis, R.: Geodesic equations and their numerical solution in Cartesian coordinates on a triaxial elipsoid. J. Geod. Sci. 9(1), 31–42 (2017)
Engel, A.: Coordinate transformation algorithms for the hand-over of targets between POEMS interrogators. Eurocontrol, Brussel (2005)
Claessens, S.J.: Efficient transformation from Cartesian to geodetic coordinates. Comput. Geosci. 133(1), 1–32 (2019)
ugli Abdufattakhov, H.M.: Coordinate systems and heights in geodesy. Eur. J. Res. Dev. Sustain. (EJRDS) 2(11), 16–18 (2021)
Grewal, M.S., Weill, L.R., Andrews, A.P.: Global Positioning Systems, Inertial Navigation, and Integration. Wiley, Hoboken (2007)
Zeng, H.: Explicitly computing geodetic coordinates from Cartesian coordinates. Earth Planets Space 65(4), 291–298 (2012). https://doi.org/10.5047/eps.2012.09.009
Nasution, B.B.: Features of single value coordinate system (SVCS) for earthquake forecasting using single layer hierarchical graph neuron (SLHGN). In: 2021 International Conference on Software Engineering & Computer Systems and 4th International Conference on Computational Science and Information Management (ICSECS-ICOCSIM), Pekan, Malaysia (2021)
Nasution, B.B., Sembiring, R.W., Siregar, I., Seri, E., Mardi, R.W.: Towards single value coordinate system (SVCS) for earthquake forecasting using single layer hierarchical graph neuron (SLHGN). In: Murayama, Y., Velev, D., Zlateva, P. (eds.) ITDRR 2020. IAICT, vol. 622, pp. 73–89. Springer, Cham (2021). https://doi.org/10.1007/978-3-030-81469-4_7
Bouman, J., Ebbing, J., Schmidt, M., Lieb, V., Fuchs, M.: Algorithm Theoretical Basis Document. GOCE+ GeoExplore, Munich (2015)
Badan Standardisasi Nasional: Geographic Information—Spatial Referencing by Coordinates. Badan Standardisasi Nasional, Jakarta (2011)
Ashby, N.: An Earth-Based Coordinate Clock Network, Boulder. National Bureau of Standards, Colorado (1975)
Fine, H.B., Thompson, H.D.: Coordintae Geometry. Macmillan Company, New York (1911)
Bronshtein, I., Semendyayev, K., Musiol, G., Muehlig, H.: Handbook of Mathematics. Springer, Berlin (2007). https://doi.org/10.1007/978-3-540-72122-2
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Nasution, B.B. et al. (2023). Transformation of an Esvecees (SVCS) Value to Spherical Coordinates as the Result of the Earthquake Forecasting Using SLHGN. In: Gjøsæter, T., Radianti, J., Murayama, Y. (eds) Information Technology in Disaster Risk Reduction. ITDRR 2022. IFIP Advances in Information and Communication Technology, vol 672. Springer, Cham. https://doi.org/10.1007/978-3-031-34207-3_17
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DOI: https://doi.org/10.1007/978-3-031-34207-3_17
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