TY  - EJOU
AU  - Garani, Georgia 
AU  - Pramantiotis, George 
AU  - Arboleda, Francisco Javier Moreno 

TI  - Spatio-Temporal Earthquake Analysis via Data Warehousing for Big Data-Driven Decision Systems
T2  - Computers, Materials \& Continua

PY  - 2026
VL  - 86
IS  - 3
SN  - 1546-2226

AB  - Earthquakes are highly destructive spatio-temporal phenomena whose analysis is essential for disaster preparedness and risk mitigation. Modern seismological research produces vast volumes of heterogeneous data from seismic networks, satellite observations, and geospatial repositories, creating the need for scalable infrastructures capable of integrating and analyzing such data to support intelligent decision-making. Data warehousing technologies provide a robust foundation for this purpose; however, existing earthquake-oriented data warehouses remain limited, often relying on simplified schemas, domain-specific analytics, or cataloguing efforts. This paper presents the design and implementation of a spatio-temporal data warehouse for seismic activity. The framework integrates spatial and temporal dimensions in a unified schema and introduces a novel array-based approach for managing many-to-many relationships between facts and dimensions without intermediate bridge tables. A comparative evaluation against a conventional bridge-table schema demonstrates that the array-based design improves fact-centric query performance, while the bridge-table schema remains advantageous for dimension-centric queries. To reconcile these trade-offs, a hybrid schema is proposed that retains both representations, ensuring balanced efficiency across heterogeneous workloads. The proposed framework demonstrates how spatio-temporal data warehousing can address schema complexity, improve query performance, and support multidimensional visualization. In doing so, it provides a foundation for integrating seismic analysis into broader big data-driven intelligent decision systems for disaster resilience, risk mitigation, and emergency management.
KW  - Data warehouse; data analysis; big data; decision systems; seismology; data visualization

DO  - 10.32604/cmc.2025.071509