Title: The Advanced Rapid Imaging andAnalysis for Monitoring Hazards (ARIA-MH) Science Data System
Presenting Author: Hook Hua
Organization: Jet Propulsion Laboratory

Abstract:
Space-based geodetic measurement techniques such as Interferometric Synthetic Aperture Radar (InSAR) are now important elements in our tool set for monitoring earthquake-generating faults, volcanic eruptions, hurricane damage, landslides, reservoir subsidence, and other natural and man-made hazards. Geodetic imaging's unique ability to capture surface deformation with high spatial and temporal resolution has revolutionized both earthquake science and volcanology. Continuous monitoring of surface deformation and surface change before, during, and after natural hazards improves decision-making from better forecasts, increased situational awareness, and more informed recovery. However, analyses of InSAR and GPS data sets are currently hand-crafted following events and are not generated rapidly and reliably enough for use in operational response to natural disasters. Additionally, the sheer data volumes needed to handle a continuous stream of InSAR data sets also presents a bottleneck. It has been estimated that continuous processing of InSAR coverage of California alone over 3-years would reach PB-scale data volumes. Our Advanced Rapid Imaging andAnalysis for Monitoring Hazards (ARIA-MH) science data system enables both science and decision-making communities to monitor areas of interest with derived geodetic data products via seamless data preparation, processing, discovery, and access. We will present our findings on the use of hybrid-cloud computing to improve the timely processing and delivery of geodetic data products, provisional scaling of computing needs, process migration, as well as providing faceted browse results for quick looks with other tools for integrative analysis.