Supercomputing Enabled Deployable Analytics for Disaster Response

First responders and other forward deployed essential workers can benefit from advanced analytics. Limited network access and software security requirements prevent the usage of standard cloud based microservice analytic platforms that are typically used in industry. One solution is to precompute a wide range of analytics as files that can be used with standard preinstalled software that does not require network access or additional software and can run on a wide range of legacy hardware. In response to the COVID-19 pandemic, this approach was tested for providing geo-spatial census data to allow quick analysis of demographic data for better responding to emergencies. These data were processed using the MIT SuperCloud to create several thousand Google Earth and Microsoft Excel files representative of many advanced analytics. The fast mapping of census data using Google Earth and Microsoft Excel has the potential to give emergency responders a powerful tool to improve emergency preparedness. Our approach displays relevant census data (total population, population under 15, population over 65, median age) per census block, sorted by county, through a Microsoft Excel spreadsheet (xlsx file) and Google Earth map (kml file). The spreadsheet interface includes features that allow users to convert between different longitude and latitude coordinate units. For the Google Earth files, a variety of absolute and relative colors maps of population density have been explored to provide an intuitive and meaningful interface. Using several hundred cores on the MIT SuperCloud, new analytics can be generated in a few minutes.

[1]  Hui Liu,et al.  Communications, Caching, and Computing for Mobile Virtual Reality: Modeling and Tradeoff , 2018, IEEE Transactions on Communications.

[2]  Wei Li,et al.  A dynamic tradeoff data processing framework for delay-sensitive applications in Cloud of Things systems , 2018, J. Parallel Distributed Comput..

[3]  Sheng Yang,et al.  Storage, Computation, and Communication: A Fundamental Tradeoff in Distributed Computing , 2018, 2018 IEEE Information Theory Workshop (ITW).

[4]  Diego Seco,et al.  Microservice-Oriented Platform for Internet of Big Data Analytics: A Proof of Concept , 2019, Sensors.

[5]  Ilyoung Chong,et al.  Design Methodology of Microservices to Support Predictive Analytics for IoT Applications , 2018, Sensors.

[6]  Jeremy Kepner Parallel MATLAB - for Multicore and Multinode Computers , 2009, Software, environments, tools.

[7]  A. Salman Avestimehr,et al.  A Fundamental Tradeoff Between Computation and Communication in Distributed Computing , 2016, IEEE Transactions on Information Theory.

[8]  Yang Zhou,et al.  Microservice-Based Platform for Space Situational Awareness Data Analytics , 2020, International Journal of Aerospace Engineering.

[9]  Ilkyeun Ra,et al.  Cloud-Based Disaster Management as a Service: A Microservice Approach for Hurricane Twitter Data Analysis , 2018, 2018 IEEE Global Humanitarian Technology Conference (GHTC).

[10]  Bogdan Franczyk,et al.  A Personal Analytics Platform for the Internet of Things - Implementing Kappa Architecture with Microservice-based Stream Processing , 2017, ICEIS.

[11]  Jeremy Kepner,et al.  Interactive Supercomputing on 40,000 Cores for Machine Learning and Data Analysis , 2018, 2018 IEEE High Performance extreme Computing Conference (HPEC).

[12]  Jeremy Kepner,et al.  Optimizing Xeon Phi for Interactive Data Analysis , 2019, 2019 IEEE High Performance Extreme Computing Conference (HPEC).

[13]  Rajiv Ranjan,et al.  Osmotic Computing: A New Paradigm for Edge/Cloud Integration , 2016, IEEE Cloud Computing.