Testing a Novel Self-Assembling Data Paradigm in the Context of IACT Data
Abstract
The process of gathering and associating data from multiple sensors or sub-detectors due to a common physical event (the process of event-building) is used in many fields, including high-energy physics and -ray astronomy. Fault tolerance in event-building is a challenging problem that increases in difficulty with higher data throughput rates and increasing numbers of sub-detectors. We draw on biological self-assembly models in the development of a novel event-building paradigm that treats each packet of data from an individual sensor or sub-detector as if it were a molecule in solution. Just as molecules are capable of forming chemical bonds, "bonds" can be defined between data packets using metadata-based discriminants. A database -- which plays the role of a beaker of solution -- continually selects pairs of assemblies at random to test for bonds, which allows single packets and small assemblies to aggregate into larger assemblies. During this process higher-quality associations supersede spurious ones. The database thereby becomes fluid, dynamic, and self-correcting rather than static. We will describe tests of the self-assembly paradigm using our first fluid database prototype and data from the VERITAS -ray telescope.
Keywords
Cite
@article{arxiv.1509.02202,
title = {Testing a Novel Self-Assembling Data Paradigm in the Context of IACT Data},
author = {Amanda Weinstein and Lucy Fortson and Thomas Brantseg and Cameron Rulten and Robyn Lutz and Jarvis Haupt and Mojtaba Kakhodaie Elyaderani and John Quinn},
journal= {arXiv preprint arXiv:1509.02202},
year = {2015}
}
Comments
In Proceedings of the 34th International Cosmic Ray Conference (ICRC2015), The Hague, The Netherlands