Visible to the public Towards Future Situation-Awareness: A Conceptual Middleware Framework for Opportunistic Situation Identification

TitleTowards Future Situation-Awareness: A Conceptual Middleware Framework for Opportunistic Situation Identification
Publication TypeConference Paper
Year of Publication2016
AuthorsYang, Kai, Wang, Jing, Bao, Lixia, Ding, Mei, Wang, Jiangtao, Wang, Yasha
Conference NameProceedings of the 12th ACM Symposium on QoS and Security for Wireless and Mobile Networks
PublisherACM
Conference LocationNew York, NY, USA
ISBN Number978-1-4503-4504-0
KeywordsCollaboration, composability, Metrics, middleware, opportunistic sensing, pubcrawl, Resiliency, security, situation identification, situation-aware, situational awareness
Abstract

Opportunistic Situation Identification (OSI) is new paradigms for situation-aware systems, in which contexts for situation identification are sensed through sensors that happen to be available rather than pre-deployed and application-specific ones. OSI extends the application usage scale and reduces system costs. However, designing and implementing OSI module of situation-aware systems encounters several challenges, including the uncertainty of context availability, vulnerable network connectivity and privacy threat. This paper proposes a novel middleware framework to tackle such challenges, and its intuition is that it facilitates performing the situation reasoning locally on a smartphone without needing to rely on the cloud, thus reducing the dependency on the network and being more privacy-preserving. To realize such intuitions, we propose a hybrid learning approach to maximize the reasoning accuracy using limited phone's storage space, with the combination of two the-state-the-art techniques. Specifically, this paper provides a genetic algorithm based optimization approach to determine which pre-computed models will be selected for storage under the storage constraints. Validation of the approach based on an open dataset indicates that the proposed approach achieves higher accuracy with comparatively small storage cost. Further, the proposed utility function for model selection performs better than three baseline utility functions.

URLhttp://doi.acm.org/10.1145/2988272.2990291
DOI10.1145/2988272.2990291
Citation Keyyang_towards_2016