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Information Systems Frontiers

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22.02.2016

Geometry-based propagation of temporal constraints

verfasst von: Zhaoyu Li, Rui Xu, Pingyuan Cui, Lida Xu, Wu He

Erschienen in: Information Systems Frontiers | Ausgabe 4/2017

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Abstract

In recent years, the Internet of Things (IoT) has been introduced to offer promising solutions in many areas. A big challenge faced by the IoT is to integrate heterogeneous information sources and process information effectively. As an important element in information integration, temporal reasoning is highly related to the dynamic, sequential aspect of both the information integration and the decision making process. Focusing on temporal reasoning, this paper introduces a method to represent both qualitative and quantitative temporal constraints in a 2-dimensional (2-D) space. Meanwhile, an efficient constraint-based geometric (CG) algorithm for propagating constraints (including inherent constraints and constraint pairs) on events in a 2-D space is proposed. A geometric recombination and intersection (GRI) method, a part of the CG algorithm, is presented to propagate one constraint pair from a geometric point. The experimental results show that in terms of both constructed and realistic benchmarks, the CG algorithm outperforms the existing Floyd-Warshall’s algorithm with the time complexity of O(n ³), especially for benchmarks with a large number of events.

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Aigner, W., & Miksch, S. (2006). CareVis: integrated visualization of computerized protocols and temporal patient data. Artificial Intelligence in Medicine, 37(3), 203–218.CrossRef

Allen, J. F. (1983). Maintaining knowledge about temporal intervals. Communications of the ACM, 26(11), 832–843.CrossRef

Atzori, L., Iera, A., & Morabito, G. (2010). The internet of things: a survey. Computer Networks, 54(15), 2787–2805. doi:10.1016/j.comnet.2010.05.010.CrossRef

Barnaghi, P., Wang, W., Henson, C., & Taylor, K. (2012). Semantics for the internet of things: early progress and back to the future. International Journal on Semantic Web and Information Systems (IJSWIS), 8(1), 1–21.CrossRef

Barreiro, J., Boyce, M., Frank, J., Iatauro, M., Kichkaylo, T., Morris, P., et al. (2012). EUROPA: A Platform for AI Planning, Scheduling, Constraint Programming, and Optimization. Paper presented at the In Proc. of 4th International Competition on Knowledge Engineering for Planning and Scheduling (ICKEPS).

Belhadji, S., & Isli, A. (1998). Temporal constraint satisfaction techniques in job shop scheduling problem solving. Constraints, 3(2–3), 203–211.CrossRef

Bi, Z., & Cochran, D. (2014). Big data analytics with applications. Journal of Management Analytics, 1(4), 249–265.CrossRef

Cai, H., Xu, L., Xu, B., & Cheng, X. (2014). IoT-based configurable information service platform for product lifecycle management. IEEE Transactions on Industrial Informatics, 10(2), 1558–1567.CrossRef

Chen, S.-s. (1990). Advances in spatial reasoning (Vol. 2): Intellect Books.

Cooper, M. C., Maris, F., & Régnier, P. (2013). Managing temporal cycles in planning problems requiring concurrency. Computational Intelligence, 29(1), 111–128.CrossRef

Cushing, W.A. (2012). When is temporal planning really temporal? Arizona State University.

Cushing, W., Kambhampati, S., & Weld, D.S. (2007) When is temporal planning really temporal? In Proceedings of the 20th international joint conference on Artifical intelligence (pp. 1852–1859): Morgan Kaufmann Publishers Inc.

Dechter, R., Meiri, I., & Pearl, J. (1991). Temporal constraint networks. Artificial Intelligence, 49(1), 61–95.CrossRef

Duftschmid, G., Miksch, S., & Gall, W. (2002). Verification of temporal scheduling constraints in clinical practice guidelines. Artificial Intelligence in Medicine, 25(2), 93–121.CrossRef

Gayraud, T., & Authie, G. (1992) A parallel algorithm for the all pairs shortest path problem. In Proceedings of the International Conference on Parallel Computing.

Ghallab, M., Nau, D., & Traverso, P. (2004). Automated planning: theory & practice: Elsevier.

Giannadakis, N., Rowe, A., Ghanem, M., & Guo, Y.-k. (2003). InfoGrid: providing information integration for knowledge discovery. Information Sciences, 155(3), 199–226.CrossRef

Li, S., Xu, L. D., & Zhao, S. (2015). The internet of things: a survey. Information Systems Frontiers, 17(2), 243–259.CrossRef

Ma, H.-D. (2011). Internet of things: objectives and scientific challenges. Journal of Computer Science and Technology, 26(6), 919–924.CrossRef

Mackworth, A. K. (1977). Consistency in networks of relations. Artificial Intelligence, 8(1), 99–118.CrossRef

Mackworth, A. K., & Freuder, E. C. (1985). The complexity of some polynomial network consistency algorithms for constraint satisfaction problems. Artificial Intelligence, 25(1), 65–74.CrossRef

Ning, P., Jajodia, S., & Wang, X. S. (2001). Abstraction-based intrusion detection in distributed environments. ACM Transactions on Information and System Security (TISSEC), 4(4), 407–452.CrossRef

Planken, L., De Weerdt, M., & Van Der Krogt, R. (2012). Computing all-pairs shortest paths by leveraging low treewidth. Journal Artificial Intelligence Research (JAIR), 43, 353–388.

Pujari, A.K., Kumari, G.V., & Sattar, A. (1999). INDU: An interval & duration network. In Advanced topics in artificial intelligence (pp. 291–303): Springer.

Ranise, S., & Tinelli, C. (2003) The SMT-LIB format: An initial proposal. In Proceedings of the 1st International Workshop on Pragmatics of Decision Procedures in Automated Reasoning (PDPAR’03), Miami, Florida (pp. 94–111).

Rit, J.-F. (1986) Propagating temporal constraints for scheduling. In AAAI (Vol. 86, pp. 383–388)

Tan, W., Chen, S., Li, J., Li, L., Wang, T., & Hu, X. (2014). A trust evaluation model for e-learning. Systems Research and Behavioral Science, 31(3), 353–365.CrossRef

Tsang, E. (2014). Foundations of constraint satisfaction: the classic text: BoD–Books on Demand.

Ullberg, J., & Pecora, F. (2012) Propagating temporal constraints on sets of intervals. In Proceedings of ICAPS Workshop on Planning and Scheduling with Timelines (PSTL), Atibaia, Brazil (pp. 25–29)

Vermesan, O., & Friess, P. (2014). Internet of things-from research and innovation to market deployment: River Publishers.

Whitmore, A., Agarwal, A., & Xu, L. (2015). The Internet of things-a survey of topics and trends. Information Systems Frontiers, 17(2), 261–274.CrossRef

Xu, R. (2004). Dynamic planning and scheduling algorithm based on temporal constraint network. Computer Integrated Manufacturing Systems, 10, 188–194.

Xu, L. (2014). Engineering informatics: state of the art and future trends. Frontiers of Engineering Management, 1(3), 276–288.CrossRef

Xu, B., Xu, L., Cai, H., & Xie, C. (2014a). Ubiquitous data accessing method in IoT-based information system for emergency medical services. IEEE Transactions on Industrial Informatics, 10(2), 1578–1586.CrossRef

Xu, L., He, W., & Li, S. (2014b). Internet of things in industries: a survey. IEEE Transactions on Industrial Informatics, 10(4), 2233–2243.CrossRef

Yan, H., Xu, L., Bi, Z., Pang, Z., Zhang, J., & Chen, Y. (2015). An emerging technology – wearable wireless sensor networks with applications in human health condition monitoring. Journal of Management Analytics, 2(2), 121–137.CrossRef

Yu, X., Nguyen, B., Han, S., Chen, H., & Li, F. (2015). Electronic CRM and perceptions of unfairness. Information Technology & Management, 16, 351–362.CrossRef

Titel: Geometry-based propagation of temporal constraints
verfasst von: Zhaoyu Li
Rui Xu
Pingyuan Cui
Lida Xu
Wu He
Publikationsdatum: 22.02.2016
Verlag: Springer US
Erschienen in: Information Systems Frontiers / Ausgabe 4/2017
Print ISSN: 1387-3326
Elektronische ISSN: 1572-9419
DOI: https://doi.org/10.1007/s10796-016-9635-0

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