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Knowledge and Information Systems

Erschienen in:

01.10.2015 | Regular Paper

Classification of multivariate time series via temporal abstraction and time intervals mining

verfasst von: Robert Moskovitch, Yuval Shahar

Erschienen in: Knowledge and Information Systems | Ausgabe 1/2015

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Abstract

Classification of multivariate time series data, often including both time points and intervals at variable frequencies, is a challenging task. We introduce the KarmaLegoSification (KLS) framework for classification of multivariate time series analysis, which implements three phases: (1) application of a temporal abstraction process that transforms a series of raw time-stamped data points into a series of symbolic time intervals; (2) mining these symbolic time intervals to discover frequent time-interval-related patterns (TIRPs), using Allen’s temporal relations; and (3) using the TIRPs as features to induce a classifier. To efficiently detect multiple TIRPs (features) in a single entity to be classified, we introduce a new algorithm, SingleKarmaLego, which can be shown to be superior for that purpose over a Sequential TIRPs Detection algorithm. We evaluated the KLS framework on datasets in the domains of diabetes, intensive care, and infectious hepatitis, assessing the effects of the various settings of the KLS framework. Discretization using Symbolic Aggregate approXimation (SAX) led to better performance than using the equal-width discretization (EWD); knowledge-based cut-off definitions when available were superior to both. Using three abstract temporal relations was superior to using the seven core temporal relations. Using an epsilon value larger than zero tended to result in a slightly better accuracy when using the SAX discretization method, but resulted in a reduced accuracy when using EWD, and overall, does not seem beneficial. No feature selection method we tried proved useful. Regarding feature (TIRP) representation, mean duration performed better than horizontal support, which in turn performed better than the default Binary (existence) representation method.

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Karma—The law of cause and effect originated in ancient India and is central to Hindu and Buddhist philosophies.

Lego—A popular game, in which modular bricks are used to construct different objects. [also, Le(t)go].

Allen JF (1983) Maintaining knowledge about temporal intervals. Commun ACM 26(11):832–843MATHCrossRef

Azulay R, Moskovitch R, Stopel D, Verduijn M, de Jonge E, Shahar Y (2007) Temporal discretization of medical time series—a comparative study. In: IDAMAP 2007, Amsterdam, The Netherlands,

Batal I, Valizadegan H, Cooper G, Hauskrecht M (2012a) A temporal pattern mining approach for classifying electronic health record data. ACM Transaction on Intelligent Systems and Technology (ACM TIST), Special Issue on Health Informatics

Batal I, Fradkin D, Harrison J, Moerchen F, Hauskrecht M (2012b) Mining recent temporal patterns for event detection in multivariate time series data. In: Proceedings of knowledge discovery and data mining (KDD), Beijing, China

Höppner F (2001) Learning temporal rules from state sequences. In: Proceedings of IJCAI Workshop on Learning from Temporal and Spatial Data (WLTSD-01), Seattle, USA, pp 25–31

Höppner F (2002) Time series abstraction methods—a survey workshop on knowledge discovery in databases, Dortmund

Hu B, Chen Y, Keogh E (2013) Time series classification under more realistic assumptions. In: Proceedings of SIAM data mining

Kam PS, Fu AWC (2000) Discovering temporal patterns for interval based events. In: Proceedings DaWaK-00

Lin J, Keogh E, Lonardi S, Chiu B (2003) A symbolic representation of time series with implications for streaming algorithms. In: 8th ACM SIGMOD DMKD workshop

10.

Mörchen F, Ultsch A (2005) Optimizing time series discretization for knowledge discovery. In: Proceedings of the Eleventh ACM SIGKDD international conference on knowledge discovery in data mining, Chicago, Illinois, pp 660–665

11.

Mörchen F (2006) Algorithms for time series knowledge mining. In: Proceedings of KDD

12.

Moerchen F (2006) A better tool than Allen’s relations for expressing temporal knowledge in interval data. In: Workshop on temporal data mining

13.

Moerchen F, Fradkin D (2010) Robust mining of time intervals with semi-interval partial order patterns. In: Proceedings of SIAM data mining

14.

Moskovitch R, Hessing A, Shahar Y (2004) Vaidurya-a concept-based, context-sensitive search engine for clinical guidelines. Medinfo 11:140–144

15.

Moskovitch R, Stopel D, Verduijn M, Peek N, de Jonge E, Shahar Y (2007) Analysis of ICU patients using the time series knowledge mining method. In: IDAMAP 2007, Amsterdam, The Netherlands

16.

Moskovitch R, Gus I, Pluderman S, Stopel D, Glezer C, Shahar Y, Elovici Y (2007) Detection of unknown computer worms activity based on computer behavior using data mining. In: IEEE Symposiyum on Computational Intelligence and Data Mining, Honolulu, Hawaii

17.

Moskovitch R, Shahar Y (2009) Vaidurya: a multiple-ontology, concept-based, context-sensitive clinical-guideline search engine. J Biomed Inform 42(1):11–21CrossRef

18.

Moskovitch R, Shahar Y (2009) Medical temporal-knowledge discovery via temporal abstraction. In: AMIA 2009, San Francisco, USA

19.

Moskovitch R, Peek N, Shahar Y (2009) Classification of ICU patients via temporal abstraction and temporal patterns mining. In: IDAMAP, Verona, Italy

20.

Moskovitch R, Shahar Y (2013) Fast time intervals mining using transitivity of temporal relations. Knowl Inf Syst. doi:10.1007/s10115-013-0707-x

21.

Moskovitch R, Shahar Y (2014) Fast detection of time intervals related patterns, TechReport 11/14. Ben Gurion University, Beer Sheva, Israel

22.

Moskovitch R, Walsh C, Hripcsak G, Tatonetti N (2014) Prediction of biomedical events via time intervals mining. In: Proceedings of ACM SIGKDD workshop on connected health at big data Era (BigCHat2014), New York, US

23.

Papapetrou P, Kollios G, Sclaroff S, Gunopulos D (2009) Mining frequent arrangements of temporal intervals. Knowl Inf Syst 21(2):133–171

24.

Patel D, Hsu W, Lee ML (2008) Mining relationships among interval-based events for classification. In: Proceedings of the 2008 ACM SIGMOD international conference on management of data, pp 393–404

25.

Pei J, Han J, Mortazavi-Asl B, Pinto H, Chen Q, Dayal U, Hsu MC (2001) PrefixSpan: mining sequential patterns efficiently by prefix-projected pattern growth. In: Proceedings of the 17th international conference data engineering (ICDE ’01)

26.

Rabiner LR (1989) A tutorial on Hidden Markov Models and selected applications in speech recognition. Proc IEEE 77(2):257–286

27.

Ratanamahatana C, Keogh EJ (2005) Three myths about dynamic time warping data mining. In: Proceedings of SIAM data mining

28.

Roddick J, Spiliopoulou M (2002) A survey of temporal knowledge discovery paradigms and methods. IEEE Trans Knowl Data Eng 4(14):750–767

29.

Sacchi L, Larizza C, Combi C, Bellazi R (2007) Data mining with temporal abstractions: learning rules from time series. Data Mining Knowl Discov 15(2):217–247

30.

Shahar Y (1997) A framework for knowledge-based temporal abstraction. Artif Intell 90(1–2):79–133

31.

Shahar Y (1998) Dynamic temporal interpretation contexts for temporal abstraction. Ann Math Artif Intell 22(1–2):159–192

32.

Shahar Y (1999) Knowledge-based temporal interpolation. J Exp Theor, Artif Intell 11:102–111

33.

Shahar Y, Chen H, Stites D, Basso L, Kaizer H, Wilson D, Musen MA (1999) Semiautomated acquisition of clinical temporal-abstraction knowledge. J Am Med Inform Assoc 6(6):494–511CrossRef

34.

Shknevsky A, Moskovitch R, Shahar Y (2014) Semantic considerations in time intervals mining. In: Proceedings of ACM SIGKDD workshop on connected health at big data Era (BigCHat2014), New York, US

35.

Stopel D, Boger Z, Moskovitch R, Shahar Y, Elovici Y (2006a) Application of artificial neural networks techniques to computer worm detection. In: International joint conference on neural networks, pp 2362–2369

36.

Stopel D, Boger Z, Moskovitch R, Shahar Y, Elovici Y (2006b) Improving worm detection with artificial neural networks through feature selection and temporal analysis techniques. In: Proceedings of the third international conference on neural networks, Barcelona

37.

Verduijn M, Sacchi L, Peek N, Bellazi R, de Jonge E, de Mol B (2007) Temporal abstraction for feature extraction: a comparative case study in prediction from intensive care monitoring data. Artif Intell Med 41:112CrossRef

38.

Villafane R, Hua K, Tran D, Maulik B (2000) Knowledge discovery from time series of interval events. J Intell Inf Syst 15(1):71–89

39.

Winarko E, Roddick J (2007) Armada—an algorithm for discovering richer relative temporal association rules from interval-based data. Data Knowl Eng 1(63):76–90

40.

Wu S, Chen Y (2007) Mining non-ambiguous temporal patterns for interval-based events. IEEE Trans Knowl Data Eng 19(6)742–758

Titel: Classification of multivariate time series via temporal abstraction and time intervals mining
verfasst von: Robert Moskovitch
Yuval Shahar
Publikationsdatum: 01.10.2015
Verlag: Springer London
Erschienen in: Knowledge and Information Systems / Ausgabe 1/2015
Print ISSN: 0219-1377
Elektronische ISSN: 0219-3116
DOI: https://doi.org/10.1007/s10115-014-0784-5

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