In recent years, a plethora of approaches have been proposed to deal with the increasingly challenging task of mining concept-drifting data streams. However, most of these approaches can only be applied to uni-dimensional classification problems where each input instance has to be assigned to a single output class variable. The problem of mining multi-dimensional data streams, which includes multiple output class variables, is largely unexplored and only few streaming multi-dimensional approaches have been recently introduced. In this paper, we propose a novel adaptive method, named Locally Adaptive-MB-MBC (LA-MB-MBC), for mining streaming multi-dimensional data. To this end, we make use of multi-dimensional Bayesian network classifiers (MBCs) as models. Basically, LA-MB-MBC monitors the concept drift over time using the average log-likelihood score and the Page-Hinkley test. Then, if a concept drift is detected, LA-MB-MBC adapts the current MBC network locally around each changed node. An experimental study carried out using synthetic multi-dimensional data streams shows the merits of the proposed method in terms of concept drift detection as well as classification performance.
AggarwalC.C., Data Streams: Models and Algorithms, Springer, 2007.
2.
AliferisC.F., StatnikovA., TsamardinosI., ManiS. and KoutsoukosX.D., Local causal and Markov blanket induction for causal discovery and feature selection for classification, Part I: Algorithms and empirical evaluation, Journal of Machine Learning Research11 (2010), 171-234.
3.
AliferisC.F., StatnikovA., TsamardinosI., ManiS. and KoutsoukosX.D., Local causal and Markov blanket induction for causal discovery and feature selection for classification, Part II: Analysis and extensions, Journal of Machine Learning Research11 (2010), 235-284.
4.
BielzaC., LiG. and LarrañagaP., Multi-dimensional classification with Bayesian networks, International Journal of Approximate Reasoning52(6) (2011), 705-727.
5.
BifetA., HolmesG., PfahringerB., KirkbyR. and GavaldàR., New ensemble methods for evolving data streams, in: Proceedings of the 15th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, (2009), 139-148.
6.
BorchaniH., BielzaC., Martínez-MartínP. and LarrañagaP., Markov blanket-based approach for learning multi-dimensional Bayesian network classifiers: An application to predict the European Quality of Life-5 Dimensions (EQ-5D) from the 39-item Parkinson's Disease Questionnaire (PDQ-39), Journal of Biomedical Informatics45 (2012), 1175-1184.
7.
ChickeringD.M., Learning equivalence classes of Bayesian-network structures, Journal of Machine Learning Research2 (2002), 445-498.
8.
ClareA. and KingR.D., Knowledge discovery in multi-label phenotype data, in: Proceedings of the 5th European Conference on Principles of Data Mining and Knowledge Discovery, (2001), 42-53.
9.
DawidA.P., Statistical theory: The prequential approach, Journal of the Royal Statistical Society: Series A147(2) (1984), 278-292.
10.
DomingosP. and HultenG., Mining high-speed data streams, in: Proceedings of the 6th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, (2000), 71-80.
11.
GaberM.M., Advances in data stream mining, Wiley Interdisciplinary Reviews: Data Mining and Knowledge Discovery2(1) (2012), 79-85.
12.
GamaJ. and CastilloG., Learning with local drift detection, in: Proceedings of the 2nd International Conference on Advanced Data Mining and Applications, (2006), 42-55.
13.
GamaJ., SebastiãoR. and RodriguesP.P., Issues in evaluation of stream learning algorithms, in: Proceedings of the 15th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, (2009), 329-338.
14.
GamaJ., SebastiãoR. and RodriguesP.P., On evaluating stream learning algorithms, Machine Learning90(3) (2013), 317-346.
15.
GamaJ., Knowledge Discovery from Data Streams, Data Mining and Knowledge Discovery Series, Chapman & Hall/ CRC, 2010.
16.
GamaJ., liobaitėI., BifetA., PechenizkiyM. and BouchachiaA., A survey on concept drift adaptation, ACM Computing Surveys46(4) (2014), 44:1-44:37.
17.
GaoJ., DingB., FanW., HanJ. and YuP.S., Classifying data streams with skewed class distributions and concept drifts, IEEE Internet Computing12(6) (2008), 37-49.
18.
GodboleS. and SarawagiS., Discriminative methods for multi-labeled classification, in: Proceedings of the 8th Pacific Asia Conference on Knowledge Discovery and Data Mining, (2004), 22-30.
19.
HenrionM., Propagating uncertainty in Bayesian networks by probabilistic logic sampling, in: Proceedings of the 4th Conference on the Uncertainty in Artificial Intelligence, (1988), 149-163.
20.
HinkleyD., Inference about the change-point from cumulative sum tests, Biometrika58(3) (1971), 509-523.
21.
KohaviR. and JohnG.H., Wrappers for feature subset selection, Artificial Intelligence97(1-2) (1997), 273-324.
22.
KollerD. and FriedmanN., Probabilistic Graphical Models. Principles and Techniques, The MIT Press, Cambridge, MA, 2009.
23.
KongX. and YuP.S., An ensemble-based approach to fast classification of multi-label data streams, in: Proceedings of the 7th International Conference on Collaborative Computing: Networking, Applications and Worksharing, (2011), 95-104.
24.
KullbackS. and LeiblerR.A., On information and sufficiency, Annals of Mathematical Statistics22(1) (1951), 79-86.
25.
MadjarovG., KocevbD., GjorgjevikjaD. and DžeroskibS., An extensive experimental comparison of methods for multi-label learning, Pattern Recognition45(9) (2012), 705-727.
26.
MinkuL., WhiteA. and YaoX., The impact of diversity on on-line ensemble learning in the presence of concept drift, IEEE Transactions on Knowledge and Data Engineering22(5) (2010), 730-742.
PearlJ., Probabilistic Reasoning in Intelligent Systems: Networks of Plausible Inference, Morgan Kaufmann Publishers, 1988.
29.
PearlJ. and VermaT.S., Equivalence and synthesis of causal models, in: Proceedings of the 6th Conference on Uncertainty in Artificial Intelligence, (1990), 220-227.
30.
QuW., ZhangY., ZhuJ. and QiuQ., Mining multi-label concept-drifting data streams using dynamic classifier ensemble, in: Proceedings of the 1st Asian Conference on Machine Learning, (2009), 308-321.
31.
ReadJ., PfahringerB. and HolmesG., Multi-label classification using ensembles of pruned sets, in: Proceedings of the 8th IEEE International Conference on Data Mining, (2008), 995-1000.
32.
ReadJ., PfahringerB., HolmesG. and FrankE., Classifier chains for multi-label classification, Machine Learning85(3) (2011), 333-359.
33.
ReadJ., BifetA., HolmesG. and PfahringerB., Scalable and efficient multi-label classification for evolving data streams, Machine Learning88(1) (2012), 243-272.
34.
SebastiãoR. and GamaJ., A study on change detection methods, in: Proceedings of the 14th Portuguese Conference on Artificial Intelligence, (2009), 353-364.
35.
TsamardinosI., BrownL.E. and AliferisC.F., The max-min hill-climbing Bayesian network structure learning algorithm, Machine Learning65(1) (2006), 31-78.
36.
TsoumakasG. and KatakisI., Multi-label classification: An overview, International Journal of Data Warehousing and Mining3(3) (2007), 1-13.
37.
TsymbalA., The problem of concept drift: Definitions and related work, Technical Report TCD-CS-2004-15, Department of Computer Science, Trinity College Dublin, Ireland, 2004.
38.
van der GaagL.C. and de WaalP.R., Muti-dimensional Bayesian network classifiers, in: Proceedings of the 3rd European Workshop on Probabilistic Graphical Models, (2006), 107-114.
39.
WidmerG. and KubatM., Learning in the presence of concept drift and hidden contexts, Machine Learning23(1) (1996), 69-101.
40.
XioufisE.S., SpiliopoulouM., TsoumakasG. and VlahavasI., Dealing with concept drift and class imbalance in multi-label stream classification, in: Proceedings of the 22nd International Joint Conference on Artificial Intelligence, (2011), 1583-1588.
41.
ZhangX., YuanQ., ZhaoS., FanW., ZhengW. and WangZ., Multi-label classification without the multi-label cost, in: Proceedings of the 10th SIAM International Conference on Data Mining, (2010), 778-789.
42.
ZhangM. and ZhouZ., A review on multi-label learning algorithms, IEEE Transactions on Knowledge and Data Engineering26(8) (2014), 1819-1837.
