Tekin, CemYoon, J.Van Der Schaar, M.2018-04-122018-04-122016http://hdl.handle.net/11693/37524Date of Conference: 12-13 February 2016Conference Name: 30th AAAI Conference on Artificial Intelligence, 2016With the advances in the field of medical informatics, automated clinical decision support systems are becoming the de facto standard in personalized diagnosis. In order to establish high accuracy and confidence in personalized diagnosis, massive amounts of distributed, heterogeneous, correlated and high-dimensional patient data from different sources such as wearable sensors, mobile applications, Electronic Health Record (EHR) databases etc. need to be processed. This requires learning both locally and globally due to privacy constraints and/or distributed nature of the multimodal medical data. In the last decade, a large number of meta-learning techniques have been proposed in which local learners make online predictions based on their locally-collected data instances, and feed these predictions to an ensemble learner, which fuses them and issues a global prediction. However, most of these works do not provide performance guarantees or, when they do, these guarantees are asymptotic. None of these existing works provide confidence estimates about the issued predictions or rate of learning guarantees for the ensemble learner. In this paper, we provide a systematic ensemble learning method called Hedged Bandits, which comes with both long run (asymptotic) and short run (rate of learning) performance guarantees. Moreover, we show that our proposed method outperforms all existing ensemble learning techniques, even in the presence of concept drift.EnglishArtificial intelligenceBig dataCognitive systemsComputer gamesComputer programmingComputer systems programmingData miningDecision support systemsMachine learningEnsemble learningOnline learningHospital data processingHybrid systemsLearning algorithmsLearning systemsPopulation statisticsClinical decision support systemsElectronic health recordGlobal predictionsMedical informaticsMeta-learning techniquesMobile applicationsPerformance guaranteesPrivacy constraintsConfidence boundsConference Paper