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Energy Time Series Forecasting: Efficient and Accurate Forecasting of Evolving Time Series from the Energy Domain PDF

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Energy Time Series Forecasting Lars Dannecker Energy Time Series Forecasting Effi cient and Accurate Forecasting of Evolving Time Series from the Energy Domain Lars Dannecker Dresden, Germany Doctorate at the Technische Universität Dresden, 20.11.2014 Original title: Efficient and Accurate Forecasting of Evolving Time Series from the Energy Domain ISBN 978-3-658-11038-3 ISBN 978-3-658-11039-0 (eBook) DOI 10.1007/978-3-658-11039-0 Library of Congress Control Number: 2015947268 Springer Vieweg © Springer Fachmedien Wiesbaden 2015 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, speci(cid:191) cally the rights of translation, reprinting, reuse of illus- trations, recitation, broadcasting, reproduction on micro(cid:191) lms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a speci(cid:191) c statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, express or implied, with respect to the material contained herein or for any errors or omissions that may have been made. Printed on acid-free paper Springer Vieweg is a brand of Springer Fachmedien Wiesbaden Springer Fachmedien Wiesbaden is part of Springer Science+Business Media (www.springer.com) TomywifeUlrikeandmydaughterLuisa. Preface Continuous balancing of electric power consumption and production is a funda- mental prerequisite for the stability and efficiency of electricity grids. This bal- ancing task requires accurate forecasts of future electricity demand and supply at any point in time. For this purpose, today’s energy data management systems (EDMS)typicallyusequantitativemodels—calledforecastmodels—thatalready provideaccuratepredictions.However,recentdevelopmentsintheenergydomain such as real-time intra-day trading and the integration of more renewable energy sourcesalsorequiremoreefficientforecastingcalculationsandarapidprovision- ingofforecastingresults.Furthermore,today’sEDMSsfulfillanumberofdiffer- ent tasks, each exhibiting different requirements for the calculation of forecasts with respect to runtime and accuracy. Thus, it is necessary to flexibly adapt the forecasting process with respect to the needs of the current requests. In contrast, currentlyemployedforecastingapproachesarerathertime-consumingandinflexi- ble.Onereasonistheveryexpensiveestimationoftheforecastmodelparameters, involvingalargenumberofsimulationsinasearchspacethatincreasesexponen- tialwiththenumberofparameters. We tackle these new requirements by introducing a novel online forecasting processthataimstoimprovetheforecastingcalculationefficiencyandtoprovide forecasting process adaptability. For this purpose, the online forecasting process employs forecast model materialization in conjunction with flexible and fast pa- rameter estimation to rapidly provide accurate forecasts that are iteratively im- proved over time. EDMSs may subscribe to the online forecasting process to re- trieve improvements found during the process execution. In addition, they can adapt the progression of the forecast calculation by defining runtime constraints andaccuracytargets.Withthat,weareabletoequallyserverrequeststhatrequire resultsinalimitedamountoftimeorthattargetthebestpossibleaccuracy. The online forecasting process is complemented by further optimizations on thelogicalaswellasonthephysicallayer.Ouroptimizationsonthelogicallayer viii Preface improvetheefficiencyoftheparameterestimationindependentlyofthedataorga- nization and the employed forecast model. As a first approach, we introduce our context-awareforecastmodelrepositorythatmaterializespreviouslyusedforecast modelsandtheirparametersinconjunctionwithinformationaboutthetimeseries contextthatwasvalidduringthetimethemodelwasused.Wemaythenprovide appropriate starting points for future forecasting calculations by reusing models thatproducedaccurateresultsinacontextsimilartothecurrentone.Furthermore, forsomeusecases,itisbeneficialtoconsidercontextinformationdirectlywithin the forecast models. Especially when predicting renewable supply, information abouttheweatherareveryimportant.However,includingcontextinformationtyp- icallymeanstoaddfurtherparameterstotheforecastmodel,whichincreasesthe effortsfortheparameterestimation.Tosolvethisissue,weintroduceanintegra- tionframeworkthatoptimizesthehandlingofcontextinformationandreducesthe additional efforts when considering them. Finally, we improve the calculation of forecastsinhierarchicalenvironments.Insteadofsimplyaggregatingtimeseries, we propose a forecast model aggregation that eliminates the need for estimating theforecastmodelparametersonhigherhierarchicallevels. Ourphysicaloptimizationsaimtodirectlyprovideanefficientwayforforecast models to access time series values. For this purpose, we introduce an access- pattern-aware storage approach that exploits the memory access patterns of the usedforecastmodelstophysicallylayoutthedataforsequentialaccessandhigh spatiallocality.Withthat,wesubstantiallyreducethenegativeinfluenceofmem- orylatencyandbandwidth,whileatthesametimeimprovingtheutilizationofthe different cache levels. In addition, we propose a special parallelization approach formulti-equationforecastmodels. Overall, with the help of our online forecasting process in conjunction with the optimizations on the logical and on the physical layer, we target to enable accurate forecasting of evolving time series considering the new requirements of thechangingelectricitymarket. Acknowledgements Firstandforemost,IwouldliketoexpressmydeepestgratitudetomyadvisorProf. Dr. Wolfgang Lehner for the opportunity to pursue my dissertation project and forhiscontinuoussupportalongtheway.Ithankhimfortheveryinterestingand challengingtopicandforalltheadvicehegaveme.Wolfgangwasalwaysavailable foradiscussionandforprovidingfeedbacktomyideas.I’mverythankfulthatI had the chance to leverage his deep knowledge in all areas of data management. AlthoughIwasanexternalmemberofhisresearchgroup,Wolfgangneverletme feelexternal,butrathertreatedmeasanintegralpart.Forme,Wolfgangisthiskind of advisor who all PhD students should have. I really appreciate all the time and guidanceyouprovidedduringthelastyears.Thankyousomuchforeverything. I would also like to thank Dr. Matthias Bhm for acting as my co-mentor in thefirsttwoyears.Hewasdeeplyinvolvedinshapingthetopicofthethesisand creatingthefirstscientificresults.Matthiasdevotedalotoftimefordiscussions, forprovidingadviceandguidance,andforgivingconstructivefeedbacktomany papers.Ilearnedsomuchfromhim,especiallywithrespecttoconductingresearch, creatingpublicationsandevaluatingmyideas.Matthias,thisthesiswouldnothave beenpossiblewithoutyou.Ireallyappreciateyourdedicationandendlesssupport. Writing this thesis was greatly supported by the SAP SE and especially the SAPlocationinDresden.SAPemployedmeasaPhDstudentandthus,gaveme the chance to start my dissertation project. I want to especially thank Dr. Gregor Hackenbroichforservingasmymentoraswellasforhisconfidence,hispatience, andhisbeliefinmethroughouttheentiretime.Inmanydiscussions,Gregorpro- videdmewithveryhelpfulinputanddirectionsforvariousaspectsofmythesis. Thankyouverymuch,I’mreallygratefulforyoursupport.Further,Iwouldliketo thankmycolleagueDr.PhilippRschforbeingaco-authorofmanypapersandthe endlessdiscussionsaboutmysometimesstrangeideas.Withhisdeepknowledge, he provided great guidance and helped forming several approaches and topics of x Acknowledgements thisthesis.ThankyouPhilippfortakingsomuchtimeandendurance,especially inrelationtothesecondhalfofmythesis. Furthermore,IwouldliketothankProf.ChristianJensenforco-referringthis thesis and for many helpful comments and advice. I really appreciate his great hospitalityduringmyvisitsinAarhusandAalborg.I’malsogratefultoProf.Dr. DominikMstforservingasmyFachreferent. Special thanks goes to my students Robert Schulze, Elena Vasilyeva, Robert Lorenz,andGordonGaumnitzforcontributingtomyresearchandforhelpingto implementthepEDMprototype.ItwasapleasureworkingwithyouandI’mvery proudthatallofyouachievedsuchgoodresultsinyourfinaltheses. IamverythankfultoallmycolleaguesatSAPSEandtheTechnischeUniver- sitt Dresden who helped me with their input and discussions. I would especially like to thank: Dr. Gregor Hackenbroich and Dr. Philipp Rsch for proof-reading my thesis and for providing very constructive comments; Dr. Ulrike Fischer for working with me in the MIRABEL project and the fruitful discussions we had; Konrad,Katrin,Andreas,Henrike,andAlexandrforbeinggreatroommates;Ines and Annette for helping me with (and enduring) my numerous requests in their role as team assistants; my fellow researchers in the database technology group Dirk, Maik, Martin, Hannes, Tim, Katrin, Julian, Thomas, Tobias, Tomas, Till, Claudio,Kai,Frank,Robert,andElenaforyouracceptanceandafruitfulresearch environment;theremainingcolleaguesatSAPSEespeciallyKay,Martin,Philipp, Michael,Marcus,David,Robert,Dan,Ivan,andKarimforbeinggoodcolleagues andforprovidingagreatworkingatmosphere. Finally, this thesis would not have been possible without the constant support and motivation from my family and friends. First and foremost, I would like to thankmybelovedwifeUlrikeforalwaysbeingthereforme,forencouragingme, andforacceptingthenumeroustimesIhadtoworkathome.Yourloveandcom- mitmentiswhathasalwaysmotivatedme.Ialsowanttothank:MydaughterLuisa forcheeringmeupandforremindingmeaboutthemostimportantthingsinlife; myparentsJuttaandFalkaswellasmybrotherFrankforcontinuouslysupporting me, for permanently believing in me, and for helping me out of the tough situ- ations where I had a lot of doubts; Kay, Martin, Jan, Gregor, Stefan, and all my otherfriendsforyourfriendshipandthepatienceyouhadwithme.Thankyou!I willdedicatemoretimetoallofyouinthefuture. LarsDannecker Dresden,12.August2014 Contents 1 Introduction.................................................. 1 2 TheEuropeanElectricityMarket:AMarketStudy ............... 11 2.1 CurrentDevelopmentsintheEuropeanElectricityMarket ....... 12 2.1.1 StructureoftheEuropeanElectricityMarket ............ 12 2.1.2 DevelopmentofRenewableEnergySourcesinEurope andGermany....................................... 13 2.1.3 ImpactofVolatileRenewableEnergySources ........... 17 2.1.4 HowtoKeeptheElectricityGridinBalance ............ 20 2.1.5 ExtendingtheTransmissionGridandEnergyStorage..... 25 2.1.6 Demand-SideManagementandDemand-Response....... 30 2.1.7 ChangesontheEuropeanElectricityMarket ............ 32 2.1.8 Improvements in Forecasting Energy Demand and RenewableSupply .................................. 37 2.2 TheMIRABELProject:ExploitingDemandandSupplySide Flexibility................................................ 41 2.2.1 Flex-Offers ........................................ 41 2.2.2 ArchitectureofMIRABEL’sEDMS ................... 43 2.2.3 BasicandAdvancedUse-Case ........................ 45 2.3 Conclusion............................................... 46 3 TheCurrentStateofEnergyDataManagementandForecasting ... 49 3.1 DataCharacteristicsintheEnergyDomain .................... 50 3.1.1 SeasonalPatterns ................................... 51 3.1.2 Aggregation-Level-DependentPredictability ............ 53 3.1.3 TimeSeriesContextandContextDrifts ................ 56 3.1.4 TypicalDataCharacteristicsofEnergyTimeSeries....... 58 3.2 ForecastingintheEnergyDomain ........................... 59 3.2.1 ForecastModelswithAutoregressiveStructures ......... 59

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Lars Dannecker developed a novel online forecasting process that significantly improves how forecasts are calculated. It increases forecasting efficiency and accuracy, as well as allowing the process to adapt to different situations and applications. Improving the forecasting efficiency is a key pre
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