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DigitalisationofEducation:ApplicationandBestPracticesOlgaViberg&AnnaMavroudi
KTHRoyalInstituteofTechnology,SchoolofElectricalEngineeringandComputerScienceResearchGroupinTechnology-EnhancedLearning
e-mail:[email protected];[email protected]
TableofContentsDigitalisationofEducation:ApplicationandBestPractices......................................................1
Introduction..........................................................................................................................1
1. LearningManagementSystems...................................................................................2
2. MassiveOpenOnlineCourses......................................................................................3
3. Learninganalyticsdashboardsandvisualisations........................................................4
4. Data-supportedfeedback.............................................................................................5
5. Studentmisconceptions...............................................................................................6
6. Identifyingat-riskstudentsandpredictiveanalytics....................................................7
7. Studentstrategiesandattitudes..................................................................................8
8. Learninginasocialcontext..........................................................................................9
9. Learninganalyticsandlearningdesign......................................................................12
References...........................................................................................................................14
IntroductionThetopicofdigitalisationofeducationhasattractedtheinterestoftheresearchcommunityworldwide due to unprecedented capabilities provided by the technology to capture the‘digitaltraces’oftoday’sstudentswho,being‘digitalnatives’,areactive intechnology-richlearningenvironments.TheaimofthisreportistopresentsolutionsonthetopicthatcanbeapplicabletoSwedishcontext.Thesesolutionsemergeasbestpracticesorexamplesderivedfromsearchingtherecentinternationalliterature.TheycanbeadoptedormodifiedtofittheSwedishcontext,giventhatitisraretofinduniversalsolutionsthatcanbeapplied‘as-is’(i.e.,directly)ineverysocio-culturalcontext.
Thisreportcomprisestendifferentapplicationsondigitalisationofmoderneducation,which in their majority are relevant to Learning Analytics, defined as “the measurement,collection,analysisandreportingof[big]dataaboutlearnersandtheircontexts,forpurposesofunderstandingandoptimizinglearningandtheenvironmentsinwhichitoccurs”(Long&Siemens,2011,p.34).Learninganalyticsevidenceforlearninghasearlierbeenvalidatedandpresentedaccordingtofourpropositions:
- Learninganalyticsimprovelearningoutcomes- Learninganalyticsimprovelearningsupportandteaching- Learninganalyticsaretakenupandusedwidely,includingdeploymentatscale- Learninganalyticsareusedinethicalway(seeFerguson&Clow,2017;Vibergetal.,
2018).
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First,thisreporttouchesuponsomebestpracticesofdigitalisationinconjunctionwithsome prominent learning technology, in particular with Learning Management Systems(LMSs),MassiveOpenOnlineCourses(MOOCs),andlearningdashboards(sections1-3).Thesecondcategorydiscussestheuseoflearninganalyticswithafocusonaddressingparticularproblems (sections 4-7): provide timely and relevant feedback, destabilise studentmisconceptions, help students develop effective learning strategies, and identify at-riskstudentswiththeaimofreducingdrop-outs.Finally,twointerestingandrelevantthemesarediscussedwhicharecloselyrelatedtocurriculumdesign(sections8-9):theinterplaybetweenlearninganalyticsandlearningdesign,learninganalyticsinasociallearningcontext.Itshouldbenotedthattheresearchstudiesmentionedinonecategorymightalsofittosomeothercategory.
In addition to the relevant literature, the report is particularly inspired by recentreviewsoflearninganalytics:Vibergetal.(2018),Misiejuk&Wasson(2017),andLangetal.(2017). These reviews suggest that thereare several researchgaps in theareaof learninganalytics. They currently include the application of learning analytics in K-12 education,researchoneverydayanalyticsinclassrooms,researchonassessment,researchonlearning-centric analytics, as opposed to learner-centric analytics, implementation and impact oflearninganalyticsanddataliteracy,withtheexceptionsofafewstudiesthataddresswhetherornotstakeholders (i.e., teachersand learners)canunderstandthevisualisations theyarepresented(Misiejuk&Wasson,2017).Mostofthelearninganalyticsresearchhassofarbeenconductedinhighereducation.
1. LearningManagementSystemsLearningManagementSystems(LMS;e.g.,Moodle,Blackboard,Canvas)arevirtuallearningenvironmentsthatarebeingwidelyusedinmanydifferenteducationalsettings.Tracedataaboutstudents’activityinaLMSareoftenattheheartoflearninganalyticsapplications.Forexample,Gaševićetal.(2016)haveshownthatonlythefollowingvariables-numberofloginsandnumberofoperationsperformedondiscussionforumsandresources-weresignificantpredictors of academic performance, predicting approximately 21% of the variability inacademic performance. Hence, it is difficult to translate these predictors into actionablerecommendationstofacilitatestudentlearning.AnanswertothisissueisofferedbyNguyenetal.(2018),whoarguethatthekeytoactionableinsightsistheassociationbetweenlearninganalyticswithlearningdesign.Thisassociationenablestheteachertocompareandcontrastthe actual online behaviour of the students with the teacher’s intentions. It is furtherdescribedinsection9onlearninganalyticswithlearningdesign.
LearninganalyticshavebeenshowntomakeextensiveuseoftracedatafromlearnersinteractingwithLMSs,andoneofthemostcommonusesistoderiveanestimateofthetimeeachlearnerspentontask,thatisengaginginparticularlearningactivities.Kovanovicetal.(2015)presenttwoexperimentsexploringdifferentmeasuresoftimeontask;oneusingdatafromafully-onlinecourseataCanadianuniversity,andanotherusingdatafromablendedcourse at an Australian university. Based on modelling different student performancemeasureswithpopularstatisticsmethodsintwodatasets,theresultsshowthattime-on-taskmeasures typically outperformed countmeasures for predicting studentperformance, butmore importantly, identified that the precise choice of time-on-taskmeasure "can have asignificant effect on the overall fit of the model, its significance, and eventually on theinterpretationofresearchfindings"(p.105).Insummary,time-on-taskestimationmethodswerefoundtoplayaconsiderableroleinshapingthefinalsstudyresults,especiallyinonlineenvironmentswheretheamountofinteractionwithLMSisusuallyhigher.Fromapracticalperspective, researchers recommend todevelop“standardizedplugin for theextractionof
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tracedatafrompopularLMSsystems(e.g.,Moodle,WebCT,Canvas)thatcouldprovidefastandeasytotime-on-taskandcountmeasures”(Kovanovicetal.,2015,p.105).Today,westillneedsuchautomatizedtoolsthatcouldbesmoothlyintegratedintoexistingLMSstobetterunderstandhow learners spend timeon their learning activities and thus to createbetteropportunitiesfortheireffectivelearning.
2. MassiveOpenOnlineCoursesMassiveOpenOnlineCourses(MOOCs)areavailabletothousandsofstudentsviasomeweb-basedplatform,increasingaccesstohigh-qualitymaterialfordistanceandlifelonglearners.MOOCscreatelargeamountsofdatacanfeedthevariouslearninganalyticstools.However,mostMOOCsstilladoptatop-downteachingapproach,ignoringthepotentialforfacilitatingawareness,self-regulationandpersonalisation (Drachsler&Kalz,2016).DrachslerandKalz(2016)describedthepotentialof learninganalytics inthecontextofMOOCs. Inparticular,theydescribeaMOOCLearningAnalyticsInnovationCycle(MOLAC;Figure1)whichcanbeappliedatthemicro,meso,andmacrolevel.
Figure1.TheMOOCLearningAnalyticsInnovationCycle(adoptedfromDrachsler&Kalz,2016)
On the micro-level, the data collection and analytics activities are focused on individualreflectionandindividualprediction.Onthemeso-level,datafromseveralopencoursesarecombined to support benchmarking and to create insights about behavior of groups oflearners rather than the individual. Finally, on themacro-level, cross-institutional learninganalyticsenablestodeveloplearningandteachinginterventionsthatcanbetestedinaclusterof educational institutions to analyse the impactof such interventions, beyond contextualfactors.IntheirreviewofMOOCsandlearninganalytics,theauthorspinpointthatpresentlymostoftheconductedstudiesfocusedonthemicro-leveloftheMOLACcycle.
AchallengewithMOOCSisthat,unliketraditionaleducationalsystems,measureslikedetaileddemographicsandpriorknowledgearenotcollected inorder tomaintaina lowbarrier toentry. Many MOOC-providing institutions thus have begun to collect this data throughoptional surveys. Students completing their courses are also thosewho tend to completethesesurveys.Reich(2014)suggestthatroughlyonequarterofenrolledlearnersfilloutsuchcoursesurveys.Thevolumeofcollectedresponsescanbehigh(oftentensofthousands)butmightrepresentaskewedsampleofgenerallymoremotivatedlearners.
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Withrespecttostudents’affectivedomain(i.e.,thedomainthatincludesthemannerinwhichindividualsmanagethingsemotionally,forexamplevalues,feelings,andappreciation),Leonyetal. (2015)built fourmodels todetectboredom, frustration,happiness,andconfusion inMOOCs.Themodelswere testedonagroupof studentsand thecorrelationbetween theemotionsandstudent’sinteractiondatawascalculated.ThefoursuggestedmodelshavebeenimplementsintoALAS-KA,alearninganalyticsmodulefortheKhanAcademyplatform.Thismodule includes new metrics (except those already provided by the platform) andvisualisationsofinformationtakenfromtheanalysisoftheuseractivities’patterns.AlloftheimplementedmodulestakeintoaccounttheProblemLogprovidedbytheKhanAcademy.Itincludesalloftheinformationaboutusers’interactionwithexercisesandthetimestampinwhichtheytookplace.Thefourmodelswereappliedonthe90studentstakingthecoursesinmathematics,physicsandchemistryin2013.Theinitialanalysisofemotionvaluescalculatedforaperiodof10dayshasshownseveralexpectedpatterns,suchasincrementsofemotionlevelsaslearnerswereinteractionmorewiththecoursematerials.Theuseofrulesforthedetectioncanhelptoovercomeseveralissues,includingaslowstart,giventhatataninitialmomenttheremightnotbeenoughdatatocalculatethelearners’emotionsvalues.Byaddingthelogictotheinferenceofeachemotion,educationalinstructorscanbeawareofthemetricsthatcouldhaveinterferedtobeabletodetectachosenemotioninalearnerandthustomakebetterinformeddecision.
3. LearninganalyticsdashboardsandvisualisationsLearning-analyticsdashboards(LAD)arecurrentlythemaintrendintheliteraturesincetheymirror the students’ behaviour back to the students and/or/or to the teachers. Learningdashboardisdefinedas“asingledisplaythataggregatesmultiplevisualisationsofdifferentindicatorsaboutlearner(s),learningprocess(es),and/orlearningcontext”(Schwendimannetal.,2016). Millecampetal.(2018)presentaLADthatsupportsthedialoguebetweenastudentand a study advisor. To ensure transfer to other contexts (in terms of scalability), thedashboardvisualisesdatathatiscommonlyavailableinhighereducation,likethegradesofthe student, study progress, and academic ranking in comparison with peers (i.e., socialcomparison), and a prediction of the duration of study for the bachelor program for thisstudent,basedonhistoricdata.AdashboardwasdeployedatKULeuven(Belgium)tosupportdiscussion sessions. The results indicate that the dashboard primarily triggers reflectiveconversationswithstudentsdoubtingtocontinuethebachelorprogram,indicatingthatthedashboardisusefultosupportdifficultdecision-makingprocesses. AnotherexamplepresentstheStudentActivityMeter(SAM)forawarenessandself-reflection (Govaerts et al., 2011). SAM visualises learning activates within online learningenvironments for learners and teachers to help increase awareness and to support self-reflection.Thisdashboardsupportsthefollowingteacherobjectives:
- Awareness for teachersofwhatandhow learnersaredoing is important toassesslearnersprogress
- SAMvisualisesthetimelearnersspentandtheresourcestheyused- Timetrackinginformationallowsteacherstoassesstheirinitialtimeestimateswith
therealtimespendingofthestudentsandfintheexercisesthatconsumemosttime- The resourceusagecanshowthepopular learningmaterialsandenables resource
discovery,throughalistofmostusedormosttimespentonresourcesinSAM.
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TheresultsoftheconductedcasestudyshowthatSAMcontributestocreatingawarenessforteachers.Itenables:i)tofindstudentsdoingwellandatrisk,ii)abettercourseoverview,andiii)understandingstudenttimespending.MostoftheparticipantswantedtocontinueusingSAM. Broosetal. (2017) introducedaLADforactionablefeedbackonlearningskills.Thedashboard provides actionable feedback about five of the learning skills assessed by theLearningAnalyticsStudyStrategiesInventory(LASSI):concentration,anxiety,motivation,teststrategies,andtimemanagement.Itusesdataaboutstudents,theirlearningskillsandscoresthatwerealreadyavailablewiththeinstitution(KULeuven),butfragmentedacrossservicesandnotfedbacktothedatasubjects(i.e.,learnersandteachers)inadirectway.14061styearstudentsin12differentstudyprogramsatKULeuvenwereinvitedtousethedashboardtosupportthemintheirtransitionfromsecondarytohighereducation.TheLASSIwasusedtoassess learningskillsusingasurveytakenwithinthefirstweeksof theacademicyear.Thedashboardsystem (for thehigh-leveloverviewof thesystemseeFigure2)didnot requiredirectaccesstothestudents’namesorothercharacteristicsthatallowforstraightforwardidentification,astheyweremadeavailableataccesstimebythesingle-signoninfrastructure.
Figure2.Overviewofsystemsanddataflowstosupportthedashboard(adoptedfromBroosetal.2017)
ThesystemloggedaccesstoandbehaviorwithintheLADandanalysedtheirrelationshipwiththese learning skills. The results show that while 8 out of 10 students accessed the LAD,studentswithlowertimemanagementscorestendtohavealowerclick-throughrate.Oncewithinthedashboard,studentswithlowerscoresforspecificlearningskillsareaccessingthecorresponding information and remediation possibilities more often. Regardless of theirscoresforanyoftheotherlearningskills,learnerswithhighermotivationscoresarereadingtheremediationpossibilitiesfortheotherfourlearningskillsmoreoften.GenderandstudyprogramwerefoundtohaveaninfluenceonhowlearnersusetheLAD.
4. Data-supportedfeedbackTheprovisionoftimelyandrelevantfeedbackisanothertopiccloselyassociatedtotheuseoflearning analytics. Kickmeier-Rust et al. (2014) developed a gamified learning app, ‘SonicDivider’1tohelpprimaryschoolstudentsinAustralialearnmathematics.Itfeaturesformativeassessment and feedback functions and gives the teacher a quickly overview about theachievements, scores, and competency levels. The authors examined the link betweenformativefeedbackandlearningperformance,andanalysedtheresultsbygenderandoverall
1SoniceDivider,http://next-tell.eu/portfolios/sonicdivider/
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bystatisticalmethods.Theyfoundevidenceforthemotivationalaspectofthegamificationelements,inparticularscoring.Theyalsoidentifiedpositiveeffectsofanindividualizedandmeaningful,elaboratedfeedbackabouterrorsmade.Withrespecttogenderdifferences,theauthors found evidence that girls were less attracted by competition elements (e.g., bycomparing high scores) than boys, however, they weremore attentive towards feedbackcomingfromthetool.
“Learning ispersonal (LIP)” 2 isanotheravailabletoolthatoffersdata-supportedfeedback.TheLIPtoolcaptureslearningactivitiesinreal-timeandprovidesinstantstatisticalfeedback.Itmainly targets teachers, studentsandstudents’peers. Inparticular, it supports learners’peer-andself-assessmentsaswellasteachers’observations.Itisoptimizedtofitclassroomactivitieswhere timeandattentionare scarce resources. The tool’s focus is toprovideanoverviewoverall learningactivitiesinallsubjectsoverthewholeterm.Itdoesnotprovidespecificinsightsorin-depthanalyses.However,itprovidestheteacherwithsimple,real-timeinsightsandallowstheteachertoenhancethedatamodel(e.g.,usedmaterial)onthefly.Thistoolisoptimisedforperformanceandtobeontablets,mobilesandlaptops.
5. StudentmisconceptionsStudents’misconceptionsaboutasubjectmightbedeeply-rootedandcanimpedelearning,whichsuggeststhatthepracticeofonlyconsideringthefinalsolutionoftenresultsinstudentknowledge gaps andmisconceptions (Davies et al., 2015). The area of intelligent tutoringsystems3 (ITS)hasa long tradition inclarificationofmisconceptionsandpersonalisationoflearning(e.g.,personalisedfeedback).
Davies et al. (2015) compared differences in detecting students’ knowledge gaps andmisconceptionsabouttheuseofabsolutereferences4whenusingassessment-leveldata(i.e.,thefinalsolutionstudentssubmitwhensolvingaproblem)tothatofusingtransactional-leveloractivity-tracedata(i.e.,theprocessstudentstaketoarriveattheirfinalsolution).Intheirstudy, the researchers – based on the analysis of the student assessment data (i.e., theirwrittenhomework,mid-termexaminationandfinalexams)collectedfromthreeuniversitiesin the western United States in 2014 (995 students) - found higher levels of knowledgecomponents gaps and misunderstandings when assessing transactional-level knowledgecomponentdatathantask-levelfinalsolutiondata.
Data was gathered through an ITS, in this case a tool developed in the Microsoft Excelplatform:foreachassignment,thedevelopedsystemcreatedaspecifiedlogofeachstepthestudenttooktocometoasolution,i.e.,notonlythefinalsolutiongradedbytheprogram.Thelogwasthenrecordedonahiddenworksheetwithintheworkbooksothatwhenthestudent’ssolutionissubmittedthelogissubmittedaswell.Thislogcanthenbeextractedforanalysisofthestudent’slearningprocessandthefinalsolution.
Examiningthe finalsolutions thatstudentssubmittedshowed littleevidencethatstudentshad any misunderstandings or knowledge gaps about the use of absolute references.Nevertheless,analysingdataat the transactional level researchers identified that farmorestudentsstruggledusingabsolutereferencesthantheanalysisofonlythefinalsolutions.In2LIPtool,http://next-tell.eu/portfolios/learning-is-personal-lip/3Intelligenttutoringsystemisacomputersystemthataimstoprovideimmediateandcustomisedfeedbacktolearners.4Formoreinformationaboutabsoluteandrelativereferences,seehttps://edu.gcfglobal.org/en/excel2016/relative-and-absolute-cell-references/1/
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particular, the findings revealed that students not only struggled to solve the problemrequiringtheuseofabsolutereferences,butalsotheytriedtouseabsolutereferenceswhentheywerenotneeded.Thiswasnotdetectedwhenanalysingjustfinalassessmentdata.
All thissuggeststhatoncedata isunderstoodthroughdatamining itcanbeusedtomakedecisions in regard to when and how to intervene in the learning process. The study’simplicationshighlightthepotentialofmakingadaptationstoinstruction,providingfeedbackand remediation, and also improvements in the ability to diagnose knowledge gaps thatinfluence student comprehension. For researchers and practitioners there are severalchallengestobeconsideredwhenattemptingtoanalysestudents’misconceptions:
- Getting the rightdata isvital! (i.e., in theaforementionedcase, transactional leveldata)
- Whencollectingdata,meaningfuldataloggingproceduresshouldbeestablishedinadvance; this includes capturing pertinent data that can be linked to otherinformation, e.g., systems level data. At this point data must be extracted andanalysedmanually(Daviesetal.,2015).
6. Identifyingat-riskstudentsandpredictiveanalyticsTheidentificationofat-riskstudentshasreceivedmuchattentionandithasbeenfrequentlyassociatedwithaspecialcategoryof learninganalyticsnamedpredictiveanalyticswhich isfocusingspecificallyonthataspect.However,thenumberofinitiativesthathavebeenabletotransitionfromconcepttoimplementationisstillscare(Jayaprakashetal.,2014,Vibergetal.2018).TheCourseSignalsprojectatPurdueUniversity(Arnold&Pistilli,2012)isasuccessfulapplicationofpredictivemodelling to student completion inhighereducation.TheCourseSignals system has been developed on the idea that students do not have a goodunderstandingofhowtheyareprogressingintheirstudies/courses.Purduedevelopedtheirapproachto“earlywarningsystems”whichshowsat-riskstudentsoverseveralyears.
The predictive model used is based on four components: demographic characteristics,previousacademichistory,interactionwiththeLMS/VLEduringthecourseandperformanceon thecourse todate.Thepredictions fromthemodelare translated intoa signal:green,denotingahighchanceofsuccess;yellow,denotingpotentialproblems;orred,denotingahighchanceoffailure.Teachersrunthemodelandgeneratesignalsforthestudentsontheircourse.Theteachercanthenchoosewhat interventions to trigger: sendingapersonalisedemailor text,posting the signalon the LMS.PurduepilotedCourseSignals in2007and itbecameautomated in2009. In2012around24000studentsand145educatorshaveusedCourseSignalsinatleastoneofthecourses.Keypointsinclude:i)problemsareidentifiedasearly as the second week in the semester, iii) feedback is categorised as motivational orinformative, iii)studentsusingSignalsseekhelpearlierandmoreoften,and iv)oneofthestudy’sresultsshowed10%moreAsandBsweregivenforcoursesusingSignalscompareforpreviouscourseswhichdidnotusetheSignalssystem.Overall,studentslikedSignals:89%ofthemconsidereditapositiveexperienceandfoundthecombinationofthetrafficsignalsandinstructor feedback tobe informativeandmotivational.Anticipatedproblemswith Signalsincludedmaintaining theprivacyof teachingperformanceandensuring thevalidityof thealgorithm.Aspointedoutbytheearlierresearch(JICS,2017),severalissueshavetobetakenintoconsiderationwhendesigningandimplementingsimilarsystems:
• Studentsdidnotexpress concernsaboutprivacyabout theirdatabut thatdidnotmeanthattheinstitutionshouldnotneglecttoprotectit.
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• Institutions need to be able to extract data fromdifferent systems efficiently andtimely.
• Giventhecentralityofstudentsuccesstotheinstitutionalmission,learninganalyticseffortsmightbebetter initiatedandledfromaneducation-focusedunitthanfromtheIT-department.
Based on the success of the Signals systems, researchers at theMarist College in the US(Jayaprakashetal.,2014)implementedtheOnlineAcademicAnalyticsInitiative(OAAI)thataimedtohelpstudents,identifiedas‘needinghelp’,toengagetheminanonlinecommunitydesignedtohelpthemtosucceedacademically.TheOAAIdevelopedaprototypeofanopen-source academic earlier alert system that feeds from the Sakai CLE (Collaboration andLearningEnvironment),andincludesopenpredictivemodelbasedonthePentahoBusinessAnalytics suite (an open source analytics suite with data mining and data integrationcapabilities), and intervention strategies that leverage Open Educational Resources. Thepredictivegoalofthedevelopedsystemwastodetectearlythoseundergraduateswhowerein academic difficulty in the course by using student data. Four sources of data wereconsidered: i) studentdemographicandaptitudedata, ii) coursegradeandcourse relateddata, iii) Sakai-generated data on student interaction with the LMS and iv) partialcontributionstothestudent’sfinalgradecollectedbySakai’sgradebooktool,i.e.,gradesonspecificgradingevents,e.g.,assignmentsandexams.ThepilotswereruninSpring2012andFall2012.Studentidentifiedatrisk,weresubjectedto2interventionsstrategies:“AwarenessMessaging”andparticipatinginon“OnlineAcademicSupportEnvironment”.InonecourseatMaristCollegetherewasasignificantimprovementinfinalgrade(6%)withthoseat-riskstudentswhoweresubjecttoaninterventioncomparedwiththoseinthecontrolgroup,whowerenot.
7. LearningstrategiesDevelopingstudents’learningstrategiesandattitudesisintriguingbecauseitinvolveshigher-orderthinkingskillsonbehalfof thestudents, likeself-regulated learning(SRL)andcriticalthinking.While the importanceof SRL to learning is recognised,understandinghowSRL isappliedincontextisnotasimpletask(Roll&Winne,2015).Torealisethepotentialoflearninganalytics foradvancedof the learning sciences,weneed: i) todevelop instrumentation torecord traces of SRL across all its phases, ii) to develop and to testmethods that identifystructureswithindata,iii)toexploretheeffectsofinterventions(Roll&Winnie,2015).
Oneofthesuccessfulapplicationsoflearninganalyticstoimprovestudents’SRLskillsrefers to the study by Tabuenca et al. (2015). In this study, the researchers investigatedstudents’ timemanagement skills as thepart of their SRL, and in particular examined theeffectsoftrackingandmonitoringtimedevotedtolearnwithamobiletoolonSRL.26studentsenrolled intwoonlinecoursesfromtwouniversities intheNetherlandsparticipated inthestudy.TheLearnTrackerBackendDatabasemodelhasbeenused.Fromthestudentactivitypointofview,thesystemhoststhetimestampanddurationofthelearningactivity(formoreseeTabuencaetal.,2015).LearnTrackeroffersmobilesupportforstudentsenrolledinonlinecourses in which the learning goals are predefined by teachers. Courses deployed inLearnTracker are retrieved from the remote database at LearnTracker Backend. Similarly,time-logs are also recorded in the backened. LearnerTracker also provides social learninganalyticscontrastingthetimedevotedbythestudentwiththetimedevotedbyhispeers,aswellasthetimeoriginallyestimatedbytheteacher.Theexperimentaimedtoestimatehowaccurate estimations by instructional designers are with regard to the time needed to
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accomplisheachlearningactivityscheduledinacourse.Time-logsrecordsduringthecourseandthegradesobtainedinthefinalevaluationweretakenasindicator.Thestudy’sfindingsshowthatusingmobiledevicesto logandtrackthetimedevotedtostudyacrosscontexts(formalandinformal)mightleadtoanimprovementontimemanagementskillsandshowedthatnotificationspushedatrandomtimeofthedaydonotproducesignificantimprovementsintimemanagement.
Researchers have also examined the development of students' reflection skillsthroughagame-basedapproachcalledthe“TrailsofIntegrityandEthics”(TIEs;Kwongetal.,2017). A total of 658 students from four Hong Kong institutions participated in the studybetweenOctober2016toDecember2016.Thisapproachusesfocusedscenariosonethicaldilemmas - coupledwithAugmentedReality (AR)andmobile technologies - todesignTIEswherescenariosaretriggeredinvariouslocationsandstudentsarechallengedtoreviewtheargumentspresentedandreflectontheirethicalchoices.Inparticular,studentsplayedouttheconsequencesoftheirdecisionswhichhelpstrengthenthelinksbetweenthetheoreticalconceptofacademicintegrityandethicsaswellasthepracticalapplicationindailysettings.Contents of all scenarios are designed based in the 3C model, i.e., each decisionmakingscenariohastoincludeaChallenge,Choices,andConsequences.AllTIEsaredeployedusingamobileapplicationMobxz5,aservicedesignedspecificallyforlearningtrailsandsupportingbothiOSandAndroidsmartdevices.Studentsusetheirmobiledevicestowalkthroughatrailandactivatethe learningactivitieswithineachcheckpointscenariomarker-based(e.g.,QRcode)andmarker-less(e.g.,GPSlocationmapping),ARtechnologiesthatarebuilt-ininthismobile app. To evaluate the effectiveness of TIEs, triangulation of different data setswasadopted,includingexperiencesurveys,qualitativefeedback,clickstreamdataandtextminingofpre/post-traildiscussion.The results indicated that students’ interests in learningaboutissuesofacademicintegrityandethicsinclassroomswerestimulated.
Thisstudy-usingclickstreamdatacollectedfrommobiledevices-presentsanexampleoftheresearch, employed at scale, in the area of learning analytics and shows positive learningevidence.Suchstudiesarelimited(Chanetal.2015)andshouldbeenthusseenasexemplars.“WithenoughevidenceshowingstudentscaneffectivelylearntheconceptsofAIE[academicintegrity and ethics] using the TIEs [Trails of Integrity and Ethics], others in the educationsector,suchassecondaryschoolscanbeencouragedtogetinvolved”(Kwongetal.,2017,p.367).
8. LearninginasocialcontextWithrespecttodigitalisationofdata,learninginasocialcontextpinpointstheemergenceofsocial learning analytics (SLA). SLA emphases the concept of social network analysis onlearningactivitiesandemploysmethodsof learninganalytics to studentgroups insteadofindividualsasascopeforanalysisoflearningactivities(Hayaetal.,2015,p.303).FergusonandBuckinghamShum(2012)suggestfiveapproachestoSLA.
- Sociallearningnetworkanalytics:asuccessfulexampleofthiscategoryistheSNAPP6(SocialNetworksAdaptingPedagogicalPractice)tool,whichisavisualisationtoolforLMSforums.Itcanbeusedtoidentifydisconnectedstudentsandindicatetheextenttowhichalearningcommunityisdevelopingwithinavirtuallearningenvironment.
5Mobxz,https://mightysignal.com/a/ios/6182956476SNAPPtool,https://github.com/aneesha/SNAPPVis
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- Sociallearningdiscourseanalytics:anexampleistheCoheretool,7whichisawebapplicationprovidingamediumforengaginginstructuredonlinediscourse,orforsummarising/analysingit,e.g.asamoderator,educatororresearcher.Figure2showshowCohereaugmentscommononlinedialoguetext:theiconsatthesideofeachpostshowsrhetoricalroleofthepostandthesemanticconnectionstherhetoricalmovebetweenposts(DeLiddoetal.,2011).
- Sociallearningcontentanalytics:whenviewingonlineresources,SocialLearn’s‘Backpack’–atoolbarofappsandresources–canbeusedonanyInternetsite.TheBackpackcurrentlyincludesthebasiccomponentsofsociallearningcontentanalytics.Itprovides,amongothers,theoptionofviewingthekeywords,hotlinksorimagesconnectedwiththeopenwebpage.Inparticular,whenclickingintheBackpack’slightbulbiconprovidestheoptionofviewingthekeywords,hotlinksorimagesconnectedwiththeopenwebpage(asinthelargeboxontherightofFigure3).Theinformationaboutimagescanbemergedwithvisualsimilaritysearchtoidentifyandrecommendotherresourcesthatmakeuseoftheseimages,
Figure3.TheSocialLearnBackpackopenatthefootofaBBCNewspage,showingalistofimagesonthepage(adoptedfromFerguson&BuckinghamShum,2012)
- Sociallearningdispositionanalytics.Learningdispositionscanbemodelledasamulti-dimensional construct called Learning Power, currently assessed by learner self-report via aweb questionnaire called ELLI (Effective Lifelong Learning Inventory8),whose data warehouse platform supports a range of analytics (Ferguson &Buckingham Shum, 2012). ELLI generates a spider diagram visual analyticwhich isusedtosupportself-reflectionandchange.ELLIhasbeenvalidatedandpilotedattheOpenUniversity(UK;Edwards,2011).
- Implementingsociallearningcontextanalytics:theSocialLearnapprecommendsandprovides access to learningmaterials in response to search terms. The app allowsresourcestoberatedandrecommendedtoindividualsortogroups.Ifuserschoosetomaketheirlocationdataavailable,thiscanbeusedtoinfluencerecommendations;forexample,ifSimonisworkingon‘ClimateChange’theappmightsuggestapodcastoncoastaldefenceswhenhevisitsaseasideresort,andcouldprovideamapshowingalocalsitewhereSimonwouldbeabletoviewtheeffectsoferosion.
7Coheretool,http://cohere.open.ac.uk/8EffectiveLifelongLearningInventory,https://www.elli.global/
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Figure 4. Dialogues augmented with the Cohere tool
Hayaetal. (2015)demonstratedaSocialLearningAnalytics(SLA)toolkitthatappliessocialnetworkanalysisandcontentanalysistechniquesonforummessagestoanalysecollaborationamong students and to support teacher inquiry. The SLA toolkit was integrated in theJuxtaLearnlearningprocessandplatform(seeFigure5).
Figure5.LearningAnalytics-enhancedJuxtaLearnProcess(adoptedfromHayaetal.2015).
The authors adopted the Teacher-led Inquiry into Student Learning (TISL) pedagogicalapproachandpracticethatencouragesteacherstosystematicallyexaminetheeffectsoftheirlearning design on student performance and learning. Learning Design refers to “theapplication of methods, resources and theoretical frameworks to achieve a particularpedagogicalgoalinagivencontext”(p.302)andfromaLearningDesignpointofview,themain challenge lies in integrating design tools used for lesson planning with tools formonitoringandanalysis.
TheresearchpresentscasestudiesthatexemplifythekeyfeaturesoftheTISLapproachinthecontextofvideocreatedlearningscenarioandthekindofoutcomesthatcanbeobtained.Intheirstudy,Hayaetal.(2015)exploredthepotentialofcomputationalmethodstosupport
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teachersandlearnersparticipatingincollaborativescenarios.Theresearchersimplementedawebspacethatsupportsnetworksofpeople,contentandservicesbasedontheopen-sourcesocialplatformElgg(https://elgg.org).Thisspaceprovidesobject-orientedprogramming–thechosenforthisstudycourse–relatedcommunicationthroughvideosandensuingdiscussionsand comments. Theplatform supportsuploading, archivingand sharingof learner-createdcontent.Overall,thelearningprocessisgroundedinthestudentreflectioninthethreekeyareas:I)collaborativevideoproduction,ii)discussionandiii)peerevaluation.Discussionandevaluationaredirectlysupportedbythewebspace.
Thecasestudies’resultsshowthattheteacherscanderivevaluableinsightsintothestudents’learningactivitiesfromanalyticsresults.Theauthors(Hayaetal.,2015)exemplifyindicatorsforthequalityofcooperationpresentedbycommunication(seee.g.,Figure6)orportfoliodiagrams(seee.g.,Figure).
Figure6.Discussionnetwork Figure7.Reciprocity
Suchdiagramsallowforintroducingthresholdsforexpectedbehaviorindicatingtheneedforinterventiontoteachershowarenowfamiliarwiththesetypesofdiagrams.Forresearchersand learning designerswho become used to interpreting such diagrams they provide theopportunitytoobtaindetailedinformationaboutirregularitiesintheprocess,whichmayandinsomecases,shouldleadtoadaptations.Thecomplementingapplicationofcontentanalysismethods,hereNetworkTextAnalysishelpedtodetectfrequentmisconceptionsfromstudentcommentswhichinformlearningdesignersandteachersabouttopicsofinterests.Moreover,additionalindicators,suchasthesemanticrichnessmeasure,providethebasesforscaffoldingstudentstokeepfocusedonthedomain-relatedlearningtaskratherthanaimingatproducing‘perfect’ videos. In summary, the toolkit supportsmultiple levels of analysis that providedeeperinsightsintothecollaborativelearningprocess
Berlandetal.(2015)introducedAMOEBA,acollaborationorchestrationtooltosupportprogramminglearningactivitiesinhighschoolbysupportingteacherstopairstudentsbasedonrealtimeanalysesofstudents’programmingprogressions.TheresultsshowedthatusingAMOEBAtohelpwithpairingstudentsresultedinimprovementsinthecomplexityanddepthofthestudent’sprograms.
9. LearninganalyticsandlearningdesignThe interplay between learning analytics and learning design has recently attracted theinterest of researchers mainly for one reason: to check whether there are discrepanciesbetweenthestudents’actualbehaviourandtheteacher’s intentions,andinturn, tomakecorrectiveactions.Forexample,thestudyofNguyenetal.(2018)usedtracedatafromthe
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Moodle LMS to investigate to what extent students’ timing of engagements aligned withinstructor learning design, and how engagement varied across different levels ofperformance.Theanalysiswas conductedover30weeksusing tracedata (fromanonlinecourseattheOpenUniversity,UK)on387studentsandreplicatedovertwosemestersin2015and2016.
Thedataanalysiswasperformedviavisualisationsandmultilevelmodelling.Tounderstandtowhat extent do students’ timing of engagement align with instructors’ learning designvisualisationswereemployed.Firstly,actuallystudypattersagainstthelearningdesignwerevisualised. Secondly, the study patters for respective individual study materials acrossexcellent, passed, and failed group. The visualisations were conducted using JupyterNotebook9andTableau10.Tocomparestudypattersacrossthreegroupsofperformanceovertime,amultilevelmodelling(ormixed-effectmodelling)approachwasused.Thisapproach,compared to the traditional repeatedmeasure ANOVA approach, allows formissing data,tolerates differently spaced waves of data (e.g., due to Christmas break) and allows fornonlinearrelationships(Nguenetal.,2018,p.144).
Theirfindingsrevealedamismatchbetweenhowinstructorsdesignedforlearningandhowstudents studied in reality. Inmostweeks, students spent less time studying the assignedmaterials on the Moodle platform compared to the number of hours recommended byinstructors.Thetimingofengagementalsovaried,frominadvancetocatchinguppatterns.Highperformingstudents(i.e.,thepassedandtheexcellentgroups)spentmoretimestudyingin advance, while low-performing students spent a higher proportion of their time oncatching-up activities. Towards the end of the course, the gap between failed andpassed/excellentstudentsincreasedconsiderably.
In summary, by comparing and contrasting the assumptions in learning design made byinstructorswithactualstudentbehavior,learninganalyticscouldactasareflectivesourceandprovide actionable feedback.Onepotential implication of this study is if students tend tospendmoretimeoncatchingupaparticular learningmaterial, the instructorscouldcheckwhetherthematerialwasclearlyexplained,andprovideaquickreview.
Rodríguez-Trianaetal.(2015)presentthemonitoring-awaredesignprocess,whichdescribesthe steps that teachers should undertake during the design of computer-supportedcollaborative learning scenarios, inorder to reflecton theirmonitoringneedsandexpressexpectationsaboutstudents’ interaction.Fromalearninganalyticsperspective,monitoringexaminesstudents’interactionsduringtheenactmentofthelearningscenariosandfacilitatestheinterventiononthesituationtowardamoreproductivedirection(Rodríguez-Trianaetal.,2015).Theauthorsadoptthefollowinglearningdesign-awaremonitoringprocess:
1. Collectinteractiondata,guidedbytheunderlyinglearningdesign(e.g.,participants,resources,and/ordeadlines).
2. Createindicatorstoconstructamodelofdesiredinteraction(i.e.,students’interactionswiththelearningsystem)basedonthelearningdesigndefinitionandconstraints,andtheteachers’decisions.
3. Compareactualanddesiredstatesofinteractioni.e.,comparingthegatheredevidencewiththelearningdesigndefinitionandconstraints.
9https://jupyter.org10https://www.tableau.com
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4. Adviceorguidetheinteraction,byinformingteachersaboutdiscrepanciesabouttheactualandthedesiredstate.
Todeploythestrategymentionedabove,theauthorsusedanumberoftools;inparticular,First,theWeb-Collagetool11tocreatethelearninginadigitalformat;then,theGLUE-PS12tool(i.e.,GroupLearningUnifiedEnvironment-PedagogicalScripting) -usedbytheteachers-deployedautomaticallythedesignintothedistributedlearningenvironments,i.e.,differentexistingVirtual Learning Environments (e.g.,Moodle); and a custom-made third tool, theGroup Learning Interaction Monitor for Pedagogical Scripting Environments (GLIMSE)prototype,totrackandreporttheinteractionstakingplaceintheLMSplatform.GLIMSEtookthescriptinstantiationfilegeneratedbyGLUE-PSandtheXMLversionoftheformstoguidethedatagatheringandanalysis.
In summary,we have provided several relevant examples thatmight be applicable in theSwedishcontext,but tobeable tounderstand furtherhow learninganalyticscan improvedifferentaspectsoflearningprocessandlearningoutcomes,practitionersneedtoconsiderseveral important questions such as:What problems do we want to solve?What learneractivitiesdowewanttosupport?Whatkindofdata,thatwemay,ormaynothavetoday,wouldbevaluabletoanalyse?Howtheavailablemethodsandtoolsthatareapplicableononeeducationalcontextberelevantandusefulinanothercontext?Whatarethechallenges?Arethereanyimportantethicalconsiderationsthatshouldbetakenintoaccount?
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