intelligent transportation systems for improving … transportation systems for improving traffic...
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IntelligentTransportationSystemsforImprovingTrafficEnergyEfficiencyandReducingGHGEmissionsfromRoadways
November 2015
AWhitePaperfromtheNationalCenterforSustainableTransportation
MatthewBarth,GuoyuanWu,andKanokBoriboonsomsin
CenterforEnvironmentalResearchandTechnology
BournsCollegeofEngineering
UniversityofCalifornia,Riverside
U.S.DepartmentofTransportation(USDOT)DisclaimerThecontentsofthisreportreflecttheviewsoftheauthors,whoareresponsibleforthefactsandtheaccuracyoftheinformationpresentedherein.ThisdocumentisdisseminatedunderthesponsorshipoftheUnitedStatesDepartmentofTransportation’sUniversityTransportationCentersprogram,intheinterestofinformationexchange.TheU.S.Governmentassumesnoliabilityforthecontentsorusethereof.AcknowledgmentsThisstudywasfundedbyagrantfromtheNationalCenterforSustainableTransportation(NCST),supportedbytheU.S.DepartmentofTransportation(U.S.DOT)throughtheUniversityTransportationCentersprogram.TheauthorwouldliketothanktheNCSTfortheirsupportofuniversity-basedresearchintransportation,andespeciallyforthefundingprovidedinsupportofthisproject.Theauthorswouldalsoliketoacknowledgeothersourcesforvariousmaterials,bothinresearchsupportandfunding,includingtheCaliforniaDepartmentofTransportation,andtheU.S.DOT’sApplicationsfortheEnvironment:Real-timeInformationSynthesis(AERIS)connectedvehicleresearchprogram.Lastly,theauthorswouldalsoliketoacknowledgeXueweiQioftheUniversityofCalifornia,Riversideforhisassistanceingatheringinformationusedinthiswhitepaper. AbouttheNationalCenterforSustainableTransportationTheNationalCenterforSustainableTransportationisaconsortiumofleadinguniversitiescommittedtoadvancinganenvironmentallysustainabletransportationsystemthroughcutting-edgeresearch,directpolicyengagement,andeducationofourfutureleaders.Consortiummembersinclude:UniversityofCalifornia,Davis;UniversityofCalifornia,Riverside;UniversityofSouthernCalifornia;CaliforniaStateUniversity,LongBeach;GeorgiaInstituteofTechnology;andUniversityofVermont.Moreinformationcanbefoundat:ncst.ucdavis.edu.
TABLEOFCONTENTSEXECUTIVESUMMARY....................................................................................................................1
Introduction....................................................................................................................................3
ITSandTheirImpactonTrafficEnergyandEmissions...................................................................3
VehicleSystems..........................................................................................................................3
TrafficManagementSystems.....................................................................................................4
TravelInformationSystems........................................................................................................5
ImpactofITSonTrafficEnergyandEmissions...........................................................................5
RecentEnvironmentalITSResearchProgramsintheUnitedStates..............................................6
Eco-TrafficSignalOperations.....................................................................................................7
Eco-LanesOperations.................................................................................................................9
RecentEnvironmentalITSResearchProgramsintheEuropeanUnion.......................................10
VehicleSystems........................................................................................................................10
TrafficManagementSystems...................................................................................................11
TravelInformationSystems......................................................................................................11
ResearchNeeds............................................................................................................................12
Environment-Mobility-SafetyNexus........................................................................................12
InducedTravelDemand...........................................................................................................12
Conclusions...................................................................................................................................12
References....................................................................................................................................14
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IntelligentTransportationSystemsforImprovingTrafficEnergyEfficiencyandReducingGHGEmissionsfromRoadways
EXECUTIVESUMMARYThefieldofIntelligentTransportationSystems(ITS)haswitnessedsignificantlyincreasedactivityinrecentyears,withtheapplicationofmoderncontrol,communications,andinformationtechnologiestovehiclesandroadwayinfrastructure.Ingeneral,ITScanbecategorizedintothreemajortargetareas:VehicleSystems,TrafficManagementSystems,andTravelInformationSystems.TheprimaryobjectivesofITShavebeenfocusedprimarilyonimprovingsafetyandincreasingmobilityandassociatedtransportationefficiency.Inaddition,itisnowwellknownthatITStechnologycanbeusedtoreducetransportation-relatedenvironmentalimpacts.Theseenvironmentalimpactsincludepollutantemissionsthatleadtopoorairquality,aswellasenergyconsumptionandgreenhousegas(GHG)emissions.Overtheyears,wehaveseenmanyITSprogramsfocusingonsafetyandmobilityalsohavingsignificantenvironmentalbenefits.Thesebenefitsrangewidelyduetoanumberofvariablessuchastypeofapplication,technologyused,andpre-existingconditionbeforedeployment.Inrecentyears,anumberofITSprogramshaveemergedthatarespecificallydesignedtominimizetheenvironmentalimpactsoftransportation.Manyoftheseenvironmental-ITSprogramstakeadvantageofthe“connectedvehicle”technologythatenablesvehiclestocommunicatewitheachotheraswellaswithroadwayinfrastructure,andviceversa.Theseenvironmental-ITSprogramstypicallyshowenergyandemissionsreductionsontheorderof5%to15%.
KeyFindingsManyITSprogramsfocusingonsafetyandmobilityalsoprovidesignificantenvironmentalbenefits.Thesebenefitsrangewidelyduetoanumberofvariablessuchastypeofapplication,technologyused,andpre-existingconditionbeforedeployment.Recentlyemergedenvironmental-ITSprogramsthatarespecificallydesignedtominimizetheenvironmentalimpactsoftransportationhavebeenshowntoreduceenergyandemissionsontheorderof5%to15%.Currentenvironmental-ITSresearchprogramsintheUnitedStatesandtheEuropeanUnionarefocusedondevelopingandtestingapplicationsthattakeadvantageof“connectedvehicle”technology,whichenablesvehiclestocommunicatewitheachotheraswellaswithroadwayinfrastructure,andviceversa.Researchisneededtoimproveourunderstandingoftheconnectionbetweenenvironment,mobility,andsafetyperformanceofanyITSprograms.ResearchisalsoneededtoquantifythepotentialinduceddemandeffectsofITSprogramdeployment.
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Mostoftheenvironmental-ITSprogramsareadditive,thereforegreaterbenefitsmaybeachievedwhenamultitudeoftheseprogramsareputintoplace.Ontheotherhand,themobilityandsafetyimpactsofenvironmental-ITSprogramsarenotcurrentlywellunderstood.Asmoreoftheseprogramsaredeployed,comprehensiveimpactassessmentsoftheirenvironmental,mobility,andsafetyperformancesareneeded.WhenplanningthedeploymentofITSprogramsthatwillimprovetrafficflowandreducecongestion,itisimportanttoalsoconsideranypotentialinduceddemandeffects,whichmayresultinanoverallincreaseinvehiclemilestraveled(VMT)aftertheITSprogramshavebeendeployedforacertainperiodoftime.SuchincreaseintheamountoftravelisundesirableasitmaywashoutthemobilityandenvironmentalbenefitsoftheITSprograms.Itmaybethattocounteracttheseeffects,theITSprogramsmayhavetobecoupledwithsomespecifictraveldemandmanagementmeasuressuchaspricing.
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IntroductionDuetotheirpotentialtoimproveroadwaysafety,reducetrafficcongestion,andenhancethemobilityofpeopleandgoods,IntelligentTransportationSystems(ITS)havegeneratedconsiderableenthusiasminthetransportationcommunity.Inadditiontoenhancingsafetyandmobility,wearenowseeingthatITScanplayamajorroleinreducingcriteriapollutantandgreenhousegas(GHG)emissions,andenergyconsumption.Itiscommonlyunderstoodthatthetransportationsectorisresponsiblefornearlyone-thirdofGHGemissions(see,e.g.,(1)).InordertoreducetheseGHGcontributions,muchofthefocushasbeenputon:1)improvingoverallvehiclefueleconomy(e.g.,usingmoreefficientinnovativedrivetrains,reducingweightwhilemaintainingsafety);2)usinglesscarbon-intensivefuels(e.g.,ethanol,electricity);and3)managingtraveldemand(e.g.,roadwaytolling)andshiftingtraveltonon-motorizedmodes.Inaddition,wearenowseeingthatITScanbeappliedasafourthkeycomponent,namelytoimprovetheefficienciesoftransportationsystemoperations,therebyreducingoverallGHGemissions.
ITSandTheirImpactonTrafficEnergyandEmissionsITSconsistsofawidevarietyoftechnologiesandapplications,asdescribedintheU.S.NationalIntelligentTransportationSystemArchitecture(2).Ingeneral,ITScanbecategorizedintothreemajorareas:VehicleSystems,TrafficManagementSystems,andTravelInformationSystems.TheseareasandtheirpotentialforreducingGHGemissionsarebrieflyintroducedbelow.
VehicleSystemsVehiclesarenowtakingadvantageofmoderncontrolsystems,fasteron-boardprocessors,andwirelesscommunicationstoprovidefeaturesthatgreatlyimprovetheirperformance.Examplesofemergingvehiclesystemsincludethefollowing:LongitudinalAssistanceSystemsaretypicallyusedtopreventfront-endandrear-endcollisions.On-boardradar,LiDAR,andcomputervisiontechnologymonitorheadwaysbetweenvehicles,andbyprovidingfeedbacktothevehicle’sbrakingsystem,canhelpreducecollisions.ThesesensorsarealsobeingusedforAdaptiveCruiseControl(ACC)systemsthatnotonlyallowadrivertoselectadesiredspeed,butalsoallowsettingthefollowingdistance.Withtheadditionofwirelesscommunicationcapabilities,ACCcanevolveintoCooperativeAdaptiveCruiseControl(CACC)wherevehiclescommunicatewitheachotherto“cooperatively”managefollowingdistance,braking,accelerating,andmore.CACCisnowemergingasapopularareaofresearch.LateralAssistanceSystemsaredesignedtoimprovetheperformanceofvehiclesduringlanechanges,merges,oranykindofturningmovement.Computervisiontechnologyandothersensorscoupledwithwirelesscommunicationsarebeingdeployedtoprovidelanedeparturewarningsandtowarndriversofpendinglateralcollisions.
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Bothlongitudinalandlateralcontrolsystemsarenowleadingusdownthepathtowardspartialandfullautomation,wherevehicleswillautomaticallydrivethemselveswithlittleinputfromthedrivers.WirelessCommunicationsSystemsarenowbeingdeployedinvehiclesinanumberofdifferentways.Cellularcommunicationtechnologyisalreadyplayingalargeroleinfleetmanagementapplicationsandvehiclemonitoring.Inaddition,DedicatedShortRangeCommunication(DSRC)radioswilllikelybedeployedtoenablevehicle-to-vehicle(V2V),vehicle-to-infrastructure(V2I)andinfrastructure-to-vehicle(I2V)applicationsthatareprimarilyfocusedonimprovingsafety.However,mobilityandenvironmentalapplicationswillalsolikelyemergethattakeadvantageofthis“connectedvehicle”technology.
TrafficManagementSystemsOverthelastseveraldecades,thetotalamountofdriving,asmeasuredinVMT,hasgrownsignificantly,contributingtosevereroadwaycongestioninmanyurbanareas.Buildingadditionalinfrastructuretohandletheincreaseintraveldemandisnotalwayspossible.However,anumberofITS-basedTrafficManagementSystemsolutionscanhelpmitigatecongestion,includingthefollowing:TrafficMonitoringSystemsareimprovingwithbettersensortechnology,morereliablecommunicationchannels,andmoreadvancedinformationprocessingcapability.Inadditiontoprovidingtransportationmanagerswithbetterreal-timeinformation,newdataprocessingtechniquesarebeingdevelopedtoestimatetrafficflow,density,andspeed,aswellasothermicroscopictrafficparameters.Thisreal-timetrafficinformationcanbeusedforbettertrafficsystemmanagementandforindividualdriverschoosingalternativeroutes,resultinginreducedcongestion.TrafficIncidentManagementtechniquesareimportanttoolsforearlydetectionandrapidremovalofincidents(i.e.,accidents,disabledvehicles,etc.),sothatnormaltrafficoperationsrecoverasquicklyaspossible.IntegratedCorridorManagementtechniques,suchasinnovativerampmeteringforfreewayaccessramps,andadvancedsignaltimingalgorithmsonarterialnetworks,worktogethertohelpkeeptrafficflowingassmoothlyaspossiblethroughthecorridor,greatlyreducingtheamountofidling.TravelDemandManagementisanothercriticalelementoftrafficmanagement.Byreducingthenumberofvehiclesonacongestedroadwayorspreadingoutthepeakoftrafficvolumethroughpricingandothertechniques,trafficflowwillimprove,resultinginlowerGHGemissions.
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Theoverarchinggoaloftrafficmanagementistotakefulladvantageofcapacitiesofexistingroadwayinfrastructure,thuskeepingtrafficflowingsmoothlyatmoderatespeeds.Assuch,thiswillhavealargeimpactinreducingenergyconsumptionandGHGemissions.Trafficmanagementsystemstrategiesgoevenfurtherbyreducingthenumberofvehiclesinthetransportationsystem,therebyreducingthetotalcontributionsofGHGemissions.
TravelInformationSystemsTomakethingsmoreconvenienttodrivers,awidevarietyofinformationsystemsfortravelershaverecentlyevolved.Examplesofthistechnologyincludethefollowing:RouteGuidanceSystemshavegreatlyimprovedinrecentyears.Theyincludeon-board,off-board,andsmartphone-basedsystems.Thesenavigationsystemsnowusegeographicandreal-timetrafficinformationandcanselectoptimalroutesinaroadwaynetworkfromspecificoriginstospecificdestinations.Thesesystemsattempttominimizesomecriteria,suchastraveltime,traveldistance,orevenGHGemissions.Geo-LocationSystemsaretypicallycoupledwithrouteguidancesystemstoallowuserstofindspecificlocations,cuttingdownonexcessivedriving(e.g.,searchingforagasolinefillingstation,openparkingspace,etc.).ElectronicPaymentSystemsarebecomingincreasinglyprevalent.Theyenablepaymentoftollsandfeeswithoutstoppingthevehicletocompletethefinancialtransaction.AllofthesesystemsaddconvenienceforthetravelerwhilereducingGHGemissions.Asdescribedabove,arouteguidancesystemwillcutbackonunnecessarytravelthatmayoccurwhenadrivergetslostorchoosesalong,out-of-the-waypath.En-routedriverinformationcanresultinreducedGHGemissionsassociatedwithdrivingaround,searchingforthesespecificgoals.Electronicpaymentsystemseliminatetheneedforadrivertodeceleratethevehicle,idlewhileamanualtransactiontakesplace,thenacceleratethevehiclebacktoadesiredspeed.Ifthispaymentcanoccurwithoutslowingdown,GHGemissionsarereduced.
ImpactofITSonTrafficEnergyandEmissionsAlloftheITSareasdescribedabovehavethepotentialforindirectlyreducingGHGemissionsthroughimprovementsinsafety,mobility,anddriverconvenience.TheactualGHGemissionreductionswillvarysignificantly,dependingonmanyfactors,includingvehiclefleetmix,trafficvolumeanddynamics,andthetypeofroadwaynetworkandinfrastructure.AvarietyoftheseITSapplicationshavebeendesignedandmodeled,andseveralhavebeenpilotedandimplementedindifferentlocations.Inordertodeterminetheoveralleffectivenessoftheseapplications,differentperformancemeasuresareestimated–usuallymobilitymeasuressuchasimprovementsinaveragetraveltimeorreductionsinnetworkdelay.Insomecases,environmentalfactorsarealsoestimated.Onestraightforwardmethodistomonitorthechangesinaveragetraveltimes(andthereforeaveragespeeds),normalizedbythetotalamountoftraffic.Ingeneral,ifoveralltrafficconditionsmovefromacongestedregime(e.g.,
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averagespeedsbelow30mph)toalesscongestedregime(speedsgreaterthan30mph),thenemissionreductionspervehiclecanbeestimatedusingspeed-emissionfactorcurves,suchasFigure3of(3).Asanexample,trafficsmoothingtechniqueshavebeenshownin(4)toresultina10%to20%CO2reduction.InadditiontotheITSapplicationsdescribedabove,anumberofITSresearchprogramshaveemergedthathavebeenspecificallydesignedtominimizetransportationGHGemissions.ThenextsectionofthiswhitepaperdescribesseveraloftheserecentITSprogramsthataretargetingtheenergyandenvironmentalimpactsoftransportation.
RecentEnvironmentalITSResearchProgramsintheUnitedStatesInthelastdecade,theU.S.DepartmentofTransportation(U.S.DOT)hasinitiatedavarietyofenvironmentallyfocusedITSresearchprograms.ManyofthesearepartoftheFederalHighwayAdministrationExploratoryAdvancedResearchprogram(FHWAEAR,see(5)).Asanexample,intheITSvehiclesystemsarea,researchersattheUniversityofCalifornia,BerkeleyhaveinvestigatedbothACCandCACCandtheirimpactsonmobilityandtheenvironment(6).Furthermore,asanexampleintheareaoftrafficmanagementsystems,thereisanongoingEARprojectonAdvancedTrafficSignalControlAlgorithms,whereseveralalgorithmshavebeendevelopedspecificallyforreducingenergyuseandemissions(see,e.g.,(7)).ResultsfromthesestudiesshowGHGemissionreductionsintherangeof5%to10%.InadditiontotheEARprogram,theU.S.DOThasamajorUniversityTransportationCentersprogram(UTC,see(8)),whereuniversityfaculty,staffandstudentsacrosstheU.S.workonanumberofadvancedtransportationresearchprojects.AnumberofUTCsfocusonsustainability,andseveralofthoseareinvestigatingtheenvironmentalimpactsofITS(see,e.g.,(9)and(10)).Someexampleprojectsfromthesecentersincludeexaminingeco-drivingtechniquesandfreightsignalpriorityforheavy-dutyvehicles(typically5%to8%reductions,seee.g.,(11)),andhowvariablespeedlimitscanbeusedtoreducetransportationenergyconsumptionandimprovevehiclemobility(12).Asanothermajoreffort,theU.S.DOThasalong-termresearchprograminconnectedvehicles.OneofthefoundationalelementsoftheconnectedvehicleresearcheffortintheenvironmentareaistheApplicationsfortheEnvironment:Real-timeInformationSynthesis(AERIS)program(13).Usingvehicle-to-vehicle(V2V),vehicle-to-infrastructure(V2I)andinfrastructure-to-vehicle(I2V)communications,thegoaloftheAERISprogramistodesignITSapplicationsthataimtoreduceenergyconsumptionandemissions.SeveralAERISoperationalconceptshavebeendeveloped,including:1)Eco-SignalOperations;2)Eco-Lanes;3)DynamicLowEmissionsZones;4)SupportforAlternativeFuelVehicle(AFV)Operations;5)Eco-TravelerInformationand6)Eco-IntegratedCorridorManagement(ICM).
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EarlyintheAERISprogram,severalexploratoryresearchprojectsconductedbyanumberofU.S.researchersinvestigatednewconceptsacrossthedifferentareasofITS,includingthefollowing:
VehicleSystems• DevelopingandEvaluatingIntelligentEco-DriveApplications,carriedoutbyresearchers
atVirginiaTech(14).Thisprojectfocusedonthedevelopmentofaneco-ACCsystemandevaluatedthenetwork-wideimpactsofsuchsystemsfordifferentlevelsofmarketpenetrationandnetworkconfigurations.ResultsshowedGHGemissionreductionsupto49%.
• Assessment,Fusion,andModelingofCommercialVehicleEngineControlUnitData,carriedoutbyCalmarTelematics(withUCRiverside)(15).Thisprojectinvestigatedtheuseofreal-time,onboarddatatocalculateenvironmentalperformancemeasuresbasedpartlyupontheteam’sComprehensiveModalEmissionsModel(CMEM).
TrafficManagementSystems• Eco-SpeedControlUsingV2IcommunicationsalsocarriedoutbyVirginiaTech(14).In
thisproject,innovativeeco-adaptivesignalcontrolalgorithmsweredevelopedandtested.Thesesystemsweremodeledusingtrafficsimulationsoftwareandtestedfordifferentroadwayconfigurations.
• Eco-FriendlyIntelligentTransportationSystems(ECO-ITS),carriedoutbyUCRiverside(16).ThisprojectbuiltonpreviousECO-ITSresearchinpredictingsecond-by-secondfuelconsumptionandtailpipeemissionsfordifferentenvironmental-ITSapplicationsandstrategies,suchasadvancedtrafficsignalization.
TravelInformationSystems• AnEvaluationofLikelyEnvironmentalBenefitsofLowestFuelConsumptionRoute
GuidanceintheBuffalo-NiagaraMetropolitanArea,carriedoutbytheUniversityatBuffalo(17).Thisstudyassessedthelikelyenvironmentalbenefitsofanewapplicationforanenvironmentallyoptimizedrouteguidancesystemformedium-sizedmetropolitanareas.ResultsshowedGHGemissionreductionsintherangeof5%to10%.
Aftertheseinitialexploratoryprojects,theAERISoperationalconceptswerefurtherdevelopedanddefined.ThemainAERISapplicationsthatwereevaluatedindetailaretheEco-TrafficSignalOperationalconcept,includingtheapplicationsofEco-ApproachandDepartureatSignalizedIntersections,Eco-TrafficSignalTiming,andEco-TrafficSignalPriority,aswellastheEco-LanesOperationalconcept,whichincludestheapplicationsofEco-SpeedHarmonizationandEco-CooperativeAdaptiveCruiseControl.Theseapplicationsaredescribedinfurtherdetailbelow.
Eco-TrafficSignalOperationsTherehasbeenagooddealofresearchineco-trafficsignaloperationsaroundtheworld.TheseoperationsuseITStechnologiestodecreasefuelconsumptionandGHGemissionsonarterialroadwaysbyreducingidling,thenumberofstops,andunnecessaryaccelerationsand
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decelerationsatsignalizedintersections.Priortotheemergenceofconnectedvehicles,eco-trafficsignaloperationswereprimarilyfocusedonsynchronizingtrafficsignalstoimprovetrafficflow,therebyreducingGHGemissions.BytakingadvantageofV2I/I2Vcommunications,anumberofothersignalizationstrategiesemerge,threeofwhicharedescribedbelow.Eco-ApproachandDepartureatSignalizedIntersections—Thisapplicationuseswirelessdatacommunicationssentfromthetrafficsignalcontrollertoconnectedvehiclestoencourage“green”approachestosignalizedintersections.ThisincludesbroadcastingSignalPhaseandTiming(SPaT)dataandaGeographicInformationDescription(GID)orMAPdata.Vehiclestatusmessages,sentfromnearbyvehiclesusingV2Vcommunications,arealsoconsideredbytheapplication.Uponreceivingthisinformation,anon-boardprocessorcanthencalculateanoptimalspeedtrajectorytoapproach,passthrough,anddepartfromasignalizedintersection.Thisspeedtrajectorycanbeprovidedasadvicetothedriverthroughahuman-machineinterface,ordirectlytothevehicle’slongitudinalcontroller(suchastheACCsystem).Thegeneralstrategyistohavethevehiclechangeitsspeedtopasstheupcomingtrafficsignalongreenortodeceleratetoastopinthemosteco-friendlymanner.Thisapplicationalsoconsidersavehicle’saccelerationasitdepartsfromasignalizedintersectionandenginestart-stoptechnologyasavehicleisstoppedatatrafficsignal.Intermsofresults,theAERISprogramhasshownthatthereisa2%to7%energysavingsforallvehiclesandthattheapplicationislesseffectivewhenthecorridoriscongested(see,e.g.,(18),(19)).Eco-TrafficSignalTiming—Thisapplicationissimilartocurrentadaptivetrafficsignalsystems;however,theapplication’sobjectiveistooptimizetrafficsignalsfortheenvironment.Theapplicationcollectsdatafromvehicles,suchasvehiclelocation,speed,GHGandotheremissionsusingconnectedvehicletechnologies.Itthenprocessesthesedatatodevelopsignaltimingstrategiesthatarefocusedonreducingfuelconsumptionandoverallemissionsatanintersection,alongacorridor,orforaregion.Theapplicationevaluatestrafficandenvironmentalparametersateachintersectioninrealtimeandadaptssothatthetrafficnetworkisoptimizedusingavailablegreentimetoservetheactualtrafficdemandswhileminimizingtheenvironmentalimpact.Intermsofresults,theAERISprogramhasshownthatthereisa1%to5.5%energysavingsandthattheapplicationiseffectiveinmostconditionsotherthanfullsaturation(20).Eco-TrafficSignalPriority—Thisapplicationallowseithertransitorfreightvehiclesapproachingasignalizedintersectiontorequestsignalpriorities.Thisapplicationconsidersthevehicle’slocation,speed,vehicletype(e.g.,AlternativeFuelVehicles)andassociatedGHGandotheremissionstodeterminewhetherpriorityshouldbegranted.Informationcollectedfromvehiclesapproachingtheintersection,suchasatransitvehicle’sadherencetoitsschedule,orthenumberofpassengersonthetransitvehiclemayalsobeconsideredingrantingpriority.Ifpriorityisgranted,thetrafficsignalwouldattempttoholdthegreenorterminatetheredontheapproachtofacilitatethetransit/freightvehiclepassingthroughtheintersectionwithoutstopping.Thisapplicationdoesnotconsidersignalpreemption,whichisreservedfor
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emergencyresponsevehicles.Intermsofresults,theAERISprogramhasshownthatthereisa1%to4%energysavingsforallfreightvehiclesanda1%to2%savingsfortransitvehicles(20).
Eco-LanesOperationsThisconceptusesconnectedvehicletechnologiestodecreasevehiclefuelconsumptionandemissionsbyreducingcongestionandunnecessaryaccelerations/decelerations,improvingtrafficflow,andencouraginggreenerdrivingbehavior.Itisenvisionedthatthiscouldoccureitheronasinglelaneoracrossmultiplelanesonafreeway.ThisEco-Laneconceptcanconsistofanumberofdifferentapplicationsthatarespecificallysetupforafreewayscenario:Eco-LanesManagement—Thisapplicationsupportstheoperationofdynamiceco-lanes,includingestablishingqualificationsforenteringthelanes,definingactivationperiodsorgeo-fencingtheeco-lanes’boundaries.Eco-SpeedHarmonization—TheEco-SpeedHarmonizationapplicationassistsinsmoothingtrafficflow,reducingunnecessarystopsandstarts,andmaintainingconsistentspeeds,thusreducingfuelconsumption,GHGs,andotheremissionsontheroadway.Thiscanbeaccomplishedtypicallythroughvariablespeedlimits.Eco-CooperativeAdaptiveCruiseControl—TheEco-CooperativeAdaptiveCruiseControlapplicationallowsindividualdriverstooptintoapplicationsthattakeadvantageofadaptivecruisecontrolcapabilitiesalongwithV2Vcommunicationsdesignedtominimizevehicleaccelerationsanddecelerationsforthebenefitofreducingfuelconsumptionandvehicleemissions.Eco-RampMetering—TheEco-RampMeteringapplicationdeterminesthemostenvironmentallyefficientoperationoftrafficsignalsatfreewayon-rampstomanagetherateofvehiclesenteringafreeway.ConnectedEco-Driving—TheConnectedEco-Drivingapplicationprovidescustomizedreal-timedrivingadvicetodriverssothattheycanadjusttheirdrivingbehavior(e.g.,speedoftravel,accelerationanddecelerationrates)tosavefuelandreduceemissions.Multi-ModalTravelerInformation—TheMulti-ModalTravelerInformationapplicationprovidespre-tripanden-routemultimodaltravelerinformationtoencourageenvironmentallyfriendlytransportationchoices.IntheUnitedStates,theAERISprogram’sEco-Lanesconceptmodelingwasfocusedonlyontheeco-speedharmonizationandeco-cooperativeadaptivecruisecontrolapplication(21).Usingasophisticatedsetofsimulationmodelingtools,itwasshownthatundertheassumptionof100%penetrationrate,eco-speedharmonizationcouldresultinupto12%energysavings,butwithan8%reductioninmobility(i.e.,longertraveltimes).However,whentunedsothatmobilitywasunaffected,thentheenvironmentalbenefitswerearound5%.Ontheotherhand,
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eco-cooperativeadaptivecruisecontrolwasshowntoprovideupwardsof30%energysavingsforagenericfreewaysegment.Whenappliedtoaregularfreewaywithon-andoff-ramps,thesavingswerearound15%.
RecentEnvironmental-ITSResearchProgramsintheEuropeanUnionIn2011,theEuropeanUnion(EU)setupWorkingGroupforCleanandEfficientMobility(WG4CEM)aspartoftheiMobilityForumwiththeaimtoidentifymostpromisingITSsolutionsforcleanandefficientmobility.Oneofthegroup’stasksistoprovideaprioritizedlistofrecommendedITSenvironmentalprojectsandaroadmapillustratingthepathwaysofresearch.ThisEuropeanworkinggroupconsistsofmembersfromroadauthorities/roadoperators,roadusersandautomotiveandinformationandcommunicationstechnology(ICT)industrystakeholdersinterestedincleanandefficientmobility.Connectedvehiclesandinfrastructurewereasubsetoftheproposedsolutions.Theresultsofthiseffortcanbefoundin(22).Inthissection,onlysomeofthemajorITSprojectsaimedatreducingGHGemissions,andinparticularthoseinvolvingconnectedvehicles,arehighlighted.Manyoftheseprojectswerefundedbyvarioussources,includingtheEuropeanCommission(EC),theEuropeanCommissionDirectorateGeneralforCommunicationsNetworks,Content&Technology(DG-CONNECT),theEuropeanUnion’sSeventhFrameworkProgramforResearch(FP7),andtheEUCompetitivenessandInnovationFrameworkProgramanditsPolicySupportProgram(CIP-PSP).TheseprogramsarecategorizedintothethreemajorITSareas.
VehicleSystemsTheEUcarriedoutamajorprograminconnectedvehiclescalled“eCoMove”whichwasfocusedon“cooperativemobilitysystemsandservicesforenergyefficiency.”ThisprogramexaminedthelatestV2I/I2VandV2Vcommunicationtechnologies,andcreatedanintegratedsolutioncomprisingeco-drivingsupportandeco-trafficmanagementtotacklethemainsourcesofenergywastebypassengerandcommercialvehicles.TheeCoMoveprojecttargetedthreemaincausesofavoidableroadtransportenergyuseinordertominimizefuelwaste:1)inefficientroutechoice;2)inefficientdrivingperformance;and3)inefficienttrafficmanagementandcontrol.Overall,theeCoMoveprojectshowedfuelsavingsofaround10%to20%foreco-drivingandapproximately10%savingsfortrafficsignaloperations(23).AnotherimportantprojectwastheECOSTANDproject,ajointEU-Japan–U.S.taskforcetodevelopastandardmethodologyfordeterminingtheimpactsofITSonenergyefficiencyandcarbondioxide(CO2)emissions.TheoverallgoalwastoprovidesupportforanagreementbetweenthethreeregionsonaframeworkforacommonassessmentmethodologyforquantifyingtheimpactsofITSonenergyefficiencyandCO2emissions(24).Currently,Compass4Disanongoingmulti-cityprojectinEuropethatisfocusedondeployingadvancedvehiclecooperativesystemstoimproveroadsafetyandenergyefficiencyandtoreducecongestion.Thisthree-yearEUco-fundedproject(startedinJanuary2013)isdeploying
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threeservicesinsevencities(Bordeaux,Copenhagen,Helmond,Newcastle,Thessaloniki,VeronaandVigo),inordertoprovetheconcretebenefitsofcooperativesystemsforcitizens,cityadministrationsandcompanies.Compass4Dispilotingthreemainservices:aredlightviolationwarning,aroadhazardwarning,andenergy-efficientintersections.Theseservicesareinplaceforoneyearon334vehicles,includingbuses,taxis,emergencyvehicles,andprivatecars,reachingmorethan550users(25).Resultsonenvironmentalimpactsarepending.
TrafficManagementSystemsTheCooperativeSystemsforSustainableMobilityandEnergyEfficiencyorCOSMOprojectadoptedasystem-wideapproachtotheassessmentofenergyefficiency,measuringtheeffectofarangeofinnovativetrafficmanagementsystemsnotonlyonfuelconsumptionandemissionsofvehicles,butalsoontheenergyusedtooperateroadsideequipment.Theaimwastoprovideapracticaldemonstrationoftheeffectivenessofthesystemsandtoassesstheirimpactunderrealisticconditions.Theprincipalresultwasasetofvalidatedspecificationscoveringtheiroperational,technical,businessandorganizationalcharacteristics.TheCOSMOtestsiteswereinSalerno,ViennaandGothenburgandranfrom2010to2013(26).Ingeneral,CO2emissionreductionswereshownontheorderof5%to15%.TheCooperativeNetworkedConceptforEmissionResponsiveTrafficOperationsorConCERTOprojectwascarriedoutfrom2010through2013andusedhighlysophisticatedenvironmentaltoolstodevelopnext-generationtechnologiestoreducemotorvehicleemissionsbasedonreal-timeemissionmeasurements(27).TheCARBOTRAFprojectiscurrentlyunderwayandisfocusingondeveloping“ADecisionSupportSystemforReducingCO2andBlackCarbonEmissionsbyAdaptiveTrafficManagement”.TheoverallgoalistodeveloptoolsforadaptivelyinfluencingtrafficinrealtimetoreduceCO2andblackcarbonemissionscausedbyroadtransportinurbanandinter-urbanareas(28).
TravelInformationSystemsIn2012,theAssessmentMethodologiesforITSinMultimodalTransportfromUserBehaviortoCO2Reduction(AMITRAN)programbeganandranuntil2014.ThisprogramdevelopedaframeworkfortheevaluationoftheeffectsofITSmeasuresintrafficandtransportonenergyefficiencyandCO2emissions(29).TheEcoGemorCooperativeAdvancedDriverAssistanceSystemforGreenCarsprojectwascarriedoutfrom2010to2013andaimedtoprovideefficientconnectedvehiclesolutionstosupportelectricvehicles(EVs).ThegoalwastodesignanddevelopanEV-oriented,highlyinnovativeAdvancedDriverAssistanceSystem(ADAS)equippedwithsuitablemonitoring,learning,reasoningandmanagementcapabilities,thatwouldhelpincreasetheEV’sautonomyandenergyefficiency(30).
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ResearchNeedsEnvironmental-ITSprogramshaveonlyemergedrecently.ResearchprogramsintheUnitedStates,theEuropeanUnion,andotherregionshavemadesignificantprogressindevelopingandtestingthesesystems.However,therearestillmanyresearchgapsthatneedtobeaddressed,someexamplesofwhicharediscussedbelow.
Environment-Mobility-SafetyNexusOvertheyears,wehaveseensomeITSprogramsfocusingonsafetyandmobilityalsohavingsignificantenvironmentalco-benefits.Thesebenefitsrangewidelyduetoanumberofvariablessuchastypeofapplication,technologyused,andpre-existingconditionbeforedeployment.Recently,anumberofITSprogramshaveemergedthatarespecificallydesignedtominimizetheenvironmentalimpactsoftransportation,someofwhicharebrieflydescribedearlierinthiswhitepaper.Themobilityandsafetyimpacts,bothattheindividualvehiclelevelandatthetrafficnetworklevel,oftheseenvironmental-ITSprogramsarenotwellunderstood.Whiletherehasbeensomeresearchonthistopic(e.g.,(31)),moreisneededtoimprovetheunderstandingoftheconnectionbetweenenvironment,mobility,andsafetyperformanceofanyITSprograms.
InducedTravelDemandOneconcernthathasemergedwithanytypeofITSimplementationisthepotentialforinducedtraveldemand.JustasithasbeenshownthatincreasedroadwaycapacitytypicallyleadstoincreasedVMT(e.g.,see(32)),somehypothesizethatifoverallmobilityimprovesduetoITS,thenpotentiallyVMTwillincrease.Todate,nodefinitivestudieshaveshownthiseffect.However,currentresearchisexamininghowautomatedvehiclesmayaffecttraveldemand(seee.g.,(33)).Preliminaryresultsshowthatwithamodestintroductionofautomatedvehicles,5%increaseinVMTmayoccur.Nevertheless,thegeneraleffectsofITSontraveldemandneedstobestudiedingreaterdetail.
ConclusionsInthiswhitepaper,state-of-the-practiceITSprogramsthatareenvironmentallybeneficialarehighlighted,spanningthethreemainareasofITS,includingVehicleSystems,TrafficManagementSystems,andTravelerInformationSystems.Forthelastseveraldecades,manyoftheseITSprogramshavebeentargetedatimprovingsafetyandreducingcongestion,withthesecondarygoalsofreducingfuelconsumptionandloweringcriteriapollutantandGHGemissions.ItisclearthatspecificenvironmentalbenefitscanbemaximizedwhenthesedifferentITSapplicationsare“tuned”sothatemissionsandfuelconsumptionarereduced.Furthermore,itisimportanttopointoutthatthereisnotasingleITStechnologysolutionthathasdemonstratedasignificantreductioninGHGemissions.Eachoftheenvironmental-ITSapplicationsdescribedinthiswhitepapertypicallycanreduceGHGemissionsintherangeof
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5%to15%.However,mostoftheseapplicationsareadditive,thereforegreaterbenefitsmaybeachievedwhenacombinationofenvironmentallyfriendlyITSprogramsareputintoplace.Also,themobilityandsafetyimpactsofenvironmental-ITSprogramsarenotcurrentlywellunderstood.ItisclearthatasmoreoftheseITSprogramsaredeployed,comprehensiveimpactassessmentsoftheirenvironmental,mobility,andsafetyperformanceareneeded.EvenwiththeseITSoperationalimprovementsthatresultinreducedemissions,wemustalsobeconcernedaboutanypotentialinduceddemandeffects.Again,thispotentialneedstobemodeledandmeasuredasnewITSapplicationsaredeployed.Tocounteracttheseeffects,theITSprogramsmayhavetobecoupledwithsomespecifictraveldemandmanagementmeasures,suchaspricing.
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