SPRINGER BRIEFS IN ELECTRICAL AND COMPUTER ENGINEERING Yi Song Jiang Xie Broadcast Design in Cognitive Radio Ad Hoc Networks 123 SpringerBriefs in Electrical and Computer Engineering Moreinformationaboutthisseriesathttp://www.springer.com/series/10059 Yi Song • Jiang Xie Broadcast Design in Cognitive Radio Ad Hoc Networks 2123 YiSong JiangXie WichitaStateUniversity TheUniversityofNorthCarolinaatCharlotte Wichita,Kansas Charlotte,NorthCarolina USA USA ISSN2191-8112 ISSN2191-8120(electronic) SpringerBriefsinElectricalandComputerEngineering ISBN978-3-319-12621-0 ISBN978-3-319-12622-7(eBook) DOI10.1007/978-3-319-12622-7 LibraryofCongressControlNumber:2014948601 SpringerChamHeidelbergNewYorkDordrechtLondon © TheAuthor(s)2014 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpartofthe materialisconcerned,specificallytherightsoftranslation,reprinting,reuseofillustrations,recitation, broadcasting,reproductiononmicrofilmsorinanyotherphysicalway,andtransmissionorinformation storageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilarmethodology nowknownorhereafterdeveloped. Theuseofgeneraldescriptivenames,registerednames,trademarks,servicemarks,etc.inthispublication doesnotimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexemptfromtherelevant protectivelawsandregulationsandthereforefreeforgeneraluse. Thepublisher,theauthorsandtheeditorsaresafetoassumethattheadviceandinformationinthisbook arebelievedtobetrueandaccurateatthedateofpublication.Neitherthepublishernortheauthorsorthe editorsgiveawarranty,expressorimplied,withrespecttothematerialcontainedhereinorforanyerrors oromissionsthatmayhavebeenmade. Printedonacid-freepaper SpringerispartofSpringerScience+BusinessMedia(www.springer.com) Preface Broadcastisanimportantoperationinwirelessnetworkswherecontrolinformation isusuallypropagatedasbroadcastsfortherealizationofmostnetworkingprotocols. Intraditionaladhocnetworks,sincethespectrumavailabilityisuniform,broadcasts aredeliveredviaacommonchannelwhichcanbeheardbyallusersinanetwork. However, in cognitive radio (CR) ad hoc networks, unlicensed users may observe heterogeneous spectrum availability, which is unknown to other unlicensed users beforethecontrolinformationwasbroadcast.Thisnon-uniformspectrumavailability imposesspecialdesignchallengesforbroadcastinCRadhocnetworks.Inthisbook, thespecialchallengesofbroadcastdesigninCRadhocnetworksarediscussed.Two broadcastprotocolsinCRadhocnetworksareintroduced:(1)aquality-of-service (QoS)-basedbroadcastprotocolunderblindinformationand(2)afully-distributed broadcastprotocolwithcollisionavoidance. Inaddition, anovelunifiedanalytical modelisalsointroducedtoanalyzetheperformanceofbroadcastprotocolsinCRad hocnetworks.Thisisthefirstbookthatdiscussestheuniquebroadcastchallengesin CRadhocnetworksandinvestigatestheanalyticalworkontheperformanceanalysis ofbroadcastprotocolsforCRadhocnetworks. v Contents 1 Introduction................................................... 1 1.1 BackgroundonCognitiveRadioNetworks ..................... 1 1.2 BackgroundonBroadcastinComputerNetworks................ 2 1.2.1 Existing Broadcast Protocols in Traditional Wireless Networks .......................................... 2 1.3 BroadcastProtocolsinCognitiveRadioNetworks ............... 3 1.3.1 ResearchStatus...................................... 3 1.3.2 ResearchChallenges.................................. 3 1.4 Analytical Model for Broadcast Protocols in Cognitive Radio Networks ................................................. 5 1.4.1 ResearchStatus...................................... 5 1.4.2 ResearchChallenges.................................. 6 1.5 Contributions .............................................. 8 1.6 Organization............................................... 9 References ..................................................... 9 2 QoS-basedBroadcastProtocolUnderBlindInformationinCognitive RadioAdHocNetworks ........................................ 13 2.1 NetworkModel ............................................ 13 2.2 ExploringBroadcastDesigninCRNs.......................... 14 2.2.1 RandomBroadcastScheme............................ 14 2.2.2 FullBroadcastScheme................................ 16 2.3 TheBasicScheme.......................................... 17 2.3.1 TheSingle-HopScenario.............................. 17 2.3.2 TheMulti-HopScenario .............................. 20 2.4 TheEnhancedScheme ...................................... 21 2.4.1 AnalysisoftheChannelAvailability..................... 21 2.4.2 TheEnhancedQB2ICScheme ......................... 25 2.5 PerformanceEvaluation ..................................... 25 References ..................................................... 36 vii viii Contents 3 DistributedBroadcastProtocolwithCollisionAvoidanceinCognitive RadioAdHocNetworks ........................................ 37 3.1 TheDistributedBroadcastProtocolwithCollisionAvoidance...... 37 3.1.1 ConstructionoftheBroadcastingSequences.............. 37 3.1.2 TheDistributedBroadcastSchedulingScheme............ 41 3.1.3 TheBroadcastCollisionAvoidanceScheme .............. 42 3.2 TheDerivationoftheValueofw .............................. 46 3.2.1 TheNetworkModel .................................. 46 3.2.2 TheDerivationoftheValueofw........................ 47 3.3 DiscussionontheProposedBroadcastProtocol ................. 52 3.3.1 The2-hopLocationInformation........................ 52 3.3.2 TimeSynchronization ................................ 53 3.4 PerformanceEvaluation ..................................... 55 References ..................................................... 64 4 UnifiedAnalyticalModelforBroadcastinCognitiveRadioAdHoc Networks...................................................... 67 4.1 CalculatingtheSuccessfulBroadcastRatio ..................... 67 4.1.1 TheUniqueChallenge ................................ 67 4.1.2 TheProposedAlgorithm .............................. 69 4.1.3 AnIllustrativeExample ............................... 70 4.2 CalculatingtheAverageBroadcastDelay....................... 72 4.2.1 TheUniqueChallenge ................................ 72 4.2.2 TheProposedAlgorithm .............................. 73 4.2.3 AnIllustrativeExample ............................... 76 4.3 BroadcastinginCRAdHocNetworks ......................... 76 4.3.1 RandomBroadcastScheme............................ 76 4.3.2 QoS-basedBroadcastScheme.......................... 78 4.3.3 DistributedBroadcastScheme ......................... 81 4.4 PerformanceEvaluation ..................................... 83 4.4.1 ValidatingAnalysisUsingHardwareImplementation ...... 83 4.4.2 ValidatingAnalysisUsingSimulation ................... 85 4.4.3 SystemParameterDesignUsingtheProposedAnalytical Model ............................................. 90 References ..................................................... 93 5 Conclusion .................................................... 95 Chapter 1 Introduction 1.1 BackgroundonCognitiveRadioNetworks The invention of portable hand-held devices, such as smartphones and tablet per- sonal computers (PCs), has led a dramatic increase in the demand of ubiquitous wirelesscommunicationnetworksandhasrevolutionizedthewaypeoplecommuni- catethesedays.Rangingfromold-fashionedcellularnetworks(e.g.,4Gnetworks) to recent local area networks (e.g., WiFi networks) or body area networks (e.g., Bluetooth),varioustypesofwirelessnetworkservicesareseeinganunprecedented growth.Withsuchrapidgrowthofwirelessdevices,thedemandsfortheradiospec- trum are constantly increasing, resulting in scarce spectrum resources. According totheFederalCommunicationsCommission(FCC),almostalltheradiospectrum for wireless communications has already been allocated. However, recent studies show that up to 85% of the allocated spectrum is underutilized due to the current fixedspectrumaccesspolicy[1]. Toalleviatethespectrumscarcityproblem, FCC hassuggestedanewparadigmfordynamicallyaccessingthevacantportionsofthe allocatedspectrum[2]. Cognitiveradio(CR)hasrecentlyemergedasapromising technologytoovercometheimbalancebetweentheincreaseinspectrumaccessde- mandandtheinefficiencyinspectrumusagebyallowingdynamicspectrumaccess (DSA).A “cognitive radio” is a radio that can change its communication protocol parameters(e.g.,operatingfrequency)basedoninteractionswiththeenvironmentin whichitoperates[2–4]. CRnetworksareregardedasthenext-generationwireless networkstoefficientlyutilizetheradiospectrum.Withthecapabilityofsensingthe frequency bands in a time and location-varying spectrum environment and adjust- ingtheoperatingparametersbasedonthesensingoutcome,CRtechnologyallows anunlicenseduser(or,secondaryuser)toexploitthosefrequencybandsunusedby licensedusers(or, primaryusers)inanopportunisticmanner[5]. Secondaryusers (SUs)canformaCRinfrastructure-basednetworkoraCRadhocnetwork.Recently, CRadhocnetworkshaveattractedplentifulresearchattentionduetotheirvarious applications[6,7]. ©TheAuthor(s)2014 1 Y.Song,J.Xie,BroadcastDesigninCognitiveRadioAdHocNetworks, SpringerBriefsinElectricalandComputerEngineering,DOI10.1007/978-3-319-12622-7_1 2 1 Introduction 1.2 BackgroundonBroadcastinComputerNetworks Broadcastisanimportantoperationincomputernetworks,especiallyindistributed multi-hop multi-channel wireless networks. Control information exchange among nodes,suchaschannelavailabilityandroutinginformation,iscrucialfortherealiza- tionofmostnetworkingprotocolsinanadhocnetwork.Thiscontrolinformationis oftensentoutasnetwork-widebroadcasts,messagesthataresenttoallothernodes in a network. In addition, some exigent data packets such as emergency messages andalarmsignalsarealsodeliveredasnetwork-widebroadcasts[8]. 1.2.1 Existing Broadcast Protocols in Traditional WirelessNetworks Intraditionalmobileadhocnetworks(MANETs), broadcastmessagesareusually conveyed through a common channel which can be heard by all nodes in the net- work [9–12]. Typical broadcast protocols in traditional wireless networks can be categorizedintothreecategories.Thefirstcategoryiscalledsimpleflooding.Thatis, everynodeinthenetworkrebroadcaststhebroadcastmessagewithaprobabilityof onewhenitreceivesthemessage.Thismethodleadstoaveryhighoverhead.More severely,sometimesitleadstoafailedbroadcast.Thatis,ifanodereceivestwoor more broadcast messages simultaneously, none of these messages can be success- fullyreceivedbythenode.Thisiscalledthebroadcastcollisionproblem.Thesecond categoryiscalledtheprobability-basedmethod.Inthismethod,eachnoderebroad- caststhemessagewithaprobabilityofpwhenitreceivesthemessage.Itcanreduce theoveralloverheadandtheprobabilityofbroadcastcollisions.Indensenetworks, multiple nodes share similar transmission coverages. Thus, the probability-based methodcanreservenetworkresourcewithoutharmingdeliveryeffectiveness.How- ever,insparsenetworks,thebroadcastdeliveryeffectivenessmaybeaffected.The thirdcategoryiscalledtheneighborknowledgemethod.Inthismethod,somenet- work topology information is given, such as the locations of 1-hop nodes, 2-hop nodesorsometimesthewholenetworktopology. Basedonthisinformation, some nodescanbeparticularlyselectedastheforwardingnodeswhileothernodesdonot rebroadcast the broadcast message. These forwarding nodes often can lead to full coverageandavoidbroadcastcollisions.Inaddition,itcanalsoleadtotheshortest broadcastdelay.However,a-priorinetworktopologyinformationisrequired. Since broadcast messages often need to be disseminated to all destinations as quicklyaspossible,weaimtoachieveveryhighsuccessfulbroadcastratio(i.e.,the probabilitythatallnodesinanetworksuccessfullyreceiveabroadcastmessage)and very short average broadcast delay (i.e., the average duration from the moment a broadcaststartstothemomentthelastnodereceivesthebroadcastmessage). 1.3 BroadcastProtocolsinCognitiveRadioNetworks 3 1.3 BroadcastProtocolsinCognitiveRadioNetworks 1.3.1 ResearchStatus Currently,researchonbroadcastprotocolsinmulti-hopCRadhocnetworksisstill initsinfantstage.ThereareonlylimitedpapersaddressingthebroadcastissueinCR adhocnetworks[13–16]. However, in[13]and[14], theglobalnetworktopology andtheavailablechannelinformationofallSUsareassumedtobeknown.Addition- ally,in[14],acommonsignalingchannelforthewholenetworkisemployedwhich isalsonotpractical. Thesetwopapersadoptimpracticalassumptionswhichmake theminadequatetobeusedinpracticalscenarios.Otherproposalsaimingtolocally establishacommoncontrolchannelmayalsobeconsideredforbroadcast[17–20]. However, theseproposalsneeda-priorichannelavailabilityinformationofallSUs which is usually obtained via broadcasts. In addition, although some schemes on channel hopping in CR networks can be used for finding a common channel be- tweentwonodes[21–23],theystillsuffervariouslimitationsandcannotbeusedin broadcastscenarios. In[21]and[22], theproposedchannelhoppingschemescan- notguaranteerendezvousundersomespecialcircumstances.Inaddition,oneofthe proposedschemesin[21]onlyworkswhentwoSUshaveexactlythesameavailable channel sets. Furthermore, in [23], a jump-stay based channel hopping algorithm isproposedforguaranteedrendezvous.However,theexpectedrendezvoustimefor the asymmetric model (i.e., different users have different available channels) is of polynomialcomplexitywithrespecttothetotalnumberofchannels.Thus,itisun- suitableforbroadcastscenariosinCRadhocnetworkswherechannelavailability is usually non-uniform and short broadcast delay is often required. Other channel hopping algorithms explained in [24] require tight time synchronization which is alsonotfeasiblebeforeanycontrolinformationisexchanged. 1.3.2 ResearchChallenges InCRadhocnetworks,sincesecondaryuserscanonlyusethechannelswhichare not occupied by primary users (PUs), different SUs may acquire different sets of available channels. Thus, the availability of such a common channel for all nodes maynotexist.Moreimportantly,beforecontrolinformationissent,aSUisunaware oftheavailablechannelsofitsneighboringnodes.Asaresult,eventhoughaglobal or local common channel may exist, SUs are unaware of its existence. Therefore, broadcastingcontrolmessagesonacommonchannelisoftennotfeasibleinCRad hocnetworksunderblindinformation[17,18,25–29]. On the other hand, since each SU is typically equipped with one radio, it can only visit one available channel at a time. A broadcast message can be received by a neighboring node only if the message is transmitted on the same channel on whichthereceivercurrentlystays.Therefore,ifaSUonlybroadcastsamessageonce on one available channel, this message may not be successfully received by all its