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Streaming Video Content Over Streaming Video Content Over WiMAX Broadband Access WiMAX Broadband Access Will Hrudey Will Hrudey www.sfu.ca/~whrudey www.sfu.ca/~whrudey ([email protected]) ([email protected]) ENSC ENSC - - 835 Communication Networks 835 Communication Networks Spring 2008 Spring 2008 Motorola WAP400 Motorola WAP400 Bell RSU Bell RSU - - 2510 2510
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Streaming Video Content Over Streaming Video Content Over WiMAX Broadband AccessWiMAX Broadband Access

Will Hrudey Will Hrudey www.sfu.ca/~whrudeywww.sfu.ca/~whrudey

([email protected])([email protected])

ENSCENSC--835 Communication Networks835 Communication Networks

Spring 2008Spring 2008

Motorola WAP400Motorola WAP400

Bell RSUBell RSU--25102510

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RoadmapRoadmap

IntroductionIntroductionDesign Design ValidationValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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IntroductionIntroductionFocus of this study:Focus of this study:Can WiMAX deliver comparable network performance to ADSL Can WiMAX deliver comparable network performance to ADSL broadband access for streaming video applications?broadband access for streaming video applications?

Simulation will stream an MPEG-4 2-hour movie to 4 video clients

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IntroductionIntroductionWhat is WiMAX Broadband Access?What is WiMAX Broadband Access?

–– WWorldwide orldwide IInteroperability for nteroperability for MMicrowave icrowave AAccess ccess IEEE 802.16IEEE 802.16--2004 [12]2004 [12]IEEE 802.16eIEEE 802.16e--20052005

–– All IP network architectureAll IP network architecture–– PointPoint--toto--multipoint (PMP) modemultipoint (PMP) mode–– Connection oriented Connection oriented –– bandwidth request / grant schemebandwidth request / grant scheme–– Flexible QoS supports voice & videoFlexible QoS supports voice & video–– Optimum spectral efficiencyOptimum spectral efficiency–– Channel bandwidths from 1.25 Channel bandwidths from 1.25 –– 20 MHz20 MHz–– Typical cell size of 7 Typical cell size of 7 -- 10 km10 km–– Optimized for outdoors Optimized for outdoors –– Scalable to 1000Scalable to 1000’’s of userss of users–– Provides fixed, nomadic and mobile usageProvides fixed, nomadic and mobile usage

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IntroductionIntroductionWhy WiMAX?Why WiMAX?

[10] Margaret LaBrecque, [10] Margaret LaBrecque, ““WiMAX IntroductionWiMAX Introduction””, WiMAX Forum 2003, WiMAX Forum 2003

WiMAX Forum March Press Release : 133 million users by 2012WiMAX Forum March Press Release : 133 million users by 2012

OPNETWORK 2007 Conference cited > 100 planned carrier trialsOPNETWORK 2007 Conference cited > 100 planned carrier trials

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IntroductionIntroduction

What is WiMAX Broadband Access?What is WiMAX Broadband Access?

[11] Intel, [11] Intel, ““Understanding WiUnderstanding Wi--Fi and WiMAX as MetroFi and WiMAX as Metro--Access SolutionsAccess Solutions””, 2007, 2007

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IntroductionIntroduction

What Is WiMAX Broadband Access?What Is WiMAX Broadband Access?

[11] Intel, [11] Intel, ““Understanding WiUnderstanding Wi--Fi and WiMAX as MetroFi and WiMAX as Metro--Access SolutionsAccess Solutions””, 2007, 2007

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IntroductionIntroductionWhat Is Video Streaming?What Is Video Streaming?

–– Digital video source delivered to video clients over an Digital video source delivered to video clients over an IP network infrastructureIP network infrastructure

Digital video information is organized as framesDigital video information is organized as framesFrames are compressed using a video codecFrames are compressed using a video codecCompressed frames are encapsulated in protocol headersCompressed frames are encapsulated in protocol headersVideo frame packets are transmitted at a constant rateVideo frame packets are transmitted at a constant rate

–– Video packets may be IP multicast or IP unicastVideo packets may be IP multicast or IP unicast

–– Managed services Unmanaged servicesManaged services Unmanaged servicesIPTV (Live & VoD)IPTV (Live & VoD)Video conferencingVideo conferencing

IPTV (Live & VoD)IPTV (Live & VoD)YouTube, Google VideoYouTube, Google Video

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IntroductionIntroduction

What Is Video Streaming?What Is Video Streaming?

Internet Access Network `

Video ClientVideo Head End

TV Stations

Stored Video

Video ContentCompression

RTPUDP (or TCP)

IPMACPHY

IPMACPHY

IPMACPHY

Video ContentCompression

RTPUDP (or TCP)

IPMACPHY

[7] [7] ““Framework for Delivering IPTV Services Over WiMAX Wireless ServiFramework for Delivering IPTV Services Over WiMAX Wireless Servicesces””, IEEE EIT 2007, IEEE EIT 2007

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IntroductionIntroduction

Video Coding SchemesVideo Coding Schemes

–– Exploit temporal and spatial characteristicsExploit temporal and spatial characteristics–– Various standards and codecs Various standards and codecs

ITU (H.26x) & ISO (MPEGITU (H.26x) & ISO (MPEG--x)x)

Codec Raw Data Rate Compressed RateCodec Raw Data Rate Compressed RateMPEGMPEG--1 30 Mbps 1.5 Mbps1 30 Mbps 1.5 MbpsMPEGMPEG--2 128 Mbps 3 2 128 Mbps 3 –– 10 Mbps10 MbpsMPEGMPEG--4 < 1.024 Mbps4 < 1.024 MbpsBased on QCIF and/or CIF video formatsBased on QCIF and/or CIF video formats

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IntroductionIntroduction

Imaging/Voice/Video For EImaging/Voice/Video For E--Health Applications over WiMAX [2]Health Applications over WiMAX [2]–– Simulation performed in MatlabSimulation performed in Matlab

IPTV over WiMAX Considerations and Transceiver Design [4]IPTV over WiMAX Considerations and Transceiver Design [4]–– No simulationsNo simulations

Evaluation of WiMAX With Various Generic TCP and UDP loads [5]Evaluation of WiMAX With Various Generic TCP and UDP loads [5]–– Utilized testbed instead of simulationsUtilized testbed instead of simulations

IPTV over WiMAX Proposed Framework and Challenges [7]IPTV over WiMAX Proposed Framework and Challenges [7]–– No simulationsNo simulations

Related WorkRelated Work

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RoadmapRoadmap

IntroductionIntroductionDesignDesignValidationValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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DesignDesignLoss – Number of Packets Dropped

1 - (# of received packets) / (# of expected packets)Avg: < 10-3 Ideal: < 10-5

Delay – Average Time of TransitProcessing delay + propagation delay + queuing delayAvg: < 300 ms Ideal: < 10 ms [9]

Jitter – Variation in Packet Arrival TimeActual reception time – expected reception timeAvg: < 60 ms Ideal: < 20 ms

Throughput – Minimum End-to-End Transmission RateMeasured in bytes / sec (or bps)10kbps – 5Mbps [14]

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DesignDesign

Development Platform

– Toshiba Tecra S2 laptop Intel Pentium M Processor / 1GB RAMWindows XP Service Pack 2

– OPNET 12.0.A PL3 + WiMAX Module [13,17]Integrated WiMAX and ADSL nodesGeneric Video Conferencing Application

– Visual Studio .NET 2003 Dev. EnvironmentRequired to compile models

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DesignDesign

Video services subnet located in TorontoVideo clients subnet located in Vancouver ( 3342 km away )

Overall Network Topology

Client WAN link 1547 km 6.1ms dprop

Server WAN link 1795 km7.2ms dprop

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DesignDesignVideo Clients Subnet Topology

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DesignDesignNetwork Parameters

– Adopted latitude / longitude coordinate system to model pathloss & propagation delay– WiMAX deployment parameters (not disclosed without NDA)

Scheduling algorithm: best effortMin sustainable data rate (DL): 3.0 MbpsMin sustainable data rate (UL): 0.640 Mbps Frequency band / channel bandwidth: 2.5 GHz / 5 MHz

– Derived 5 MHz channel definitionPHY layer access scheme: OFDM 512Transmit Power levels (BS / SS): 5W / 2W

– Reviewed Motorola datasheets for current generation WiMAX hardwareWiMAX clients are located 2 / 4 / 6 km from base station

– Manually configured robust burst profiles as a function of distancePathloss model : suburban with mostly flat terrain with light tree densities

– ADSL ConfigurationDownlink: 3.0 MbpsUplink: 0.640 MbpsSubscriber to Central Office is 5km delay based link

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DesignDesignNetwork Parameters– Modulation / coding and required SNR [2]

– OFDM 512 subcarriers

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DesignDesign

Server provides Video on Demand (VoD) servicesLocal client used only for initial troubleshooting and validation

Video Services Subnet Topology

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DesignDesignVideo traffic is loss tolerant but delay sensitiveSimulation model is trace drivenConfigured 2 video streams

MPEG-2 1280x720 @ 30 fps [15,16]MPEG-4 352x288 @ 25 fps [15,16]

Video trace pre-processingSorted into codec sequence (versus display sequence)Converted frame sizes to bytesImported into OPNET as a distribution

Configured Application and Profiles NodesPromoted necessary statistics

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DesignDesignVideo Traffic Profiles

MPEG-2 stream resulted in poor performance so used MPEG-4 stream

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DesignDesign

WAN links– 10-20% background traffic

LAN links– 10-20% background traffic

Internet– Packet Discard Ratio: 0.001% – Packet Latency: 0.001s

Background Traffic Growth: 10% every 30 min

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DesignDesign

Video Traffic Details

[15,16] [15,16]

Observe peak and mean rates for MPEG-2 and MPEG-4 traffic

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DesignDesign

Model LimitationsModel Limitations

– Video traffic only [15,16]

– No RTP encapsulation

– WiMAX AMC not available [13]

– WiMAX power management not available [13]

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RoadmapRoadmap

IntroductionIntroductionDesign Design ValidationValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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ValidationValidationCBR Video Traffic Using 1 fps (17280 bytes/sec)

DES LogObserve WAN and LAN background traffic

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RoadmapRoadmap

IntroductionIntroductionDesign Design ValidationValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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AnalysisAnalysis

Loss Measurement ( instantaneous )Loss Measurement ( instantaneous )

BS buffer: 128 KBBS buffer: 128 KB

–– Loss is depicted as deviation from the blue line representing 25Loss is depicted as deviation from the blue line representing 25 pkts/secpkts/sec–– 1024 KB is large enough to prevent dropped downlink packets at B1024 KB is large enough to prevent dropped downlink packets at BSS–– 6km WiMAX station loss still significant because SNR is below mi6km WiMAX station loss still significant because SNR is below minimum nimum

level modulation/coding [2]level modulation/coding [2]

BS buffer: 1024 KBBS buffer: 1024 KB

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AnalysisAnalysisDelay MeasurementDelay Measurement

–– Curves are averaged across the 2Curves are averaged across the 2--hour movie durationhour movie duration–– Metric Avg: < 300 ms Ideal: < 10 ms [9] Metric Avg: < 300 ms Ideal: < 10 ms [9]

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AnalysisAnalysisJitter MeasurementJitter Measurement

–– Curves are averaged across the 2Curves are averaged across the 2--hour movie durationhour movie duration–– Metric Avg: < 60 ms Ideal: < 20 ms Metric Avg: < 60 ms Ideal: < 20 ms

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AnalysisAnalysisThroughputThroughput

–– Curves are averaged across the 2Curves are averaged across the 2--hour movie durationhour movie duration–– Metric 10kbps Metric 10kbps –– 5Mbps [14] 5Mbps [14]

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RoadmapRoadmap

IntroductionIntroductionDesign Design Model ValidationModel ValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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ConclusionsConclusionsSimulation Time: 2.0 hrs Actual time: > 8 hours primary sceSimulation Time: 2.0 hrs Actual time: > 8 hours primary scenarionario

WiMAX satisfied the video performance metricsWiMAX satisfied the video performance metrics–– WiMAX packet loss significantly reduced by increasing BS bufferiWiMAX packet loss significantly reduced by increasing BS bufferingng–– Results are understated since the model used worst case BE schedResults are understated since the model used worst case BE scheduleruler

Overall results in comparison to ADSL are promisingOverall results in comparison to ADSL are promising–– Dependant on specific carrier deployment parameters Dependant on specific carrier deployment parameters

WiMAX has capacity to deliver higher throughput rates & QoS thanWiMAX has capacity to deliver higher throughput rates & QoS than ADSLADSL

–– While further refinement is required, WiMAX can provide comparabWhile further refinement is required, WiMAX can provide comparable le network performance to ADSL for video streaming servicesnetwork performance to ADSL for video streaming services

Model stability may improve with OPNET 14Model stability may improve with OPNET 14–– WiMAX model results were unreasonable at timesWiMAX model results were unreasonable at times

Simulations do not guarantee real world equivalenceSimulations do not guarantee real world equivalence–– Must be considered when interpreting resultsMust be considered when interpreting results

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RoadmapRoadmap

IntroductionIntroductionDesign Design Model ValidationModel ValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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Project ChallengesProject ChallengesEnvironment (licensing, access, VS integration)Environment (licensing, access, VS integration)

No OPNET newsgroups, gurus, or userNo OPNET newsgroups, gurus, or user--uploaded modelsuploaded models

Steep learning curve for OPNET configurations and videoSteep learning curve for OPNET configurations and video–– Insufficient documentation Insufficient documentation –– Importing video traces, detailed profile configuration, routing Importing video traces, detailed profile configuration, routing –– WiMAX implementationWiMAX implementation–– Extended troubleshooting (confirmed bugs: Extended troubleshooting (confirmed bugs: SPRSPR--113276 / SPR113276 / SPR--8242982429))–– Learning video traffic details (formats, codecs, GOP details)Learning video traffic details (formats, codecs, GOP details)

WiMAX rtPS scheduling difficult to configureWiMAX rtPS scheduling difficult to configure–– Could not achieve working configurationCould not achieve working configuration

Learning WiMAX fundamentals within project durationLearning WiMAX fundamentals within project duration

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RoadmapRoadmap

IntroductionIntroductionDesign Design Model ValidationModel ValidationAnalysisAnalysisConclusionsConclusionsChallengesChallengesFuture WorkFuture WorkReferencesReferences

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Future WorkFuture WorkDevelop more comprehensive simulations Develop more comprehensive simulations –– Experimentally characterize specific WiMAX parametersExperimentally characterize specific WiMAX parameters

scheduling, transmit power, antenna gain, channel bandwidthsscheduling, transmit power, antenna gain, channel bandwidths

Conduct comprehensive analysis on dataConduct comprehensive analysis on data

Research and refine video performance metricsResearch and refine video performance metrics

Encapsulate video traffic in RTPEncapsulate video traffic in RTP

Incorporate audio streamsIncorporate audio streams

WiMAX mobility and shadowingWiMAX mobility and shadowing

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ReferencesReferences[1] M. [1] M. ChatterjeeChatterjee, S. , S. SenguptaSengupta, and S. , and S. GangulyGanguly, "Feedback, "Feedback--Based realBased real--time time streaming over streaming over WiMaxWiMax," ," IEEE Wireless Communications MagazineIEEE Wireless Communications Magazine, vol. 14, no. 1, pp. , vol. 14, no. 1, pp. 6464--71, Feb. 2007.71, Feb. 2007.

[2] D. [2] D. NiyatoNiyato, E. , E. HossainHossain, and J. Diamond, "IEEE802.16/WiMAX, and J. Diamond, "IEEE802.16/WiMAX--Based broadband Based broadband wireless access and its application for telemedicine / ewireless access and its application for telemedicine / e--health services," health services," IEEE IEEE Wireless Communications MagazineWireless Communications Magazine, vol. 14, no.1, pp. 72, vol. 14, no.1, pp. 72--83, Feb. 2007.83, Feb. 2007.

[3] [3] KuoKuo--HuiHui Li, Intel WiMAX Solutions Division [Online]. Available: Li, Intel WiMAX Solutions Division [Online]. Available: http://santos.ee.ntu.edu.tw/mobile/Speech/WiMAX%20Network%20Archhttp://santos.ee.ntu.edu.tw/mobile/Speech/WiMAX%20Network%20Architecture.pdf itecture.pdf (January 2008).(January 2008).

[4] F. [4] F. RetnasothieRetnasothie, M. , M. OzdemirOzdemir, T. , T. YucekYucek, H. , H. CelebiCelebi, J. Zhang, and R. , J. Zhang, and R. MuththaiahMuththaiah, , "Wireless IPTV over WiMAX: challenges and applications," "Wireless IPTV over WiMAX: challenges and applications," Proc. IEEE WAMICON Proc. IEEE WAMICON 20062006, Clearwater, FL, Dec. 2006, pp. 1, Clearwater, FL, Dec. 2006, pp. 1--5.5.

[5] F. [5] F. YousafYousaf, K. Daniel, and C. , K. Daniel, and C. WietfeldWietfeld, "Performance evaluation of IEEE 802.16 , "Performance evaluation of IEEE 802.16 WiMAX link with respect to higher layer protocols," WiMAX link with respect to higher layer protocols," Proc. IEEE ISWCS 2007Proc. IEEE ISWCS 2007, , TrondheimTrondheim, Norway, Oct. 2007, pp. 180, Norway, Oct. 2007, pp. 180--184.184.

[6] H. Juan, H. Huang, C. Huang, and T. Chiang, "Scalable video [6] H. Juan, H. Huang, C. Huang, and T. Chiang, "Scalable video streaming over streaming over mobile WiMAX," mobile WiMAX," Proc. ISCAS 2007Proc. ISCAS 2007, New Orleans, Louisiana, May 2007, pp. 3463, New Orleans, Louisiana, May 2007, pp. 3463--3466.3466.

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ReferencesReferences[7] I. [7] I. UilecanUilecan, C. Zhou, and G. , C. Zhou, and G. AtkinAtkin, , ““Framework for delivering IPTV services over Framework for delivering IPTV services over WiMAX wireless networks,WiMAX wireless networks,”” Proc IEEE EIT 2007Proc IEEE EIT 2007, Chicago, IL, May 2007, pp. 470, Chicago, IL, May 2007, pp. 470--475. 475.

[8] J. She, F. [8] J. She, F. HouHou, P. Ho, and L. , P. Ho, and L. XieXie, , ““IPTV over WiMAX key success factors, IPTV over WiMAX key success factors, challenges, and solutions,challenges, and solutions,”” IEEE Communications MagazineIEEE Communications Magazine, vol. 45, no. 8, pp. 87, vol. 45, no. 8, pp. 87--93, Aug 2007.93, Aug 2007.

[9] V. [9] V. MarkovskiMarkovski, F. , F. XueXue, and , and LjLj. . TrajkovicTrajkovic, ``Simulation and analysis of packet loss in , ``Simulation and analysis of packet loss in video transfers using User Datagram Protocol,'' video transfers using User Datagram Protocol,'' The Journal of SupercomputingThe Journal of Supercomputing, vol. , vol. 20, no. 2, pp. 17520, no. 2, pp. 175--196, Sep. 2001.196, Sep. 2001.

[10] M. [10] M. LaBrecqueLaBrecque, WiMAX introduction [Online]. Available: , WiMAX introduction [Online]. Available: http://http://www.wimaxforum.orgwww.wimaxforum.org/technology/downloads (February 2008)./technology/downloads (February 2008).

[11] Intel, Understanding Wi[11] Intel, Understanding Wi--Fi and WiMAX as metroFi and WiMAX as metro--access solutions [Online]. access solutions [Online]. Available: http://Available: http://www.rclient.com/PDFs/IntelPaper.pdfwww.rclient.com/PDFs/IntelPaper.pdf (February 2008).(February 2008).

[12] IEEE Std. 802.16[12] IEEE Std. 802.16--2004: Part 16: Air interface for fixed broadband wireless 2004: Part 16: Air interface for fixed broadband wireless access systems [Online]. Available: http://standards.ieee.org/geaccess systems [Online]. Available: http://standards.ieee.org/getieee802/802.16.html tieee802/802.16.html (February 2008).(February 2008).

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ReferencesReferences[13] OPNET WiMAX (802.16e) model user guide [Online]. Available [13] OPNET WiMAX (802.16e) model user guide [Online]. Available via OPNET via OPNET WiMAX registration.WiMAX registration.

[14] J. Kurose and K. Ross, [14] J. Kurose and K. Ross, Computer Networking: A TopComputer Networking: A Top--Down ApproachDown Approach, 4/e. , 4/e. Boston, MA: Pearson/AddisonBoston, MA: Pearson/Addison--Wesley, 2008.Wesley, 2008.

[15] G. [15] G. AuweraAuwera, P. David, and M. , P. David, and M. ReissleinReisslein, , ""Traffic characteristics of H.264/AVC Traffic characteristics of H.264/AVC variable bit rate video," [Online]. Available: http://trace.eavariable bit rate video," [Online]. Available: http://trace.eas.asu.edu/h264/index.html s.asu.edu/h264/index.html (March 2008).(March 2008).

[16] G. [16] G. AuweraAuwera, P. David, and M. , P. David, and M. ReissleinReisslein, "Traffic and quality characterization of , "Traffic and quality characterization of singlesingle--layer video streams encoded with the H.264/MPEGlayer video streams encoded with the H.264/MPEG--4 advanced video coding 4 advanced video coding standard and scalable video coding extension" [Online]. Availablstandard and scalable video coding extension" [Online]. Available: e: http://trace.eas.asu.edu/h264/index.html (March 2008).http://trace.eas.asu.edu/h264/index.html (March 2008).

[17] OPNET modeler software [Online]. Available: [17] OPNET modeler software [Online]. Available: http://http://www.opnet.com/products/modeler/home.htmlwww.opnet.com/products/modeler/home.html..

[18] WiMAX forum [Online]. Available: [18] WiMAX forum [Online]. Available: http://http://www.wimaxforum.org/news/pr/view?item_keywww.wimaxforum.org/news/pr/view?item_key=9212a980801358eef27c4dec8bb=9212a980801358eef27c4dec8bbab579bfc6529a (April 2008).ab579bfc6529a (April 2008).


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