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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 1 Error Recovery
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 2 Problems with Internet Limited Bandwidth Varying Conditions Delay Jitter Packet Loss Delay Heterogeneity :
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 3 Network Encoder Sender Middlebox Receiver Decoder You Are Here
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 4 Overview Characteristics of the Internet General techniques Error recovery for audio Effect of loss on MPEG Error recovery for MPEG
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 5 Loss Characteristics of The Internet
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 6 Characteristics of Internet 60-70% of paths do not show any loss Those with loss have an average of 4.5 – 6% packet loss [Paxson97] End-to-end Internet packet dynamics
![NUS.SOC.CS Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 6 Characteristics of Internet 60-70% of paths do not show any loss Those with loss have an average of 4.5 – 6% packet loss [Paxson97] End-to-end Internet packet dynamics](http://images.slideplayer.com/26/8304848/slides/slide_6.jpg "NUS.SOC.CS Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 6 Characteristics of Internet 60-70% of paths do not show any loss Those with loss have an average of 4.5 – 6% packet loss [Paxson97] End-to-end Internet packet dynamics")
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 7 Packet Loss Pattern 1000 30 Number of Occurrences Burst Length
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 8 Characteristics of Internet Bursts of loss are typically short (2-3 consecutively loss packets) Long burst do occur Burst may occur periodically
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 9 Wireless Link Loss rate measured in my office 10 ~ 20% Up to 50% reported!
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 10 Gilbert Model GOODBAD
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 11 A Survey of Packet-Loss Recovery Techniques for Streaming Audio Perkins, Hodson and Hardman IEEE Network Magazine 1998
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 12 Retransmission 1234 124 3 3 X
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 13 Redundant Data 1234 124 2 23 345 53
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 14 24 Error Concealment 1234 1
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 15 Retransmission for audio
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 16 Pros/Cons of Retransmissions
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 17 Scalable Retransmission On packet loss T = random(0, RTT) wait for T multicast NACK On receiving NACK from others suppress own NACK
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 18 Retransmit when Group size is small Loss rate is low Large latency acceptable
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 19 Selective Retransmission Retransmission based on priority of packets Important/urgent packets are retransmitted first Packets are only retransmitted when there is enough time [Papadopoulos and Parulkar, NOSSDAV 1996]
![NUS.SOC.CS Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 19 Selective Retransmission Retransmission based on priority of packets Important/urgent packets are retransmitted first Packets are only retransmitted when there is enough time [Papadopoulos and Parulkar, NOSSDAV 1996]](http://images.slideplayer.com/26/8304848/slides/slide_19.jpg "NUS.SOC.CS Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 19 Selective Retransmission Retransmission based on priority of packets Important/urgent packets are retransmitted first Packets are only retransmitted when there is enough time [Papadopoulos and Parulkar, NOSSDAV 1996]")
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 20 Redundant Data for audio
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 21 Parity Forward Error Correction 1011001 1000010 0001001 XOR 0010010
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 22 Parity Forward Error Correction 1011001 1000010 0001001 0010010
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 23 Parity FEC Ordering
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 24 Parity FEC Ordering
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 25 Parity FEC Ordering
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 26 Parity FEC Ordering
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 27 Parity FEC Ordering
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 28 Reed-Solomon Code RS(n,k) RS n k (popular: n = 223) (popular: k = 32) Parity symbols Data symbols
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 29 Reed-Solomon Code Data block (length n+k, e.g., 255) Can correct up to 16 corrupted symbols per block (32/2)
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 30 Media Specific FEC 1234 124 2 23 345 53
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 31 Pros/Cons of Redundant Data
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 32 Interleaving
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 33 Pros/Cons of Interleaving
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 34 Error Concealment
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Recreate Lost Information NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 35
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 36 Effect of Loss on Audio Speech Human ears can interpolate Loss up to length of phoneme can still be tolerable
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 37 Insertion-based Repair Splice Silence Substitution Noise Substitution Repetition
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 38 Other Repair Methods Interpolation Regeneration
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 39 Error Concealment More complex error concealment algorithms provide better performance (i.e., playback quality)
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 40 Colin’s Recommendations
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 41 Non-Interactive Apps Interleaving FEC Retransmission for unicast only
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 42 Interactive Applications Media Specific FEC
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 43 Error Concealment Repeat
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 44 Packet Loss Effects on MPEG Video Sent over the Public Internet Jill Boyce and Robert Gaglianello ACM Multimedia 1998
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 45 Measurement-based Study Need to understand the problem before proposing solution
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 46 Data Gathering Method From: NYC 13, Austin 21, London 18 To: Holmdel, NJ
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 47 Data Gathering Method Video: Two 5-mins MPEG 30 fps 384 kbps and 1 Mbps GOP: IBBPBBPBBPBBPBB QSIF 176x112 and SIF 352x240 One row per slice
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 48 Average Packet Loss
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 49 Frames Affected by Errors % Frames in Error Packet Loss Rate
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 50 Overview of Error Recovery for Video
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 51 Methods Retransmission Interleaving Error Concealment FEC Limiting Error Propagation Reference Frame Selection
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 52 Reference Frame Selection I P B B P X I
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 53 Methods Retransmission Interleaving Error Concealment FEC Limiting Error Propagation Reference Frame Selection Changing Temporal Pattern
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 54 Case Study: HD video conferencing Korean Air, Inha University (Seoul), University of Southern California, Pratt & Whitney
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© PWICE, 2006 55 USC-Inha Two-way Experiments USC (Powell Hall of Engineering) July 2005
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© PWICE, 2006 56 USC-Inha Two-way Experiments Inha University (Memorial Library) July 2005
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© PWICE, 2006 57 KAL Network Infrastructure Korean Air network infrastructure between Incheon, Kimpo, and Pusan KAL network & external ISP (KT) 1 Gbps: ICN-GMP 50 Mbps: GMP-PUS December 2005
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© PWICE, 2006 58 Network Measurements End-to-end packet loss rates of the network path between Kimpo (GMP) and Incheon (ICN) observed during November 15-16, 2005 Network is shared with other business traffic Loss rates are quite low November 2005
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© PWICE, 2006 59 Hardware Preparation 3 computers purchased in Korea Computers sent to USC with KAL Software setup in the IMSC laboratories Linux installation RCS software installation Retransmission configuration End-to-end equipment test with local JVC cameras and displays Computers sent back to KAL HQ December 2005
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© PWICE, 2006 60 Hardware Test at KAL Re-configuration for Sony HDR-HC1 cameras December 2005 Local area network tests
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© PWICE, 2006 61 Experiments: ICN ◄▬► GMP Asymmetric environment: 88 Mb/s & 50 Mb/s Conclusion: ICN - GMP: sufficient BW for HD video Sufficient headroom for data applications December 2005 Bandwidth measurements Visual quality Required by RCS
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© PWICE, 2006 62 Experiments: ICN ◄▬► PUS Asymmetric environment: 6 Mb/s & 1 Mb/s GMP - PUS: initially insufficient BW for HD video Investigated network routers with KAL IT help Conclusion: replaced router to improve throughput; to be re-tested December 2005 Bandwidth measurements Visual quality
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© PWICE, 2006 63 Measurements: Packet Loss Rate Path: ICN - PUS Two packet sizes: 564 bytes and 940 bytes Conclusion: GMP - PUS loss rate very high December 2005 One-way packet loss rate Two-way packet loss rate
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© PWICE, 2006 64 Packet Loss Error Recovery Selective retransmission protocol is used to recover from lost data Effectiveness of protocol is tested in lab environment Gilbert Model is used to induce losses into transmission Transmission delay is chosen to be 10 ms (expected latency in Korea)
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© PWICE, 2006 65 Packet Loss Error Recovery Selective retransmission protocol 10% Loss Rate 5% Loss Rate 1% Loss Rate With Retransmissions Sept. - Dec. 2005 (ICN-GMP Link)
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Current Hardware Codecs NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 66 Hauppauge HD-PVR Cavium PureVu™ CNW31XX
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HD-PVR H.264 Encoder NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 67
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 68
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 69 Error Control Techniques for Interactive Low Bitrate Video Transmission over The Internet Injong Rhee SIGCOMM ‘98
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 70 Basic Idea “Better Late Than Never!”, or Late packet is still useful
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 71 MPEG Frame Pattern IBBPBBP IPBBPBB
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 72 H.261 Error Propagation IPPPPPP XXXXXX IPPPPPP XXXX retransmission loss
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 73 H.261 Frame Pattern IPPPPPP X loss
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 74 IPPPPPP H.261 Frame Pattern X loss X X retransmission
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 75 PTDD Periodic Temporal Dependency Distance Large PTDD Higher Chance of Repair Longer Error Propagations Less Temporal Redundancy
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 76 QAL IPPP IPPP Base Layer Enhancement Layer
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 77 QAL IPPP IPPP Base Layer + FEC Enhancement Layer X
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 78 QAL + PTDD IPPP IPPP Base Layer Enhancement Layer
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 79 Error Propagation
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 80 Recovery from Error Propagation
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 81 Frame “quality” PSNR =
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 82 PSNR vs. Loss Rate Packet Loss Rate PSNR
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 83 Today’s Summary
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 84 How to recover packet loss Retransmission FEC Error Concealment
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NUS.SOC.CS5248-2010 Roger Zimmermann (based in part on slides by Ooi Wei Tsang) 85 Limit the damage of error Interleaving Key frame selection Change reference frame
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