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PPR: Partial Packet Recovery for Wireless Networks Kyle Jamieson and Hari Balakrishnan MIT Computer Science and Artificial Intelligence Laboratory.

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Presentation on theme: "PPR: Partial Packet Recovery for Wireless Networks Kyle Jamieson and Hari Balakrishnan MIT Computer Science and Artificial Intelligence Laboratory."— Presentation transcript:

1 PPR: Partial Packet Recovery for Wireless Networks Kyle Jamieson and Hari Balakrishnan MIT Computer Science and Artificial Intelligence Laboratory

2 2 The problem Lots of packets lost to collisions and noise in wireless networks Non-colliding bits (P1) (P2) Time Can’t recover non-colliding bits today!

3 3 Bits in a packet don’t share fate Many bits from corrupted packets are correct, but status quo receivers don’t know which! (30 node testbed, CSMA on)

4 4 Three key questions 1. How does receiver know which bits are correct? 2. How does receiver know P2 is there at all? 3. How to design an efficient ARQ protocol?

5 5 How can receiver identify correct bits? Use physical layer (PHY) hints: SoftPHY – Receiver PHY has the information! – Pass this confidence information to higher layer as a hint SoftPHY implementation is PHY-specific; interface is PHY-independent Implemented for direct sequence spread spectrum (DSSS) over MSK (this talk) and other modulations

6 6 A new source of information High uncertainty PHY conveys uncertainty in each bit it delivers up Low uncertainty

7 7 Direct seq. spread spectrum background Demodulate MSK signal Decide on closest codeword to received (Hamming distance) Many 32-bit chip sequences are not valid codewords Codewords separated by at least 11 in Hamming distance 802.11 similar Transmitter:Receiver:

8 8 SoftPHY hint for spread spectrum  SoftPHY hint is 2 Receive: 11101101000111000011010110100010 C 1 : 11101101100111000011010100100010  SoftPHY hint is 9 Receive: 11001101000111010111011110110111 C 1 : 11101101100111000011010100100010 Hamming distance between received chips and decided-upon codeword

9 9 Three key questions 1. How does receiver know which bits are correct? 2. How does receiver know P2 is there at all? 3. How to design an efficient ARQ protocol? A: SoftPHY:

10 10 Postamble decoding

11 11 Codeword synchronization – Translate stream of chips to codewords – Search for postamble at all chip offsets Chip synchronization without preamble/postamble Receiver design with postamble 010101001010011101010001011101001010… Offset 0: Offset 3: Chips: Codeword 1 Codeword 2Codeword 3 Codeword 1Codeword 2Codeword 3

12 12 Three key questions 1. How does receiver know which bits are correct? 2. How does receiver know P2 is there at all? 3. How to design an efficient ARQ protocol? A: Postamble: Partial Packets

13 13 ARQ today: correctly-received bits get resent PP-ARQ key idea: resend only incorrect bits Efficiently tell sender about what happened – Feedback packet ARQ with partial packets 1010001101010111101101010101 Hamming distance

14 14 10101011010100001001010101010101 Labeling bits “good” or “bad” Threshold test : pick a threshold  – Label codewords with SoftPHY hint >  “bad” – Label codewords with SoftPHY hint ≤  “good” “good”“bad”  Hamming distance

15 15 PP-ARQ protocol 2. Codewords are in fact correct or incorrect – Two possibilities for mistakes Labeling a correct codeword “bad” Labeling an incorrect codeword “good” “Good” bits “Bad” bits 1. Assuming hints correct, which ranges to ask for? – Dynamic programming problem – Forward and feedback channels

16 16 Implementation Sender: telos tmote sky sensor node – Radio: CC2420 DSSS/MSK (Zigbee) – Modified to send postambles Receiver: USRP software radio with 2.4 GHz RFX 2400 daughterboard – Despreading, postamble synchronization, demodulation – SoftPHY implementation [moteiv.com] [ettus.com] PP-ARQ: trace-driven simulation using data from above

17 17 Live wireless testbed experiments – Senders transmit 101-byte packets, varying traffic rate – Evaluate raw PPR throughput – Evaluate SoftPHY and postamble improvements Trace-driven experiments – Evaluate end-to-end PP-ARQ performance – Internet packet size distribution – 802.11-size preambles Experimental design 25 senders 6 receivers

18 18 PP-ARQ performance comparison Packet CRC (no postamble) Fragmented CRC (no postamble) – Tuned against traces for optimal fragment size Preamble Checksum Preamble Checksum

19 19 Throughput improvement 2.3-2.8x

20 20 PP-ARQ retransmissions are short

21 21 25% improvement over fragmented

22 22 PP-ARQ retransmissions are short

23 23 PP-ARQ feedback overhead is low 802.11 ACK size

24 24 Related work ARQ with memory [Sindhu, IEEE Trans. On Comm. ’77] – Incremental redundancy [Metzner, IEEE Trans. On Comm. ’79] – Code combining [Chase, IEEE Trans. On Comm. ’85] Combining retransmissions – SPaC [Dubois-Ferrière, Estrin, Vetterli; SenSys ’05] Diversity combining – Reliability exchanging [Avudainayagam et al., IEEE WCNC ’03] – MRD [Miu, Balakrishnan, Koksal; MobiCom ’05] – SOFT [Woo et al.; MobiCom ’07] Fragmented CRC – Seda [Ganti et al.; SenSys ’06], 802.11 fragmentation

25 25 Conclusion Mechanisms for recovering correct bits from parts of packets – SoftPHY interface (PHY-independent) – Postamble decoding PP-ARQ improves throughput 2.3–2.8  over the status quo PPR Useful in other apps, e.g. opportunistic forwarding

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