1. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission A Physical-layer Network Coding Relay scheme for IEEE 802.11 Date: 2013-01-11 Authors: Slide1

2. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Slide2 Abstract Based on joint network coding and channel coding, a physical network coding (PNC) transmission scheme for a two-way relay system is proposed. By using the broadcast nature of the wireless medium and the linear property of LDPC codes, only two time slots are required for data transmission. In the first time slot, the two users send their own data to the relay at the same time. In the second time slot, the relay performs joint network decoding and channel decoding, and then forwards the encoded bits to the two users. Simulations results show that the proposed scheme outperforms the conventional decode-and-forward (DF) Relay in term of system throughput, which is increased up to 100%.

3. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Slide3 Background Device-to-device (D2D) communication is a more reasonable scheme for the traffic between a communicating STAs pair, which are closely located with limited interference to the WLAN network. D2D links have several advantages, such as low transport delay and high data rate. One drawback of direct D2D communication is the limited range, the relay is able to extend the communication range and improve the performance of wireless systems. Physical network coding (PNC) is a joint network and channel coding technique that can be used at the relay station to help cooperating users to improve the throughput.

4. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission A Physical-layer Network Coding (PNC) scheme is proposed to further boost the throughput and capacity of the system. Two way relay channel TWRC Slide 4

5. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Diagram of 3-Phase PNC Slide 5

6. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Process flow of 3-phase conventional networking coding scheme : The information bits of STAs S1 and S2 are encoded by LDPC encoder to produce codewords c1 and c2, respectively. And then, modulate to produce complex-valued symbols x1 and x2. Symbols x1 and x2 are sent to relay node in two different time slots, respectively. Relay demodulates and decodes the received symbols y 1 and y 2 to get the estimates c1 and c2, respectively. If the estimates do not satisfy the parity check matrix of LDPC, adopt ARQ protocol and chase combining. If satisfied, Relay performs the network coding and modulates to broadcast for the two STAs in one time slot. Each STA demodulates and decodes the received signal. Process flow Slide 6

7. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Diagram of 2-Phase PNC Slide 7

8. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission System Model of PNC Slide 8 NOTES Multiple access (MA) phase: Two STAs send signals simultaneously in one timeslot to the relay. Broadcast phase: the relay decodes the superimposed signals and maps them to a network- coded (XOR) packet to broadcast to the two STAs.

9. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Process flow of 2-phase PNC scheme : The information bits of STAs S1 and S2 are encoded by the same LDPC encoder to produce codewords c1 and c2, respectively. And then, modulate to produce complex-valued symbols x1 and x2. Symbols x1 and x2 are sent to relay node at the same time in one time slot. Relay demodulates the superimposed received signal to produce the LLRs of as LDPC decoder input, and then decodes by LDPC to get the z estimates. If the z estimates do not satisfy the parity check matrix of LDPC, adopt ARQ and chase combining.. If satisfied, Relay modulates z and broadcasts to two STAs in one timeslot. Each STA demodulates and decodes the received signal. Process flow Slide 9

10. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission In the MA phase, the STAs S1 and S2 send symbols x 1 and x 2 to relay node simultaneously. The AWGN channel and BPSK modulation is considered. The received superimposed signal of relay is, where n is the AWGN random complex variable with mean zero and variance. Define, Assume L denotes the LLR of, Detection and decoding of relay for 2-phase PNC scheme Slide 10 10 0

11. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Simulation Parameters Slide 11 ParametersValues Channel modelAWGN Coding(3,6) LDPC Code rate½ Length of codeword1088 ModulationBPSK Channel estimationPerfect CSI

12. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Throughput performance of two STAs Slide 12 We use term throughput (tp) to indicate the average number of correct received data packets in one time slot for two STAs. The tp performance of the proposed scheme is significantly improved. For SNR -1dB, 2-phase PNC is the best, TP is increased up to 100%.where SNR = Es/ σ 2.

13. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission Conclusions Network coding can significantly boost the throughput and capacity of the system. Compared to the conventional DF relay scheme, the throughput of the 2-phase PNC is increased up to 100%, and the throughput of the 3-phase PNC is increased up to 33%. The proposed scheme can be applied to two-way high-throughput scenarios, such as short-range video communication, short-range two-person interactive 3D game and data synchronization for local devices. Slide 13

14. doc.: IEEE 802.11-13/0111r0 Zhanji Wu, et. Al. December 2012 Submission References [1] K. Doppler, M. Rinne, C. Wijting, C. B. Ribeiro, and K. Hug, Device-to- device communication as an underlay to LTE-advanced networks. IEEE Communications Magazine. vol. 47, pp. 42-49, 2009. [2] Xuanmin Lu, Qiaoyun Qiu, Heng Wu. A Joint Design of Network Coding and Channel Coding for Multiple Access Channel. Modern Electronics Technique. Vol.23, No.06, 2010.pp:52-55. [3] S.Zhang, S.Liew. Channel Coding and Decoding in a Relay System Operated with Physical-Layer Networking Coding. IEEE Journal on Selected Areas in Communications, 2009, pp: 788–796. [4] C. Hausl and J. Hagenauer, Iterative network and channel decoding for the two-way relay channel, in Proc. IEEE International Conference on Communication (ICC 2006), Istanbul, Turkey, Jun. 2006. Slide 14