Blind Known Interference Cancellation

This paper investigates interference-cancellation schemes at the receiver, in which the interference data, which is valid data intended for another receiver, is known a priori. The interference channel, however, is unknown (the blind part). Such a priori knowledge is common in wireless relay networks. For example, a relay could be relaying data that was previously transmitted by a node A. If node A is now receiving a signal from another node B, the interference from the relay is actually self-information known to node A. Besides the case of self-information, the node could also have overheard or received the interference data in a prior transmission by another node. Directly removing the known interference requires accurate estimate of the interference channel, which may be difficult in many situations. In this paper, we propose a novel scheme, Blind Known-Interference Cancellation (BKIC), to cancel known interference without interference channel information. BKIC consists of two steps. The first step combines adjacent symbols to cancel the interference, exploiting the fact that the channel coefficients are almost the same between successive symbols. After such interference cancellation, however, the signal of interest is distorted. The second step recovers the signal of interest amidst the distortion. We propose two algorithms for the critical second steps. The first algorithm (BKIC-S) is based on the principle of smoothing. It is simple and has near optimal performance in the slow fading scenario. The second algorithm (BKIC-RBP) is based on the principle of real-valued belief propagation. Since there is no loop in the Tanner graph, BKIC-RBP can achieve MAP-optimal performance with fast convergence, and has near interference-free performance even in the fast fading scenario. Both BKIC schemes outperform the traditional self-interference cancellation schemes that have perfect initial channel information by a large margin, while having lower complexities.

[1]  Soung Chang Liew,et al.  > Replace This Line with Your Paper Identification Number (double-click Here to Edit) < 1 , 2022 .

[2]  Philip Levis,et al.  Achieving single channel, full duplex wireless communication , 2010, MobiCom.

[3]  Dina Katabi,et al.  SourceSync: a distributed wireless architecture for exploiting sender diversity , 2010, SIGCOMM '10.

[4]  John G. Proakis,et al.  Digital Communications , 1983 .

[5]  Athanasios V. Vasilakos,et al.  Differential Modulation for Bidirectional Relaying With Analog Network Coding , 2010, IEEE Transactions on Signal Processing.

[6]  Soung Chang Liew,et al.  Implementation of physical-layer network coding , 2013, Phys. Commun..

[7]  W. Hirt,et al.  Robust noncoherent receiver exploiting UWB channel properties , 2004, 2004 International Workshop on Ultra Wideband Systems Joint with Conference on Ultra Wideband Systems and Technologies. Joint UWBST & IWUWBS 2004 (IEEE Cat. No.04EX812).

[8]  Sae-Young Chung,et al.  On the design of low-density parity-check codes within 0.0045 dB of the Shannon limit , 2001, IEEE Communications Letters.

[9]  Soung Chang Liew,et al.  Asynchronous Physical-Layer Network Coding , 2012, IEEE Transactions on Wireless Communications.

[10]  J.M. Shea,et al.  Overlapped Transmission in Wireless Ad hoc Networks , 2006, 2006 International Conference on Communications, Circuits and Systems.

[11]  Soung Chang Liew,et al.  Physical Layer Network Coding Schemes over Finite and Infinite Fields , 2008, IEEE GLOBECOM 2008 - 2008 IEEE Global Telecommunications Conference.

[12]  R.W. Brodersen,et al.  Spectrum Sensing Measurements of Pilot, Energy, and Collaborative Detection , 2006, MILCOM 2006 - 2006 IEEE Military Communications conference.

[13]  Soung Chang Liew,et al.  Implementation of physical-layer network coding , 2011, 2012 IEEE International Conference on Communications (ICC).

[14]  Dina Katabi,et al.  Zigzag decoding: combating hidden terminals in wireless networks , 2008, SIGCOMM '08.

[15]  Tolga M. Duman,et al.  Noise predictive belief propagation , 2005, IEEE Transactions on Magnetics.

[16]  Tolga M. Duman,et al.  Belief propagation over frequency selective fading channels , 2004, IEEE 60th Vehicular Technology Conference, 2004. VTC2004-Fall. 2004.

[17]  Qinfang Sun,et al.  Estimation of continuous flat fading MIMO channels , 2002, 2002 IEEE Wireless Communications and Networking Conference Record. WCNC 2002 (Cat. No.02TH8609).

[18]  P. Bello Characterization of Randomly Time-Variant Linear Channels , 1963 .

[19]  Piero Castoldi Multiuser Detection in CDMA Mobile Terminals , 2002 .

[20]  Chintha Tellambura,et al.  Differential modulation for two-way wireless communications: a perspective of differential network coding at the physical layer , 2009, IEEE Transactions on Communications.

[21]  W. C. Jakes,et al.  Microwave Mobile Communications , 1974 .

[22]  Srihari Nelakuditi,et al.  Known Interference Cancellation: Resolving Collisions Due to Repeated Transmissions , 2010, 2010 Fifth IEEE Workshop on Wireless Mesh Networks.

[23]  Ying-Chang Liang,et al.  On Channel Estimation for Amplify-and-Forward Two-Way Relay Networks , 2008, IEEE GLOBECOM 2008 - 2008 IEEE Global Telecommunications Conference.

[24]  Sachin Katti,et al.  Embracing wireless interference: analog network coding , 2007, SIGCOMM '07.

[25]  Soung Chang Liew,et al.  Physical-layer network coding: Tutorial, survey, and beyond , 2011, Phys. Commun..

[26]  Michael L. Honig,et al.  A message-passing approach for joint channel estimation, interference mitigation, and decoding , 2009, IEEE Transactions on Wireless Communications.

[27]  Michael Gastpar,et al.  Cooperative strategies and capacity theorems for relay networks , 2005, IEEE Transactions on Information Theory.

[28]  Gregory W. Wornell,et al.  Distributed space-time-coded protocols for exploiting cooperative diversity in wireless networks , 2003, IEEE Trans. Inf. Theory.