Fading Relay Channels: Performance Limits and Space–Time Signal Design

Nabar, R.U.; Bölcskei, Helmut; Kneubuhler, F.W.

doi:10.1109/jsac.2004.830922

Cited by 1,663 publications

(1,163 citation statements)

References 35 publications

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“…When the assisting relays work under the half-duplex constraint, different cooperative protocols are possible [20]. Every protocol exhibits different capacity properties, but the efficiency of the cooperative transmission also depends on the way resources are allocated to the source and relay terminals.…”

Section: Optimization Schemes and Approachesmentioning

confidence: 99%

Cooperative Wireless Networking Beyond Store-and-Forward

Valentin

Lichte

Karl

et al. 2007

Wireless Pers Commun

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Abstract. In future wireless networks devices may cooperate to form logical links. Each of these links may consist of several independent physical channels which are shared by the cooperating partners. Even without multiple antennas this cooperation provides diversity in time and space. This so-called cooperation diversity increases the robustness of the link vs. fading and interference. After surveying approaches in cooperation diversity we focus on optimizing its performance by combining several cooperation schemes and by integrating cooperation into space-time coding. For multiple scenarios, we further discuss the factors and benefits introduced by user cooperation and how cooperation-aware resource allocation can be employed to further increase the performance of cooperative networks. When it comes to implementation, the question arises how cooperation can be integrated efficiently into existing wireless networks. A case study for 802.11-based WLANs reveals the issues that need to be solved in order to deploy cooperative techniques. We provide an overview of the state of the art in implementing cooperation approaches, analyze how appropriate these approaches solve the issues, and, where appropriate, point out their deficiencies. We conclude with a road map for future research necessary to tackle these deficiencies for the practical implementation of cooperation in next generation mesh, WLAN, WMAN, and cellular standards.

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Section: Optimization Schemes and Approachesmentioning

confidence: 99%

Cooperative Wireless Networking Beyond Store-and-Forward

Valentin

Lichte

Karl

et al. 2007

Wireless Pers Commun

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“…Especially, it is crucial in cellular environments to mitigate intercell interference for an increased rate and extended coverage at cell edge. In such efforts, various relaying protocols such as amplify-and-forward (AF), decode-and-forward (DF), compress-and-forward (CF) have been proposed [1], [2], [3], [4]. Those relaying schemes are mainly to exploit the multipath diversity for power gain (or increased rate) that results from combining direct and relayed signals.…”

Section: Introductionmentioning

confidence: 99%

Partial Information Relaying with Per Antenna Superposition Coding

Kim

Choi

Seo

et al. 2010

IEEE Trans. Commun.

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Abstract-In this letter we propose per antenna superposition coding (PASC) by which partial information can be relayed instead of full information, to exploit the higher capacity of source-relay-destination link. Here, the PASC is designed across antennas, producing basic layer and superposed layer for each data stream per antenna. It is shown that an overall data rate of partial information relaying with PASC can be increased beyond that offered by full information relaying by virtue of fast forwarding of partial information over relatively better link.Index Terms-Cooperative relaying, multiple antennas, per antenna superposition coding (PASC), partial information, rate matching, power allocation.

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“…One approach to improving the capacity of the network is to employ cooperative communication techniques, in which multiple nodes in the network cooperate to transmit information to a desired receiver node. Recently, both cooperative relay strategies [1][2][3][4][5][6] and cooperative transmission strategies [7][8][9][10] have been extensively studied. In this paper, we consider a cooperative transmission strategy based on a technique called time-reversal communication (TRC), which can be regarded as generalization of beamforming.…”

Section: Introductionmentioning

confidence: 99%

Performance of Cooperative Time-Reversal Communication in a Mobile Wireless Environment

Barton

Huang

et al. 2007

International Journal of Distributed Sensor Networks

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In this paper, we study the performance of a technique called time reversal for cooperative communication in a mobile wireless environment. To put the work in context, a brief introduction to timereversal communication (TRC) in general and cooperative TRC in particular is presented. Performance of a proposed cooperative TRC scheme is evaluated numerically via a simulated indoor environment containing multiple wireless communication nodes. We characterize the behavior of the peak power received at a target node as a function of the number of cooperating transmitting nodes and as a function of the distance of the target from its predicted location within the simulated environment.The results demonstrate that the performance of cooperative TRC is less sensitive to uncertainty in the target position than might be expected from standard assumptions regarding the relationship between signal wavelength and spatial channel correlation in a complex multipath environment.

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Fading Relay Channels: Performance Limits and Space–Time Signal Design

Cited by 1,663 publications

References 35 publications

Cooperative Wireless Networking Beyond Store-and-Forward

Cooperative Wireless Networking Beyond Store-and-Forward

Partial Information Relaying with Per Antenna Superposition Coding

Performance of Cooperative Time-Reversal Communication in a Mobile Wireless Environment

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