Base Station Cooperation on the Downlink: Large System Analysis

Zakhour, Randa; Hanly, Stephen V.

doi:10.1109/tit.2011.2177770

Cited by 123 publications

(157 citation statements)

References 56 publications

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“…After some algebraic manipulations we obtain (44). Note that for τ 2 = 0 and α = α ⋆• , (44) is identical to the asymptotic SINR derived in [3] and for the inter-cell interference-free system in [13]. For β = 1, equation (44) simplifies to γ…”

Section: Sum Rate Maximizing Regularizationmentioning

confidence: 75%

Deterministic Equivalent for the SINR of Regularized Zero-Forcing Precoding in Correlated MISO Broadcast Channels with Imperfect CSIT

Wagner

Couillet

Debbah

et al. 2011

2011 IEEE International Conference on Communications (ICC)

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Abstract-This paper considers the MISO broadcast channel with different spatial correlations of the user vector channels. The base station implements regularized zero-forcing (RZF) precoding based on an imperfect channel estimation. We derive a deterministic equivalent of the signal-to-interference plus noise ratio (SINR) by applying novel results from the field of large dimensional random matrices. Based on this deterministic equivalent, we compute the sum rate maximizing RZF precoder which is given in closed form for independent and identically distributed channels. Simulations show that the accuracy of the approximated SINR extends well into finite dimensions.

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Section: Sum Rate Maximizing Regularizationmentioning

confidence: 75%

Deterministic Equivalent for the SINR of Regularized Zero-Forcing Precoding in Correlated MISO Broadcast Channels with Imperfect CSIT

Wagner

Couillet

Debbah

et al. 2011

2011 IEEE International Conference on Communications (ICC)

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“…To overcome these issues, we follow the same approach as in other works for single-or multi-cell networks [11]- [16] and resort to the asymptotic regime where N and K grow large with a non trivial ratio K/N . The design and analysis of the considered networks is performed under the assumption of imperfect CSI (modeled by the generic Gauss-Markov formulation form) for the UEs.…”

Section: Introductionmentioning

confidence: 99%

“…The design and analysis of the considered networks is performed under the assumption of imperfect CSI (modeled by the generic Gauss-Markov formulation form) for the UEs. Unlike most previous works [13], [16], the asymptotically optimal values of the Lagrange multipliers are computed using recent results from random matrix theory [17], which provide us with a much simpler means to overcome the technical difficulties arising with the application of standard random matrix theory tools. These results are then exploited to compute explicit expressions for the asymptotic signal-to-interference-plus-noise ratios (SINRs), which are eventually used to obtain the asymptotic powers needed to ensure target rates as well as the asymptotic total transmit power.…”

Section: Introductionmentioning

confidence: 99%

“…The main literature related to this work is represented by [12]- [16], [20]. Specifically, a single-cell setting is considered in [12], [20] while a CoBF network is investigated in [13].…”

Section: Introductionmentioning

confidence: 99%

“…In [15], the authors focus on the sum rate of a CoMP under the assumption of regularized zero-forcing precoding. In [16], the authors provide an asymptotic analysis of all considered network configurations but for the simplest case in which only two cells are present and CSI is perfect. The analysis is also conducted under the restrictive assumption that the channels among all UEs within a given cell and the interfering BS can be modelled as ∼ CN (0, ǫI N ) with ǫ controling the interference level between neighbor cells.…”

Section: Introductionmentioning

confidence: 99%

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Large System Analysis of Base Station Cooperation for Power Minimization

Sanguinetti

Couillet

Debbah

2016

IEEE Trans. Wireless Commun.

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Abstract-This work focuses on a large-scale multi-cell multiuser MIMO system in which L base stations (BSs) of N antennas each communicate with K single-antenna user equipments. We consider the design of the linear precoder that minimizes the total power consumption while ensuring target user rates. Three configurations with different degrees of cooperation among BSs are considered: the coordinated beamforming scheme (only channel state information is shared among BSs), the coordinated multipoint MIMO processing technology or network MIMO (channel state and data cooperation), and a single cell beamforming scheme (only local channel state information is used for beamforming while channel state cooperation is needed for power allocation). The analysis is conducted assuming that N and K grow large with a non trivial ratio K/N and imperfect channel state information (modeled by the generic Gauss-Markov formulation form) is available at the BSs. Tools of random matrix theory are used to compute, in explicit form, deterministic approximations for: (i) the parameters of the optimal precoder; (ii) the powers needed to ensure target rates; and (iii) the total transmit power. These results are instrumental to get further insight into the structure of the optimal precoders and also to reduce the implementation complexity in large-scale networks. Numerical results are used to validate the asymptotic analysis in the finite system regime and to make comparisons among the different configurations.

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Universal Access in 5G Networks: Potential Challenges and Opportunities for Urban and Rural Environments

Hassan

Omar

Imran

et al. 2018

5G Networks: Fundamental Requirements, Enabling Technologies, and Operations Management

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As the number of smartphones and demand for higher data-rate connections keep explosively growing, the technology has to pursue this trend in order to be able to provide the suitable communication schemes. By 2020, it is calculated that the total global mobile wireless user devices will be over 10 billion, with the mobile data traffic growing more than 200 times over compared to 2010 numbers. It is foreseeable that 4G mobile communication system could no longer meet the need of users service requirements. Thus, the new 5G communication systems are promising a complete network structure with unlimited access to information, providing the requested service demands to users far beyond what the current 4G offers by supporting innovative new wireless technologies and network architecture to meet the extremely high-performance requirement (Table 1.1).These features include support for new types and massive number of devices, for very high mobile traffic volumes, universal access for users, very high frequency reuse and spectrum reuse in wireless technologies, automated provisioning, configuration and management of a wide range of new network services, ultrareliable, ultralow latency, ultradensification, and even more. 5G networks would be a heterogeneous networks (HetNets), meaning that different networks will be integrated all together to a unified system, enabling

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Base Station Cooperation on the Downlink: Large System Analysis

Cited by 123 publications

References 56 publications

Deterministic Equivalent for the SINR of Regularized Zero-Forcing Precoding in Correlated MISO Broadcast Channels with Imperfect CSIT

Deterministic Equivalent for the SINR of Regularized Zero-Forcing Precoding in Correlated MISO Broadcast Channels with Imperfect CSIT

Large System Analysis of Base Station Cooperation for Power Minimization

Universal Access in 5G Networks: Potential Challenges and Opportunities for Urban and Rural Environments

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