Optimal Resource Allocation in Coordinated Multi-Cell Systems

Björnson, Emil

doi:10.1561/0100000069

Cited by 298 publications

(321 citation statements)

References 226 publications

(452 reference statements)

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“…However, in practice, hardware suffers from impairments; for example, phase noise, IQ imbalance, and amplifier non-linearities [4][5][6]. These have a deleterious impact on the achievable performance [7][8][9][10][11][12][13]. This effect is more pronounced in high-rate systems, especially those employing inexpensive hardware [5].…”

Section: Introductionmentioning

confidence: 99%

“…This effect is more pronounced in high-rate systems, especially those employing inexpensive hardware [5]. For instance, some recent works have demonstrated that non-ideal hardware severely affects single-hop multiantenna systems; [6,8] proved that there is a finite capacity limit at high SNR, while [9,13] showed that existing signal processing algorithms need to be re-designed to account for these impairments.…”

Section: Introductionmentioning

confidence: 99%

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On the impact of transceiver impairments on af relaying

Björnson¹,

Papadogiannis

Matthaiou

et al. 2013

2013 IEEE International Conference on Acoustics, Speech and Signal Processing

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Recently, it was shown that transceiver hardware impairments have a detrimental impact on the performance of communication systems, especially for high-rate systems. The vast majority of technical contributions in the area of relaying assume ideal transceiver hardware. This paper quantifies the impact of transceiver hardware impairments in dual-hop Amplify-and-Forward (AF) relaying, both for fixed and variable gain relays. The outage probability (OP) in this practical scenario is a function of the instantaneous end-toend signal-to-noise-and-distortion ratio (SNDR). This paper derives closed-form expressions for the exact and asymptotic OPs under Rayleigh fading, accounting for hardware impairments at both the transmitter and the relay. The performance loss is small at low spectral efficiency, but can otherwise be very substantial. In particular, it turns out that for high signal-to-noise ratio (SNR), the instantaneous end-to-end SNDR converges to a deterministic constant, called the SNDR ceiling, which is inversely proportional to the level of impairments. This stands in stark contrast to the ideal hardware case for which the end-to-end SNDR grows without bound in the high SNR regime.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the impact of transceiver impairments on af relaying

Björnson¹,

Papadogiannis

Matthaiou

et al. 2013

2013 IEEE International Conference on Acoustics, Speech and Signal Processing

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“…Besides the conclusions in Section III-A, (8) shows that D2D mode is optimal when the interference received at UE 2 is much smaller than the one received at the base station, i.e., I D2D I ul . By solving (8) as a quadratic equation, we have…”

Section: B D2d Optimality With a Shared Resourcementioning

confidence: 81%

“…As shown in [8], the optimization problems (P1) and (P2) are tightly connected [8]: let the optimal solution to (P1) with transmit power p * UE be denotedR * , then the optimal solution to (P2) with the QoS levelR * is exactly p * UE . Nevertheless, we show that these optimization problems behave differently in terms of when D2D mode is preferable over cellular mode, and vice versa.…”

Section: A System Modelmentioning

confidence: 99%

“…Furthermore, we take into account the effects of multiple antennas in the BS as it is an important feature of LTE and IMT-Advanced systems that enables simultaneous scheduling of spatially separated users [1], [8], [9]. The mode selection problem is formulated with two objectives: maximizing the QoS for a given transmit power, and minimizing the power for a given QoS.…”

Section: Introductionmentioning

confidence: 99%

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Closed-form optimality characterization of network-assisted device-to-device communications

Shalmashi

Björnson

Slimane

et al. 2014

2014 IEEE Wireless Communications and Networking Conference (WCNC)

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International audience—This paper considers the mode selection problem for network-assisted device-to-device (D2D) communications with multiple antennas at the base station. We study transmission in both dedicated and shared frequency bands. Given the type of resources (i.e., dedicated or shared), the user equipment (UE) decides to transmit in the conventional cellular mode or directly to its corresponding receiver in the D2D mode. We formulate this problem under two different objectives. The first problem is to maximize the quality-of-service (QoS) given a transmit power, and the second problem is to minimize the transmit power given a QoS requirement. We derive closed-form results for the optimal decision and show that the two problem formulations behave differently. Taking a geometrical approach, we study the area around the transmitter UE where the receiving UE should be to have D2D mode optimality, and how it is affected by the transmit power, QoS, and the number of base station antennas. I. INTRODUCTION Emerging multimedia services and applications introduce new traffic types and user behaviors [1]. To address the higher demands imposed on wireless networks, more spectrally effi-cient and energy efficient approaches should be developed. Device-to-device (D2D) communication underlaying cellular networks is proposed to improve cell spectral and energy efficiency of the network [2], [3]. In D2D transmission mode, user equipments (UEs) communicate directly to their intended receivers as opposed to the conventional cellular mode where they communicate through the base station (BS). D2D mode can bring proximity gains and reduce the transmission time. Users in the D2D mode can transmit either in a separate frequency band or via spectrum sharing with cellular users. In the former case, D2D communications do not interfere with cellular users. This case is interesting due to its potential applications, such as public safety and multicasting for local multimedia services and robustness to infrastructure failure. On the other hand, spectrum sharing can be employed to efficiently utilize the resources which allows for better area spectral efficiency [4]. The gain from spectrum sharing can be assured if the interference is controlled by proper mode selection and resource management. However, depending on the network topology and channel conditions, it may not always be beneficial to choose the D2D mode for a UE

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MassiveMIMO

Verenzuela

Björnson

2019

Wiley Encyclopedia of Electrical and Electronics Engineering

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Massive MIMO, where MIMO stands for multiple‐input multiple‐output, is a multiuser‐MIMO (MU‐MIMO) cellular communication technology with a massive number of antennas and users. More precisely, each base station (BS) is equipped with a large number of antennas and utilizes these antennas to spatially multiplex many user equipments (UEs) on the same time‐frequency resource. The main difference from conventional cellular networks is that the interference between UEs is managed by spatial processing (called transmit precoding or receive combining) instead of by scheduling them on orthogonal time‐frequency resources. The key differentiator from conventional MU‐MIMO systems is that the users' channels become nearly orthogonal – a property referred to as “favorable propagation” – when the BS has a large number of antennas. This property vastly reduces the interference and thus allows for spatial multiplexing of many tens of UEs, instead of a handful UEs. In addition, favorable propagation enables the use of relatively simple linear signal processing techniques for interference suppression.

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Optimal Resource Allocation in Coordinated Multi-Cell Systems

Cited by 298 publications

References 226 publications

On the impact of transceiver impairments on af relaying

On the impact of transceiver impairments on af relaying

Closed-form optimality characterization of network-assisted device-to-device communications

MassiveMIMO

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