Wireless Access for Ultra-Reliable Low-Latency Communication: Principles and Building Blocks

Popovski, Petar; Nielsen, Jimmy Jessen; Stefanović, Čedomir; Carvalho, Elisabeth de; Ström, Erik G.; Trillingsgaard, Kasper F.; Bana, Alexandru-Sabin; Kim, Dong-Min; Kotaba, Radosław; Park, Jihong; Sørensen, René

doi:10.1109/mnet.2018.1700258

Cited by 363 publications

(277 citation statements)

References 11 publications

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“…The principles for supporting URLLC are discussed in [3] by considering, for instance, the design of packets and access protocols. In [6], [7] authors outline the key technical requirements and architectural approaches pertaining to wireless access protocols, radio resource management aspects, next generation core networking capabilities, edge-cloud, and edge artificial intelligence capabilities, and propose first avenues for specific solutions to enable the Tactile Internet revolution.…”

Section: And/or If Power Consumptionmentioning

confidence: 99%

“…However, a dedicated receiver on each branch may be needed for systems that transmit continuously in order to simultaneously and continuously monitor SIR on each branch. In this work 3 T 0 may send some pilot symbols as overhead when transmitting to R 0 for the latter be able to estimate the CSI. be able to estimate the CSI.…”

Section: System Modelmentioning

confidence: 99%

“…Notice that this overhead can be accounted as part of the constraint r min (check Section III); while although we assume perfect CSI, the imperfectness may be modeled as a loss in the SIR as in [12], [26]. 4 Diversity is an important building block for supporting URLLC [3], and herein we focus simply on spatial diversity taking advantage of the multiple receive antennas. Notice that other diversity sources such as frequency, time and/or polarization could also be available [28], and our results and methodology can be easily re-utilized/extended to cover such scenario.…”

Section: System Modelmentioning

confidence: 99%

“…As p 0 increases T 0 is capable of transmitting with a larger bit rate for the same reliability target, thus, the curve r 0 vs p 0 with P[O(r 0 , p 0 )] = ε is increasing on p 0 as shown in the figure. Let us focus the attention on the red point on the curve P[O(r 0 , p 0 )] = ε, and notice that for any positive α 1 and α 2 , P[O(r 0 − α 1 , p 0 + α 2 )] < ε holds, but according to (3) and based on the fact that ε ≪ 1 we have that EE(r 0 − α 1 , p 0 + α 2 , β) < EE(r 0 , p 0 , β), thus, the solution of P1 lies on the curve P[O(r 0 , p 0 )] = ε. Additionally, P1 has a non-empty solution when P[O(r min , p max )] ≤ ε. Notice that the solutions of P1, named p * 0 and r * 0 , must depend on information easy to obtain for T 0 .…”

Section: Problem Formulationmentioning

confidence: 99%

See 3 more Smart Citations

Joint Power Control and Rate Allocation Enabling Ultra-Reliability and Energy Efficiency in SIMO Wireless Networks

López

Alves

2019

IEEE Trans. Commun.

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Coming cellular systems are envisioned to open up to new services with stringent reliability and energy efficiency requirements. In this paper we focus on the joint power control and rate allocation problem in Single-Input Multiple-Output (SIMO) wireless systems with Rayleigh fading and stringent reliability constraints. We propose an allocation scheme that maximizes the energy efficiency of the system while making use only of average statistics of the signal and interference, and the number of antennas M that are available at the receiver side. We show the superiority of the Maximum Ratio Combining (MRC) scheme over Selection Combining (SC) in terms of energy efficiency, and prove that the gap between the optimum allocated resources converges to (M !) 1/(2M ) as the reliability constraint becomes more stringent. Meanwhile, in most cases MRC was also shown to be more energy efficient than Switch and Stay Combining (SSC) scheme, although this does not hold only when operating with extremely large M , extremely high/small average signal/interference power and/or highly power consuming receiving circuitry. Numerical results show the feasibility of the ultra-reliable operation when M increases, while greater the fixed power consumption and/or drain efficiency of the transmit amplifier is, the greater the optimum transmit power and rate.

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Section: And/or If Power Consumptionmentioning

confidence: 99%

Section: System Modelmentioning

confidence: 99%

Section: System Modelmentioning

confidence: 99%

Section: Problem Formulationmentioning

confidence: 99%

See 2 more Smart Citations

Joint Power Control and Rate Allocation Enabling Ultra-Reliability and Energy Efficiency in SIMO Wireless Networks

López

Alves

2019

IEEE Trans. Commun.

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“…Multi-connectivity with signal-to-noise ratio (SNR) gain at receiver side using schemes like joint decoding, selection combining and maximal ratio combining (MRC) are discussed in [5]. Use of various diversity sources, packet design and access protocols as key component supporting URLLC in wireless communication system are discussed in [6]. Authors in [7] discussed the way to offer URLLC without intervention in physical layer design by using interface diversity and integrating multiple com-munication interfaces, where each interface is based on different technology.…”

Section: Introductionmentioning

confidence: 99%

Achieving Ultra-Reliable Communication via CRAN-Enabled Diversity Schemes

Kharel

López

Alves

2019

2019 European Conference on Networks and Communications (EuCNC)

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Internet of things is in progress to build a smart society, and wireless networks are critical enablers for many of its use cases. In this paper, we present a multi-coordinated transmission scheme to achieve ultra-reliability for critical machine-type wireless communication networks. We take advantage of diversity, which is fundamental for dealing with fading channel impairments, and for achieving ultra-reliable region of operation in order of five 9's as defined by 3GPP standardization bodies. We evaluate an interference-limited network composed of multiple remote radio heads that are allowed to cooperate, by keeping silence thus reducing interference, or by performing more elaborated strategies such as maximal ratio transmission, in order to serve a user equipment with ultra-reliability. We provide extensive numerical analysis and discuss the gains of cooperation by the centralized radio access network.

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Random Access for Machine‐Type Communications

Leyva-Mayorga¹,

Stefanović²,

Popovski³

et al. 2019

Wiley 5G Ref

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The success of 5G wireless networks (5G) substantially relies on efficiently embracing machine‐type communications (MTC), intended to support autonomous exchange of data between devices. Typical MTC applications include smart metering, e‐health care, environmental and structural monitoring, and asset tracking. Therefore, MTC is an essential component of smart cities and the Internet of Things (IoT). However, cellular networks have traditionally been designed to efficiently handle human‐to‐human (H2H) traffic, whose characteristics greatly differ from those of MTC traffic. Only recently the cellular networks started to be optimized for MTC and, in that sense, a special focus has been put on the random access (RA), which occurs whenever a device requests initial access to a base station (BS). Specifically, the RA mechanism of cellular networks is based on the slotted ALOHA protocol, whose efficiency degrades rapidly as the number of users increases, also presenting a large signaling overhead when short packets are transmitted. The RA channels are further challenged by massive machine‐type communications (mMTC) applications, where a great number of MTC devices attempt to access the BS, while the class of MTC applications with strict latency requirements is challenged by the signaling overhead. These problems have been inherited from the H2H‐oriented cellular systems and, while numerous solutions have been proposed, there is still no consensus on the MTC enhancements for the second phase of 5G standardization.

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Wireless Access for Ultra-Reliable Low-Latency Communication: Principles and Building Blocks

Cited by 363 publications

References 11 publications

Joint Power Control and Rate Allocation Enabling Ultra-Reliability and Energy Efficiency in SIMO Wireless Networks

Joint Power Control and Rate Allocation Enabling Ultra-Reliability and Energy Efficiency in SIMO Wireless Networks

Achieving Ultra-Reliable Communication via CRAN-Enabled Diversity Schemes

Random Access for Machine‐Type Communications

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