On the Application of Massive MIMO Systems to Machine Type Communications

Figueiredo, Felipe Augusto Pereira de; Cardoso, Fabbryccio A. C. M.; Moerman, Ingrid; Fraidenraich, Gustavo

doi:10.1109/access.2018.2886030

Cited by 21 publications

(15 citation statements)

References 72 publications

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“…Unfortunately, the exact distribution for large n is very intricate and its evaluation becomes computationally prohibitive. However, as n increases, the distributions of C and S, given in (11) and (12) respectively, become approximately Gaussian due to central limit theorem [30], that is C ∼ N (μ C , σ 2 C ), and S ∼ N (μ S , σ 2 S ). Since C and S are uncorrelated (see Appendix C), for the Gaussian case, this condition implies that they are also independent random variables [31], and therefore their joint distribution can be given as The analytical expression for the mean μ C and variance σ 2 C of C, are expressed by (34) and (43), respectively in Appendix A.…”

Section: B Approximated Distribution Of |H| For Large Nmentioning

confidence: 99%

“…The use of reflecting surfaces to perform beamforming has emerged in the last three years as an alternative to the sixth generation of mobile communications. Hu et al [11] use adjacent surfaces, covered with a magnetic and active material capable of being electronically and intelligently manipulated, to solve wireless communication tasks [12].…”

Section: Introductionmentioning

confidence: 99%

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Bit Error Probability for Large Intelligent Surfaces Under Double-Nakagami Fading Channels

Ferreira

Facina

Figueiredo

et al. 2020

IEEE Open J. Commun. Soc.

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In this work, we investigate the probability distribution function of the channel fading between a base station, an array of intelligent reflecting elements, known as large intelligent surfaces (LIS), and a single-antenna user. We assume that both fading channels, i.e., the channel between the base station and the LIS, and the channel between the LIS and the single user are Nakagami-m distributed. Additionally, we derive the exact bit error probability considering quadrature amplitude (M-QAM) and binary phase-shift keying (BPSK) modulations when the number of LIS elements, n, is equal to 2 and 3. We assume that the LIS can perform phase adjustment, but there is a residual phase error modeled by a Von Mises distribution. Based on the central limit theorem, and considering a large number of reflecting elements, we also present an accurate approximation and upper bounds for the bit error rate. Through several Monte Carlo simulations, we demonstrate that all derived expressions perfectly match the simulated results. INDEX TERMS Bit error rate, large intelligent surfaces, massive MIMO, Nakagami-m fading, von Mises circular distribution.

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Section: B Approximated Distribution Of |H| For Large Nmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bit Error Probability for Large Intelligent Surfaces Under Double-Nakagami Fading Channels

Ferreira

Facina

Figueiredo

et al. 2020

IEEE Open J. Commun. Soc.

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“…The Remark 14 shows that as N grows without bound, the transmit power can be reduced proportionally to 1/N 2 . The transmit power reduction is significant mainly to powerconstrained devices such as Internet of Things (IoT) devices [27,28].…”

Section: G Power-scaling Lawmentioning

confidence: 99%

Large Intelligent Surfaces With Discrete Set of Phase-Shifts Communicating Through Double-Rayleigh Fading Channels

Figueiredo¹,

Facina²,

Ferreira³

et al. 2020

Preprint

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It is known that the Central Limit Theorem (CLT) is not always the most appropriate tool for deriving closed-form expressions. We evaluate a Single-Input Single-Output (SISO) system performance in which the Large Intelligent Surface (LIS) acts as a scatterer. The direct link between the transmitting and receiving devices is negligible. Quantization phase errors are considered since the high precision configuration of the reflection phases is not always feasible. We derive exact closed-form expressions for the spectral efficiencies, outage probabilities, and average symbol error rate (SER) of different modulations. We assume a more comprehensive scenario in which $b$ bits are dedicated to the LIS elements' phase adjustment. From Monte Carlo simulations, we prove the excellent accuracy of our approach and investigate the behavior of power scaling law and power required to reach a specific capacity, depending on the number of reflecting elements. We show that the LIS with approximately fifty elements and four dedicated bits for phase quantization outperforms the conventional system performance without LIS.

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“…By taking advantage of these two features, mMIMO is able to spatially separate signals that are simultaneously transmitted by a large number of URLLC devices over the same channel resource in GF random access, which makes it a prominent enabler for massive access [31]. Furthermore, simple linear processing such as conjugate beamforming and zero-forcing (ZF) beamforning can achieve near-optimal performance with favorable propagation [83]. In this subsection, we present a number of potential enhancements to GF URLLC by mMIMO.…”

Section: B Enhancements To Gf Urllcmentioning

confidence: 99%

Enabling Grant-Free URLLC: An Overview of Principle and Enhancements by Massive MIMO

Ding¹,

Pokhrel²,

Park³

et al. 2021

Preprint

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<div>Enabling ultra-reliable low-latency communication (URLLC) with stringent requirements for transmitting data packets (e.g., 99.999% reliability and 1 millisecond latency) presents considerable challenges in uplink transmissions. For each packet transmission over dynamically allocated network radio resources, the conventional random access protocols are based on a request- rant scheme. This induces excessive latency and necessitates reliable control signalling, resulting overhead. To address these problems, grant-free (GF) solutions are proposed in the fifth-generation (5G) new radio (NR). In this paper, an overview and vision of the state-of-the-art in enabling GF URLLC are presented. In particular, we first provide a comprehensive review of NR specifications and techniques for URLLC, discuss underlying principles, and highlight impeding issues of enabling GF URLLC. Furthermore, we explain two key phenomena of massive multiple-input multiple-output (mMIMO) (i.e., channel hardening and favorable propagation) and build several deep insights into how celebrated mMIMO features can be exploited to enhance the performance of GF URLLC. Moving further ahead, we examine the potential of cell-free (CF) mMIMO and analyze its distinctive features and benefits over mMIMO to resolve GF URLLC issues. Finally, we identify future research directions and challenges in enabling GF URLLC with CF mMIMO.</div>

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On the Application of Massive MIMO Systems to Machine Type Communications

Cited by 21 publications

References 72 publications

Bit Error Probability for Large Intelligent Surfaces Under Double-Nakagami Fading Channels

Bit Error Probability for Large Intelligent Surfaces Under Double-Nakagami Fading Channels

Large Intelligent Surfaces With Discrete Set of Phase-Shifts Communicating Through Double-Rayleigh Fading Channels

Enabling Grant-Free URLLC: An Overview of Principle and Enhancements by Massive MIMO

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