Mahyar Nemati scite author profile

The Internet of Things (IoT) is rapidly becoming an integral part of our life and also multiple industries. We expect to see the number of IoT connected devices explosively grows and will reach hundreds of billions during the next few years. To support such a massive connectivity, various wireless technologies are investigated. In this survey, we provide a broad view of the existing wireless IoT connectivity technologies and discuss several new emerging technologies and solutions that can be effectively used to enable massive connectivity for IoT. In particular, we categorize the existing wireless IoT connectivity technologies based on coverage range and review diverse types of connectivity technologies with different specifications. We also point out key technical challenges of the existing connectivity technologies for enabling massive IoT connectivity. To address the challenges, we further review and discuss some examples of promising technologies such as compressive sensing (CS) random access, non-orthogonal multiple access (NOMA), and massive multiple input multiple output (mMIMO) based random access that could be employed in future standards for supporting IoT connectivity. Finally, a classification of IoT applications is considered in terms of various service requirements. For each group of classified applications, we outline its suitable IoT connectivity options.

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RIS-Assisted Coverage Enhancement in Millimeter-Wave Cellular Networks

Nemati

Park

Choi

2020

IEEE Access

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The use of millimeter-wave (mmWave) bandwidth is one key enabler to achieve the high data rates in the fifth-generation (5G) cellular systems. However, mmWave signals suffer from significant path loss due to high directivity and sensitivity to blockages, limiting its adoption within small-scale deployments. To enhance the coverage of mmWave communication in 5G and beyond, it is promising to deploy a large number of reconfigurable intelligent surfaces (RISs) that passively reflect mmWave signals towards desired directions. With this motivation, in this work, we study the coverage of an RIS-assisted large-scale mmWave cellular network using stochastic geometry, and derive the peak reflection power expression of an RIS and the downlink signal-to-interference ratio (SIR) coverage expression in closed forms. These analytic results clarify the effectiveness of deploying RISs in the mmWave SIR coverage enhancement, while unveiling the major role of the density ratio between active base stations (BSs) and passive RISs. Furthermore, the results show that deploying passive reflectors are as effective as equipping BSs with more active antennas in the mmWave coverage enhancement. Simulation results confirm the tightness of the closed-form expressions, corroborating our major findings based on the derived expressions.INDEX TERMS Millimeter-wave (mmWave), reconfigurable intelligent surface (RIS), coverage, signalto-interference ratio (SIR), stochastic geometry.

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Short-Range Ambient Backscatter Communication Using Reconfigurable Intelligent Surfaces

Nemati

Ding

Choi

2020

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Ambient backscatter communication (AmBC) has been introduced to address communication and power efficiency issues for short-range and low-power Internet-of-Things (IoT) applications. On the other hand, reconfigurable intelligent surface (RIS) has been recently proposed as a promising approach that can control the propagation environment especially in indoor communication environments. In this paper, we propose a new AmBC model over ambient orthogonal-frequency-divisionmultiplexing (OFDM) subcarriers in the frequency domain in conjunction with RIS for short-range communication scenarios. A tag transmits one bit per each OFDM subcarrier broadcasted from a WiFi access point. Then, RIS augments the signal quality at a reader by compensating the phase distortion effect of multipath channel on the incident signal. We also exploit the special spectrum structure of OFDM to transmit more data over its squeezed orthogonal subcarriers in the frequency domain. Consequently, the proposed method improves the bit-error-rate (BER) performance and provides a higher data rate compared to existing AmBC methods. Analytical and numerical evaluations show the superior performance of the proposed approach in terms of BER and data rate.

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Modeling RIS Empowered Outdoor-to-Indoor Communication in mmWave Cellular Networks

Nemati

Maham

Pokhrel

et al. 2021

IEEE Trans. Commun.

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Low ICI Symbol Boundary Alignment for 5G Numerology Design

Nemati

Pecht

2018

IEEE Access

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

Ding¹,

Nemati²,

Pokhrel³

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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Performance Analysis of Massive MIMO Assisted Semi-Grant-Free Random Access

Ding

Feng

Nemati

et al. 2021

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Performance of TDOA and AOA Localization Techniques for Different Base-Stations Topologies

Nemati

Baykas

Choi

2019

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Mahyar Nemati

IoT Connectivity Technologies and Applications: A Survey

RIS-Assisted Coverage Enhancement in Millimeter-Wave Cellular Networks

Short-Range Ambient Backscatter Communication Using Reconfigurable Intelligent Surfaces

Modeling RIS Empowered Outdoor-to-Indoor Communication in mmWave Cellular Networks

Low ICI Symbol Boundary Alignment for 5G Numerology Design

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

Performance Analysis of Massive MIMO Assisted Semi-Grant-Free Random Access

Performance of TDOA and AOA Localization Techniques for Different Base-Stations Topologies

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