24 research outputs found
Efficient Multi-Pair IoT Communication with Holographically Enhanced Meta-Surfaces Leveraging OAM Beams: Bridging Theory and Prototype
Meta-surfaces, also known as Reconfigurable Intelligent Surfaces (RIS), have
emerged as a cost-effective, low power consumption, and flexible solution for
enabling multiple applications in Internet of Things (IoT). However, in the
context of meta-surface-assisted multi-pair IoT communications, significant
interference issues often arise amount multiple channels. This issue is
particularly pronounced in scenarios characterized by Line-of-Sight (LoS)
conditions, where the channels exhibit low rank due to the significant
correlation in propagation paths. These challenges pose a considerable threat
to the quality of communication when multiplexing data streams. In this paper,
we introduce a meta-surface-aided communication scheme for multi-pair
interactions in IoT environments. Inspired by holographic technology, a novel
compensation method on the whole meta-surface has been proposed, which allows
for independent multi-pair direct data streams transmission with low
interference. To further reduce correlation under LoS channel conditions, we
propose a vortex beam-based solution that leverages the low correlation
property between distinct topological modes. We use different vortex beams to
carry distinct data streams, thereby enabling distinct receivers to capture
their intended signal with low interference, aided by holographic
meta-surfaces. Moreover, a prototype has been performed successfully to
demonstrate two-pair multi-node communication scenario operating at 10 GHz with
QPSK/16-QAM modulation.Comment: Meta-surface, RIS, Internet-of-Things (IoT), Line-of-Sight (LoS),
Orbital Angular Momentum (OAM), holographic communications, multi-use
Holographic MIMO Communications: Theoretical Foundations, Enabling Technologies, and Future Directions
Future wireless systems are envisioned to create an endogenously
holography-capable, intelligent, and programmable radio propagation
environment, that will offer unprecedented capabilities for high spectral and
energy efficiency, low latency, and massive connectivity. A potential and
promising technology for supporting the expected extreme requirements of the
sixth-generation (6G) communication systems is the concept of the holographic
multiple-input multiple-output (HMIMO), which will actualize holographic radios
with reasonable power consumption and fabrication cost. The HMIMO is
facilitated by ultra-thin, extremely large, and nearly continuous surfaces that
incorporate reconfigurable and sub-wavelength-spaced antennas and/or
metamaterials. Such surfaces comprising dense electromagnetic (EM) excited
elements are capable of recording and manipulating impinging fields with utmost
flexibility and precision, as well as with reduced cost and power consumption,
thereby shaping arbitrary-intended EM waves with high energy efficiency. The
powerful EM processing capability of HMIMO opens up the possibility of wireless
communications of holographic imaging level, paving the way for signal
processing techniques realized in the EM-domain, possibly in conjunction with
their digital-domain counterparts. However, in spite of the significant
potential, the studies on HMIMO communications are still at an initial stage,
its fundamental limits remain to be unveiled, and a certain number of critical
technical challenges need to be addressed. In this survey, we present a
comprehensive overview of the latest advances in the HMIMO communications
paradigm, with a special focus on their physical aspects, their theoretical
foundations, as well as the enabling technologies for HMIMO systems. We also
compare the HMIMO with existing multi-antenna technologies, especially the
massive MIMO, present various...Comment: double column, 58 page
Seven Defining Features of Terahertz (THz) Wireless Systems: A Fellowship of Communication and Sensing
Wireless communication at the terahertz (THz) frequency bands (0.1-10THz) is
viewed as one of the cornerstones of tomorrow's 6G wireless systems. Owing to
the large amount of available bandwidth, THz frequencies can potentially
provide wireless capacity performance gains and enable high-resolution sensing.
However, operating a wireless system at the THz-band is limited by a highly
uncertain channel. Effectively, these channel limitations lead to unreliable
intermittent links as a result of a short communication range, and a high
susceptibility to blockage and molecular absorption. Consequently, such
impediments could disrupt the THz band's promise of high-rate communications
and high-resolution sensing capabilities. In this context, this paper
panoramically examines the steps needed to efficiently deploy and operate
next-generation THz wireless systems that will synergistically support a
fellowship of communication and sensing services. For this purpose, we first
set the stage by describing the fundamentals of the THz frequency band. Based
on these fundamentals, we characterize seven unique defining features of THz
wireless systems: 1) Quasi-opticality of the band, 2) THz-tailored wireless
architectures, 3) Synergy with lower frequency bands, 4) Joint sensing and
communication systems, 5) PHY-layer procedures, 6) Spectrum access techniques,
and 7) Real-time network optimization. These seven defining features allow us
to shed light on how to re-engineer wireless systems as we know them today so
as to make them ready to support THz bands. Furthermore, these features
highlight how THz systems turn every communication challenge into a sensing
opportunity. Ultimately, the goal of this article is to chart a forward-looking
roadmap that exposes the necessary solutions and milestones for enabling THz
frequencies to realize their potential as a game changer for next-generation
wireless systems.Comment: 26 pages, 6 figure
A Speculative Study on 6G
While 5G is being tested worldwide and anticipated to be rolled out gradually in 2019, researchers around the world are beginning to turn their attention to what 6G might be in 10+ years time, and there are already initiatives in various countries focusing on the research of possible 6G technologies. This article aims to extend the vision of 5G to more ambitious scenarios in a more distant future and speculates on the visionary technologies that could provide the step changes needed for enabling 6G
Design of Reconfigurable Intelligent Surfaces for Wireless Communication: A Review
Existing literature reviews predominantly focus on the theoretical aspects of
reconfigurable intelligent surfaces (RISs), such as algorithms and models,
while neglecting a thorough examination of the associated hardware components.
To bridge this gap, this research paper presents a comprehensive overview of
the hardware structure of RISs. The paper provides a classification of RIS cell
designs and prototype systems, offering insights into the diverse
configurations and functionalities. Moreover, the study explores potential
future directions for RIS development. Notably, a novel RIS prototype design is
introduced, which integrates seamlessly with a communication system for
performance evaluation through signal gain and image formation experiments. The
results demonstrate the significant potential of RISs in enhancing
communication quality within signal blind zones and facilitating effective
radio wave imaging
Novel Insights into Orbital Angular Momentum Beams: From Fundamentals, Devices to Applications
It is well-known by now that the angular momentum carried by elementary particles can be categorized as spin angular momentum (SAM) and orbital angular momentum (OAM). In the early 1900s, Poynting recognized that a particle, such as a photon, can carry SAM, which has only two possible states, i.e., clockwise and anticlockwise circular polarization states. However, only fairly recently, in 1992, Allen et al. discovered that photons with helical phase fronts can carry OAM, which has infinite orthogonal states. In the past two decades, the OAM-carrying beam, due to its unique features, has gained increasing interest from many different research communities, including physics, chemistry, and engineering. Its twisted phase front and intensity distribution have enabled a variety of applications, such as micromanipulation, laser beam machining, nonlinear matter interactions, imaging, sensing, quantum cryptography and classical communications. This book aims to explore novel insights of OAM beams. It focuses on state-of-the-art advances in fundamental theories, devices and applications, as well as future perspectives of OAM beams
Multi-User Holographic MIMO Surfaces: Channel Modeling and Spectral Efficiency Analysis
The multi-user Holographic Multiple-Input and Multiple-Output Surface
(MU-HMIMOS) paradigm, which is capable of realizing large continuous apertures
with minimal power consumption, has been recently considered as an
energyefficient solution for future wireless networks, offering increased
flexibility in impacting electromagnetic (EM) wave propagation according to the
desired communication, localization, and sensing objectives. The tractable
channel modeling in MU-HMIMOS wireless systems is one of the most critical
research challenges, mainly due to the coupling effect induced by the
excessively large number of closely spaced patch antennas. In this paper, we
focus on this challenge for the downlink of multi-user MIMO communications and
extend an EM-compliant channel model to multiuser case, which is expressed in
the wavenumber domain using the Fourier plane wave approximation. Based on the
presented channel model, we investigate the spectral efficiency of maximumratio
transmission and Zero-Forcing (ZF) precoding schemes. We also introduce a novel
hardware efficient ZF precoder, leveraging Neumann series (NS) expansion to
replace the required matrix inversion operation, which is very hard to be
computed in the conventional way due to the extremely large number of patch
antennas in the envisioned MU-HMIMOS communication systems. In comparison with
the conventional independent and identical Rayleigh fading channels that ignore
antenna coupling effects, the proposed EM-compliant channel model captures the
mutual couplings induced by the very small antenna spacing. Our extensive
performance evaluation results demonstrate that our theoretical performance
expressions approximate sufficiently well ..