826,697 research outputs found
Enabling Disaster Resilient 4G Mobile Communication Networks
The 4G Long Term Evolution (LTE) is the cellular technology expected to
outperform the previous generations and to some extent revolutionize the
experience of the users by taking advantage of the most advanced radio access
techniques (i.e. OFDMA, SC-FDMA, MIMO). However, the strong dependencies
between user equipments (UEs), base stations (eNBs) and the Evolved Packet Core
(EPC) limit the flexibility, manageability and resiliency in such networks. In
case the communication links between UEs-eNB or eNB-EPC are disrupted, UEs are
in fact unable to communicate. In this article, we reshape the 4G mobile
network to move towards more virtual and distributed architectures for
improving disaster resilience, drastically reducing the dependency between UEs,
eNBs and EPC. The contribution of this work is twofold. We firstly present the
Flexible Management Entity (FME), a distributed entity which leverages on
virtualized EPC functionalities in 4G cellular systems. Second, we introduce a
simple and novel device-todevice (D2D) communication scheme allowing the UEs in
physical proximity to communicate directly without resorting to the
coordination with an eNB.Comment: Submitted to IEEE Communications Magazin
Enabling Communication Technologies for Automated Unmanned Vehicles in Industry 4.0
Within the context of Industry 4.0, mobile robot systems such as automated
guided vehicles (AGVs) and unmanned aerial vehicles (UAVs) are one of the major
areas challenging current communication and localization technologies. Due to
stringent requirements on latency and reliability, several of the existing
solutions are not capable of meeting the performance required by industrial
automation applications. Additionally, the disparity in types and applications
of unmanned vehicle (UV) calls for more flexible communication technologies in
order to address their specific requirements. In this paper, we propose several
use cases for UVs within the context of Industry 4.0 and consider their
respective requirements. We also identify wireless technologies that support
the deployment of UVs as envisioned in Industry 4.0 scenarios.Comment: 7 pages, 1 figure, 1 tabl
An Exclusion zone for Massive MIMO With Underlay D2D Communication
Fifth generation networks will incorporate a variety of new features in
wireless networks such as data offloading, D2D communication, and Massive MIMO.
Massive MIMO is specially appealing since it achieves huge gains while enabling
simple processing like MRC receivers. It suffers, though, from a major
shortcoming refereed to as pilot contamination. In this paper we propose a
frame-work in which, a D2D underlaid Massive MIMO system is implemented and we
will prove that this scheme can reduce the pilot contamination problem while
enabling an optimization of the system spectral efficiency. The D2D
communication will help maintain the network coverage while allowing a better
channel estimation to be performed
Orbital angular momentum states enabling fiber-based high-dimensional quantum communication
Quantum networks are the ultimate target in quantum communication, where many
connected users can share information carried by quantum systems. The keystones
of such structures are the reliable generation, transmission and manipulation
of quantum states. Two-dimensional quantum states, qubits, are steadily adopted
as information units. However, high-dimensional quantum states, qudits,
constitute a richer resource for future quantum networks, exceeding the
limitations imposed by the ubiquitous qubits. The generation and manipulation
of such -level systems have been improved over the last ten years, but their
reliable transmission between remote locations remains the main challenge.
Here, we show how a recent air-core fiber supporting orbital angular momentum
(OAM) modes can be exploited to faithfully transmit -dimensional states.
Four OAM quantum states and their superpositions are created, propagated in a
1.2 km long fiber and detected with high fidelities. In addition, three quantum
key distribution (QKD) protocols are implemented as concrete applications to
assert the practicality of our results. This experiment enhances the
distribution of high-dimensional quantum states, attesting the orbital angular
momentum as vessel for the future quantum network
Optical communication on CubeSats - Enabling the next era in space science
CubeSats are excellent platforms to rapidly perform simple space experiments.
Several hundreds of CubeSats have already been successfully launched in the
past few years and the number of announced launches grows every year. These
platforms provide an easy access to space for universities and organizations
which otherwise could not afford it. However, these spacecraft still rely on RF
communications, where the spectrum is already crowded and cannot support the
growing demand for data transmission to the ground. Lasercom holds the promise
to be the solution to this problem, with a potential improvement of several
orders of magnitude in the transmission capacity, while keeping a low size,
weight and power. Between 2016 and 2017, The Keck Institute for Space Studies
(KISS), a joint institute of the California Institute of Technology and the Jet
Propulsion Laboratory, brought together a group of space scientists and
lasercom engineers to address the current challenges that this technology
faces, in order to enable it to compete with RF and eventually replace it when
high-data rate is needed. After two one-week workshops, the working group
started developing a report addressing three study cases: low Earth orbit,
crosslinks and deep space. This paper presents the main points and conclusions
of these KISS workshops.Comment: 7 pages, 5 figures, 2 tables, Official Final Report of KISS (Keck
Institute for Space Studies) workshop on "Optical communication on CubeSats"
(http://kiss.caltech.edu/workshops/optcomm/optcomm.html
MO BIDIC - Teletype Interface
Device for enabling two-way communication between twin digital computer and teletypewrite
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