823 research outputs found
AoA-aware Probabilistic Indoor Location Fingerprinting using Channel State Information
With expeditious development of wireless communications, location
fingerprinting (LF) has nurtured considerable indoor location based services
(ILBSs) in the field of Internet of Things (IoT). For most pattern-matching
based LF solutions, previous works either appeal to the simple received signal
strength (RSS), which suffers from dramatic performance degradation due to
sophisticated environmental dynamics, or rely on the fine-grained physical
layer channel state information (CSI), whose intricate structure leads to an
increased computational complexity. Meanwhile, the harsh indoor environment can
also breed similar radio signatures among certain predefined reference points
(RPs), which may be randomly distributed in the area of interest, thus mightily
tampering the location mapping accuracy. To work out these dilemmas, during the
offline site survey, we first adopt autoregressive (AR) modeling entropy of CSI
amplitude as location fingerprint, which shares the structural simplicity of
RSS while reserving the most location-specific statistical channel information.
Moreover, an additional angle of arrival (AoA) fingerprint can be accurately
retrieved from CSI phase through an enhanced subspace based algorithm, which
serves to further eliminate the error-prone RP candidates. In the online phase,
by exploiting both CSI amplitude and phase information, a novel bivariate
kernel regression scheme is proposed to precisely infer the target's location.
Results from extensive indoor experiments validate the superior localization
performance of our proposed system over previous approaches
Thirty Years of Machine Learning: The Road to Pareto-Optimal Wireless Networks
Future wireless networks have a substantial potential in terms of supporting
a broad range of complex compelling applications both in military and civilian
fields, where the users are able to enjoy high-rate, low-latency, low-cost and
reliable information services. Achieving this ambitious goal requires new radio
techniques for adaptive learning and intelligent decision making because of the
complex heterogeneous nature of the network structures and wireless services.
Machine learning (ML) algorithms have great success in supporting big data
analytics, efficient parameter estimation and interactive decision making.
Hence, in this article, we review the thirty-year history of ML by elaborating
on supervised learning, unsupervised learning, reinforcement learning and deep
learning. Furthermore, we investigate their employment in the compelling
applications of wireless networks, including heterogeneous networks (HetNets),
cognitive radios (CR), Internet of things (IoT), machine to machine networks
(M2M), and so on. This article aims for assisting the readers in clarifying the
motivation and methodology of the various ML algorithms, so as to invoke them
for hitherto unexplored services as well as scenarios of future wireless
networks.Comment: 46 pages, 22 fig
Sub-Nanosecond Time of Flight on Commercial Wi-Fi Cards
Time-of-flight, i.e., the time incurred by a signal to travel from
transmitter to receiver, is perhaps the most intuitive way to measure distances
using wireless signals. It is used in major positioning systems such as GPS,
RADAR, and SONAR. However, attempts at using time-of-flight for indoor
localization have failed to deliver acceptable accuracy due to fundamental
limitations in measuring time on Wi-Fi and other RF consumer technologies.
While the research community has developed alternatives for RF-based indoor
localization that do not require time-of-flight, those approaches have their
own limitations that hamper their use in practice. In particular, many existing
approaches need receivers with large antenna arrays while commercial Wi-Fi
nodes have two or three antennas. Other systems require fingerprinting the
environment to create signal maps. More fundamentally, none of these methods
support indoor positioning between a pair of Wi-Fi devices
without~third~party~support.
In this paper, we present a set of algorithms that measure the time-of-flight
to sub-nanosecond accuracy on commercial Wi-Fi cards. We implement these
algorithms and demonstrate a system that achieves accurate device-to-device
localization, i.e. enables a pair of Wi-Fi devices to locate each other without
any support from the infrastructure, not even the location of the access
points.Comment: 14 page
Implementation of improvements of the Wi-Fi network of the RTBF and implementation of a Wi-Fi network for an “intelligent” building
Este Trabajo de Fin de Grado se ha realizado dentro de la Radio Televisión Belga Francófona (RTBF)
en Bruselas. El objetivo de este proyecto es el diseño de una red Wi-Fi completamente confiable y de
alto rendimiento para una de sus localizaciones.
Para empezar, se completaron un estudio teórico y mediciones reales. La comparación entre el estudio
teórico y práctico no estaba concluyente por lo que las predicciones teóricas se han modificado para
corresponder a la realidad.
Finalmente, la RTBF está construyendo un nuevo edificio en 2022 para el cual un estudio predictivo
teórico se ha hecho para proporcionar una cantidad de puntos de accesos necesarios para una cobertura
completa.This End-of-Grade work have been done inside the Francophone Belgian Radio-Television (RTBF) in
Brussels. The goal of this Project is to design a fully reliable and performant Wi-Fi network for one of
their localization.
To begin with, a theorical study and real-life measurements were completed. The comparasion between
the theorical and practical study was not concluding so the theorical predictions have been changed to
correspond to reality.
Finally, the RTBF is constructing a new building in 2022 for which a theorical predictive study have
been done to provide the number of needed access points for a complete coverage.Grado en Ingeniería en Tecnologías de Telecomunicació
Ubiquitous Indoor Fine-Grained Positioning and Tracking: A Channel Response Perspective
The future of location-aided applications is shaped by the ubiquity of
Internet-of-Things devices. As an increasing amount of commercial off-the-shelf
radio devices support channel response collection, it is possible to achieve
fine-grained position estimation at a relatively low cost. In this paper, we
focus on the channel response-based positioning and tracking for various
applications. We first give an overview of the state of the art (SOTA) of
channel response-enabled localization, which is further classified into two
categories, i.e., device-based and contact-free schemes. A taxonomy for these
complementary approaches is provided concerning the involved techniques. Then,
we present a micro-benchmark of channel response-based direct positioning and
tracking for both device-based and contact-free schemes. Finally, some
practical issues for real-world applications and future research opportunities
are pointed out.Comment: 13th International Conference on Indoor Positioning and Indoor
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