111 research outputs found
Indoor wireless communications and applications
Chapter 3 addresses challenges in radio link and system design in indoor scenarios. Given the fact that most human activities take place in indoor environments, the need for supporting ubiquitous indoor data connectivity and location/tracking service becomes even more important than in the previous decades. Specific technical challenges addressed in this section are(i), modelling complex indoor radio channels for effective antenna deployment, (ii), potential of millimeter-wave (mm-wave) radios for supporting higher data rates, and (iii), feasible indoor localisation and tracking techniques, which are summarised in three dedicated sections of this chapter
Towards joint communication and sensing (Chapter 4)
Localization of user equipment (UE) in mobile communication networks has been supported from the early stages of 3rd generation partnership project (3GPP). With 5th Generation (5G) and its target use cases, localization is increasingly gaining importance. Integrated sensing and localization in 6th Generation (6G) networks promise the introduction of more efficient networks and compelling applications to be developed
Employing Ray-tracing and Least-Squares Support Vector Machines for Localisation
This article evaluates the use of least-squares support vector machines, with ray-traced data, to solve the problem of localisation in multipath environments. The schemes discussed concern 2-D localisation, but could easily be extended to 3-D. It does not require NLOS identification and mitigation, hence, it can be applied in any environment. Some background details and a detailed experimental setup is provided. Comparisons with schemes that require NLOS identification and mitigation, from earlier work, are also presented. The results demonstrate that the direct localisation scheme using least-squares support vector machine (the Direct method) achieves superior outage to TDOA and TOA/AOA for NLOS environments. TDOA has better outage in LOS environments. TOA/AOA performs better for an accepted outage probability of 20 percent or greater but as the outage probability lowers, the Direct method becomes better
Towards localisation with Doppler radar
In this thesis the author introduces a novel method for Geo Localisation via Doppler Radar. The area of research is in the three dimensional space using amplitude and magnitude measurements. Geo Localisation in mobile applications is a useful technology that enables monitoring and gathering information about objects of interest
RF signal sensing and source localisation systems using Software Defined Radios
Radio frequency (RF) source localisation is a critical technology
in numerous location-based military and civilian applications. In
this thesis, the problem of RF source localisation has been
studied from the perspective of the system implementation for
real-world applications. Commercial off-the-shelf Software
Defined Radio (SDR) devices are used to demonstrate the practical
RF source localisation systems. Compared to the conventional
localisation systems, which rely on dedicated hardware, the
SDR-based system is developed using general-purpose hardware and
software-defined components, offering great flexibility and cost
efficiency in system design and implementation.
In this thesis, the theoretical results of source localisation
are evaluated and put into practice. To be specific, the
practical localisation systems using different measurement
techniques, including received-signal-strength-indication (RSSI)
measurements, time-difference-of-arrival (TDOA) measurements and
joint TDOA and frequency-difference-of-arrival (FDOA)
measurements, are demonstrated to localise the stationary RF
signal sources using the SDRs. The RSSI-based localisation system
is demonstrated in small indoor and outdoor areas with a range of
several metres using the SDR-based transceivers. Furthermore,
interests from the defence area motivated us to implement the
time-based localisation systems. The TDOA-based source
localisation system is implemented using multiple spatially
distributed SDRs in a large outdoor area with the sensor-target
range of several kilometres. Moreover, they are implemented in a
fully passive way without prior knowledge of the signal emitter,
so the solutions can be applied in the localisation of
non-cooperative signal sources provided that emitters are
distant. To further reduce the system cost, and more importantly,
to deal with the situation when the deployment of multiple SDRs,
due to geographical restrictions, is not feasible, a joint TDOA
and FDOA-based localisation system is also demonstrated using
only one stationary SDR and one mobile SDR.
To improve the localisation accuracy, the methods that can reduce
measurement error and obtain accurate location estimates are
studied. Firstly, to obtain a better understanding of the
measurement error, the error sources that affect the measurement
accuracy are systematically analysed from three aspects: the
hardware precision, the accuracy of signal processing methods,
and the environmental impact. Furthermore, the approaches to
reduce the measurement error are proposed and verified in the
experiments. Secondly, during the process of the location
estimation, the theoretical results on the pre-existing
localisation algorithms which can achieve a good trade-off
between the accuracy of location estimation and the computational
cost are evaluated, including the weight least-squares
(WLS)-based solution and the Extended Kalman Filter (EKF)-based
solution. In order to use the pre-existing algorithms in the
practical source localisation, the proper adjustments are
implemented.
Overall, the SDR-based platforms are able to achieve low-cost and
universal localisation solutions in the real-world environment.
The RSSI-based localisation system shows tens of centimetres of
accuracy in a range of several metres, which provides a useful
tool for the verification of the range-based localisation
algorithms. The localisation accuracy of the TDOA-based
localisation system and the joint TDOA and FDOA-based
localisation system is several tens of metres in a range of
several kilometres, which offers potential in the low-cost
localisation solutions in the defence area
Space-Time diversity for NLOS mitigation in TDOA-based positioning systems
This paper studies the potential impact of using space-Time information in the mitigation of the Non-LineOf-Sight condition in mobile subscriber's positioning systems. First of all, this work discusses the positioning problem based on measures of Time Differences Of Arrival departing from a more exact characterization of the signal statistics and including some geometrical restrictions to achieve an improved accurate. Furthermore, a novel approach that integrates signal propagation characteristics to information provided by a suitable timing estimation model based on Cramer Rao Bound for a Rayleigh-fading channel, when antenna arrays are used at the receiver and when a set ofchannel vector estimates are available, has been introduced to study the positive benefits of space-Time diversity. These approaches are evaluated within a realistic simulation scenario.Peer ReviewedPostprint (published version
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