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CDD-DLL for PN Code Tracking in DS-CDMA Communication SystemsYu, Hao-Chih 21 June 2001 (has links)
PN code tracking plays a very important role in CDMA communication systems.
In literature, the influences of multipath fading and of multiuser interference
on PN code tracking are studied separately. The multipath fading influence is
mitigated by combining a rake receiver and a channel estimator in
the Delay-Locked Loop (DLL). The multiuser interference is overcome by
incorporating a data estimator into the DLL. In the downlink, PN code tracking
may suffer from the multipath fading influence. However, the multipath fading
and the multiuser interference influences exist in the uplink. Unfortunately,
sole use of the aforementioned methods cannot solve out both influences simultaneously.
In this thesis, two new Coherent Decision-Directed Delay-Locked Loop (CDD-DLL)
PN-Code tracking schemes are developed and either can overcome both influences.
First, a channel and a data estimators are incorporated into the DLL inherent
with a rake receiver. This new scheme works properly in an environment with
multipath fading and multiuser interference. Second, the original CDD-DLL is
combined with a multipath interference canceller (MPI) to reduce both influences.
Analytical results are derived for the two schemes proposed and are validated
with numerical simulations. Simulation results show that the conventional DLLs
working in a multipath fading and multiuser interference environment can be
significantly improved using the new schemes. Moreover, the latter outperforms
the former because the multipath interference is cancelled completely.
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An architecture for network path selectionMotiwala, Murtaza 19 January 2012 (has links)
Traditional routing protocols select paths based on static link weights and converge to new paths only when there is an outright reachability failure (such as a link or router failure). This design allows routing scale to hundreds of thousands of nodes, but it comes at the cost of functionality: routing provides only simple, single path connectivity. Networked applications in the wide-area, enterprise, and data center can all benefit from network protocols that allow traffic to be sent over multiple routes en route to a destination. This ability, also called multipath routing, has other significant benefits over single-path routing, such as more efficiently using network resources and recovering more quickly from network disruptions.
This dissertation explores the design of an architecture for path selection in the network and proposes a "narrow waist" interface for networks to expose choice in routing traffic to end systems. Because most networks are also business entities, and are sensitive to the cost of routing traffic in their network, this dissertation also develops a framework for exposing paths based on their cost. For this purpose, this dissertation develops a cost model for routing traffic in a network. In particular, this dissertation presents the following contributions:
* Design of path bits, a "narrow waist" for multipath routing. Our work ties a large number of multipath routing proposals by creating an interface (path bits) for decoupling the multipath routing protocols implemented by the network and end systems
(or other network elements) making a choice for path selection. Path bits permit simple, scalable, and efficient implementations of multipath routing protocols in the network that still provide enough expressiveness for end systems to select alternate paths. We demonstrate that our interface is flexible and leads to efficient network implementations by building prototype implementations on different hardware and
software platforms.
* Design of path splicing, a multipath routing scheme. We develop, path splicing, a multipath routing technique, which uses random perturbations from the shortest path to create exponentially large number of paths with only a linear increase in state in a network. We also develop a simple interface to enable end systems to make path selection decisions. We present various deployment paths for implementing path splicing in both intradomain and interdomain routing on the Internet.
* Design of low cost path-selection framework for a network. Network operators and end systems can have conflicting goals, where the network operators are concerned with saving cost and reducing traffic uncertainty; and end systems favor better performing paths. Exposing choice of routing in the network can thus, create a tension between the network operators and the end systems. We propose a path-selection framework where end systems make path selection decisions based on path performance and networks expose paths to end systems based on their cost to the network. This thesis presents a cost model for routing traffic in a network to enable network operators to reason about "what-if " scenarios and routing traffic on their network.
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Mehrwegeausbreitung bei GNSS-gestützter PositionsbestimmungWildt, Steffen 19 July 2007 (has links) (PDF)
GNSS-Messungen werden neben systembedingten Fehlereinflüssen vor allem von den Auswirkungen der Mehrwegeausbreitung und Signalbeugung insbesondere in der Empfangsumgebung dominiert. Verschiedene Dienste z.B. der Landesvermessungsämter haben deshalb ein primäres Interesse daran, die Auswirkungen der Effekte möglichst gering zu halten oder aber genau bestimmen zu können, um Korrekturwerte zu generieren. Mehrwege- und Beugungseffekte lassen sich besonders innerhalb von Netzstrukturen gut bestimmen. Liegen Sollkoordinaten aller Beobachtungsstationen vor gelingt dies auch in Echtzeit. In der vorliegenden Arbeit werden neben einer detaillierten Beschreibung der jeweiligen Einflussgrößen auch Möglichkeiten aufgezeigt, die genannten Effekte zu erkennen und Maßnahmen zur Reduktion der Auswirkungen auf das Meßergebnis zu ergreifen. Kern der Untersuchungen ist ein zweistufiges Modell zur Reduzierung von Mehrwegeeffekten in Echtzeit innerhalb von (Referenz-) Stationsnetzen durch Bestimmung von Korrekturwerten für originale und abgeleitete Meßwerte pro Epoche, Station und Satellit.
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New Signal Processing Techniques for MIMO Physical LayerSenaratne, Damith N. Unknown Date
No description available.
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Spatiotemporal characterization of indoor wireless channelsGurrieri, Luis 29 October 2010 (has links)
The continuous advancement in wireless communications technology demands new approaches to improving the capacity of existing radio links. The high data throughput required can be achieved by the complete utilization of space, time and polarization diversities inherent in any propagation environment. Among the different propagation scenarios, the indoor channels represent a particularly challenging problem given the number and complexity of interactions between the transmitted signal and the environment. This dissertation explores the interrelation between propagation physics and space-time-polarization diversity based on a novel high resolution channel sounding and reconstruction technique. First, a method to reconstruct the indoor complex channel response based on a limited set of samples and the elimination of the interference using deconvolution techniques is presented. Then, the results for the joint angle-of-arrival, delay characterization and depolarization of electromagnetic waves are presented. Finally, a novel approach to using depolarized multipath signals to boost the receiver signal-to-noise performance is presented. The current study shows that full utilization of the diversities of channel novel wireless systems can be proposed with significant improvement in capacity.
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A feasibility study of broadband low–noise amplifiers with multiple amplification paths for radio astronomy / P.P. KrügerKrüger, Petrus Paulus January 2010 (has links)
Multipath amplifier theory:
In this thesis it is proven that the theoretical minimum noise measure of a multipath amplifier (an
amplifier which has multiple parallel amplifiers) is achieved by using the optimum source impedance for
the amplifier and the optimum gain for each amplification path. This optimum source impedance and
gain can be calculated by using the optimum–loaded input network, i.e. by replacing each amplifier with
its optimum source impedance. The resulting noise measure is the same as the minimum noise measure of
the amplifiers used in the amplification paths. Whereas single–path amplifiers can achieve this minimum
noise measure over narrow bandwidths, multipath amplifiers are theoretically able to achieve the minimum
noise measure over very broad bandwidths.
The theory is demonstrated by applying it to distributed amplifiers. In an ideal distributed amplifier,
the magnitude of the optimum gain of the amplification paths decreases and the phase delay increases
the farther the stage is from the input, with the decrease in gain being faster for higher frequencies. The
challenge in designing broadband, low–noise, distributed amplifiers is to achieve optimum gain matching
over broad bandwidths.
Multipath amplifier design procedure:
Based on the theory, a three step design and optimisation procedure is introduced. Firstly, unconditionally
stable amplification paths are designed to have small minimum noise measures, then an input network
is designed for optimum source impedance matching and lastly an output network is designed for gain
matching.
Multipath amplifier prototype:
The theory and design procedure is demonstrated by optimising a 0.5–2 GHz distributed amplifier. An
average noise measure of 0.3 dB is achieved, which is only 0.1 dB higher than the minimum noise measure
of the amplification stages used. This increase is mainly due to transmission line loss and gain mismatch.
Radio telescope feasibility:
Multipath amplifiers break the trade–off between noise temperature, bandwidth and source termination
that a single–path amplifier has, because they have much more design freedom when designing the input
network. In general, the more paths, the larger the low–noise bandwidth, but the larger and more complex
the amplifier. Roughly two to three amplification paths are required per octave of bandwidth for LNAs
around 1 GHz. When the bandwidth is very narrow, a single path is sufficient.
Multipath amplifiers have similar trade–offs between linearity and power consumption, between noise
temperature and noise resistance, and between noise temperature and size to a single–path amplifier.
Multipath amplifiers are therefore a feasible alternative for use in radio telescopes. / Thesis (Ph.D. (Space Physics))--North-West University, Potchefstroom Campus, 2011.
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Spatiotemporal characterization of indoor wireless channelsGurrieri, Luis 29 October 2010 (has links)
The continuous advancement in wireless communications technology demands new approaches to improving the capacity of existing radio links. The high data throughput required can be achieved by the complete utilization of space, time and polarization diversities inherent in any propagation environment. Among the different propagation scenarios, the indoor channels represent a particularly challenging problem given the number and complexity of interactions between the transmitted signal and the environment. This dissertation explores the interrelation between propagation physics and space-time-polarization diversity based on a novel high resolution channel sounding and reconstruction technique. First, a method to reconstruct the indoor complex channel response based on a limited set of samples and the elimination of the interference using deconvolution techniques is presented. Then, the results for the joint angle-of-arrival, delay characterization and depolarization of electromagnetic waves are presented. Finally, a novel approach to using depolarized multipath signals to boost the receiver signal-to-noise performance is presented. The current study shows that full utilization of the diversities of channel novel wireless systems can be proposed with significant improvement in capacity.
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A feasibility study of broadband low–noise amplifiers with multiple amplification paths for radio astronomy / P.P. KrügerKrüger, Petrus Paulus January 2010 (has links)
Multipath amplifier theory:
In this thesis it is proven that the theoretical minimum noise measure of a multipath amplifier (an
amplifier which has multiple parallel amplifiers) is achieved by using the optimum source impedance for
the amplifier and the optimum gain for each amplification path. This optimum source impedance and
gain can be calculated by using the optimum–loaded input network, i.e. by replacing each amplifier with
its optimum source impedance. The resulting noise measure is the same as the minimum noise measure of
the amplifiers used in the amplification paths. Whereas single–path amplifiers can achieve this minimum
noise measure over narrow bandwidths, multipath amplifiers are theoretically able to achieve the minimum
noise measure over very broad bandwidths.
The theory is demonstrated by applying it to distributed amplifiers. In an ideal distributed amplifier,
the magnitude of the optimum gain of the amplification paths decreases and the phase delay increases
the farther the stage is from the input, with the decrease in gain being faster for higher frequencies. The
challenge in designing broadband, low–noise, distributed amplifiers is to achieve optimum gain matching
over broad bandwidths.
Multipath amplifier design procedure:
Based on the theory, a three step design and optimisation procedure is introduced. Firstly, unconditionally
stable amplification paths are designed to have small minimum noise measures, then an input network
is designed for optimum source impedance matching and lastly an output network is designed for gain
matching.
Multipath amplifier prototype:
The theory and design procedure is demonstrated by optimising a 0.5–2 GHz distributed amplifier. An
average noise measure of 0.3 dB is achieved, which is only 0.1 dB higher than the minimum noise measure
of the amplification stages used. This increase is mainly due to transmission line loss and gain mismatch.
Radio telescope feasibility:
Multipath amplifiers break the trade–off between noise temperature, bandwidth and source termination
that a single–path amplifier has, because they have much more design freedom when designing the input
network. In general, the more paths, the larger the low–noise bandwidth, but the larger and more complex
the amplifier. Roughly two to three amplification paths are required per octave of bandwidth for LNAs
around 1 GHz. When the bandwidth is very narrow, a single path is sufficient.
Multipath amplifiers have similar trade–offs between linearity and power consumption, between noise
temperature and noise resistance, and between noise temperature and size to a single–path amplifier.
Multipath amplifiers are therefore a feasible alternative for use in radio telescopes. / Thesis (Ph.D. (Space Physics))--North-West University, Potchefstroom Campus, 2011.
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High-frequency modulated-backscatter communication using multiple antennasGriffin, Joshua David 02 March 2009 (has links)
Backscatter radio - the broad class of systems that communicate using scattered electromagnetic waves - is the driving technology behind many compelling applications such as radio frequency identification (RFID) tags and passive sensors. These systems can be used in many ways including article tracking, position location, passive temperature sensors, passive data storage, and in many other systems which require information exchange between an interrogator and a small, low-cost transponder with little-to-no transponder power consumption. Although backscatter radio is maturing, such systems have limited communication range and reliability caused, in part, by multipath fading. The research presented in this dissertation investigates how multipath fading can be reduced using multiple antennas at the interrogator transmitter, interrogator receiver, and on the transponder, or RF tag. First, two link budgets for backscatter radio are presented and fading effects demonstrated through a realistic, 915 MHz, RFID-portal example. Each term in the link budget is explained and used to illuminate the propagation and high-frequency effects that influence RF tag operation. Second, analytic envelope distributions for the M x L x N, dyadic backscatter channel - the general channel in which a backscatter system with M transmitter, L RF tag, and N receiver antennas operates - are derived. The distributions show that multipath fading can be reduced using multiple-antenna RF tags and by using separate transmitter and receiver antenna arrays at the interrogator. These results are verified by fading measurements of the M x L x N, dyadic backscatter channel at 5.8 GHz - the center of the 5725-5850 MHz unlicensed industrial, scientific, and medical (ISM) frequency band that offers reduced antenna size, increased antenna gain, and, in some cases, reduced object attachment losses compared to the commonly used 902-928 MHz ISM band. Measurements were taken with a custom backscatter testbed and details of its design are provided. In the end, this dissertation presents both theory and measurements that demonstrate multipath fading reductions for backscatter-radio systems that use multiple antennas.
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Modelling and Simulation of GPS Multipath PropagationHannah, Bruce M. January 2001 (has links)
Multipath remains a dominant error source in Global Positioning System (GPS) applications that require high accuracy. With the use of differential techniques it is possible to remove many of the common-mode error sources, but the error effects of multipath have proven much more difficult to mitigate. The research aim of this work is to enhance the understanding of multipath propagation and its effects in GPS terrestrial applications, through the modelling of signal propagation behaviour and the resultant error effects. Multipath propagation occurs when environmental features cause combinations of reflected and/or diffracted replica signals to arrive at the receiving antenna. These signals, in combination with the original line-of-sight (LOS) signal, can cause distortion of the receiver correlation function and ultimately the discrimination function and hence errors in range estimation. To date, a completely satisfactory mitigation strategy has yet to be developed. In the search for such a mitigation strategy, it is imperative that a comprehensive understanding of the multipath propagation environment and the resultant error effects exists. The work presented here, provides a comprehensive understanding through the use of new modelling and simulation techniques specific to GPS multipath. This dissertation unites the existing theory of radio frequency propagation for the GPS L1 signal into a coherent treatment of GPS propagation in the terrestrial environment. To further enhance the understanding of the multipath propagation environment and the resultant error effects, this dissertation also describes the design and development of a new parabolic equation (PE) based propagation model for analysis of GPS multipath propagation behaviour. The propagation model improves on previous PE-based models by incorporating terrain features, including boundary impedance properties, backscatter and time-domain decomposition of the field into a multipath impulse response. The results provide visualisation as well as the defining parameters necessary to fully describe the multipath propagation behaviour. These resultant parameters provide the input for a correlation and discrimination model for visualisation and the generation of resultant receiver error measurements. Results for a variety of propagation environments are presented and the technique is shown to provide a deterministic methodology against real GPS data. The unique and novel combined modelling of multipath propagation and reception, presented in this dissertation, provides an effective set of tools that have enhanced the understanding of the behaviour and effect of multipath in GPS applications, and ultimately should aid in providing a solution to the GPS multipath mitigation problem.
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