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Radio local area networks : protocol design and performance analysisMuriithi, Ndiritu January 1996 (has links)
No description available.
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Wideband measurements and characterisation of the UFH mobile radio channelMolkdar, D. January 1987 (has links)
No description available.
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Traffic performance of cellular mobile radio systemsVargas, J. H. S. January 1988 (has links)
No description available.
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A speech coder design for land mobile radio communicationsWong, Wing-Tak Kenneth January 1989 (has links)
No description available.
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Digital data transmission over mobile radio channelsMuhson, Said A. January 1987 (has links)
The aim of this work is to study data transmission over a microwave digital mobile radio channel at 900 MHz, where the channel is subjected to multipath fading. Besides the fading, the other impairments assumed here are additive noise, co-channel interference and adjacent channel interference. Two modulation techniques are investigated in this work, namely Quadrature-Amplitude-Modulation (QAM) and Quadrature-Phase-Shift- Keying (QPSK). The channel is characterised digitally, assuming multipath Rayleigh fading in the presence of noise. The detection process studied here are near-maximum likelihood schemes: non-linear equalisation methods are also considered in detail. The thesis is also concerned with carrier synchronisation and channel estimation under conditions of Rayleigh fading. Since the carrier syncn,honisation is a most important requirement in mobile radio, a Digital Phase Locked Loop (DPLL) technique has been designed and investigated in the form of a feedback digital synchronisation system. Two types of channel estimation technique, namely feedforward and feedback estimators, are also investigated in this work. The feedback estimator is modified by the addition of a digital control system, in order to reduce its delay, and to cope with rapidly fading signals. Successful carrier synchronisation is demonstrated by the use of space diversity. The study was completed using models of the component parts of the system, and by the use of extensive computer simulations to analyse the system under various operating conditions.
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Generalized Three Dimensional Geometrical Scattering Channel Model for Indoor and Outdoor Propagation EnvironmentsAlsehaili, Mohammad 19 January 2011 (has links)
The well known geometrical scattering channel modeling technique has been suggested to describe the spatial statistical
distribution of the received multipath signals at various types of wireless communication environments and for different wireless system
applications. This technique is based on the assumption that the scatterers, i.e. objects that give rise to the multipath signals, are
randomly distributed within a specified geometry that may include the base station and/or the mobile station. The geometrical scattering
channel models can provide convenient and simple statistical functions for some of the important physical quantities of the received
multipath fading signals, such as: angle of arrival, time of arrival, angular spread, delay spread and the spatial correlation function.
In this thesis, a new three dimensional geometrical scattering channel model has been developed for outdoor and indoor wireless
communication environments. The probability density functions of the angle of arrival of the received multipath signals are provided in
compact forms. These functions facilitate independent control of the angular spread in both the azimuth and the elevation angles via the
model's parameters. To establish the model verification, the developed model has been compared against the results from a site-specific
propagation prediction technique in indoor and outdoor wireless communication environments.
The developed three dimensional model has been extended to include the temporal statistical distribution of the received multipath signals
for uniform and non-uniform distributions of the scatterer. Several of the probability density functions of the angle of arrival and time of
arrival of the received multipath signals are provided. The probability density functions of the angle of arrival have been validated by
comparing them against the results from real channel measurements data. In addition, the developed three dimensional geometrical scattering
channel model has been extended for multiple input multiple output wireless channel modeling applications. A three dimensional spatial
correlation function has been developed in terms of some of the physical channel's parameters, such as: displacements and orientation of
the employed antenna elements. The developed correlation function has been used to simulate and investigate the performance
of wireless multiple input multiple output systems in different scenarios.
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Generalized Three Dimensional Geometrical Scattering Channel Model for Indoor and Outdoor Propagation EnvironmentsAlsehaili, Mohammad 19 January 2011 (has links)
The well known geometrical scattering channel modeling technique has been suggested to describe the spatial statistical
distribution of the received multipath signals at various types of wireless communication environments and for different wireless system
applications. This technique is based on the assumption that the scatterers, i.e. objects that give rise to the multipath signals, are
randomly distributed within a specified geometry that may include the base station and/or the mobile station. The geometrical scattering
channel models can provide convenient and simple statistical functions for some of the important physical quantities of the received
multipath fading signals, such as: angle of arrival, time of arrival, angular spread, delay spread and the spatial correlation function.
In this thesis, a new three dimensional geometrical scattering channel model has been developed for outdoor and indoor wireless
communication environments. The probability density functions of the angle of arrival of the received multipath signals are provided in
compact forms. These functions facilitate independent control of the angular spread in both the azimuth and the elevation angles via the
model's parameters. To establish the model verification, the developed model has been compared against the results from a site-specific
propagation prediction technique in indoor and outdoor wireless communication environments.
The developed three dimensional model has been extended to include the temporal statistical distribution of the received multipath signals
for uniform and non-uniform distributions of the scatterer. Several of the probability density functions of the angle of arrival and time of
arrival of the received multipath signals are provided. The probability density functions of the angle of arrival have been validated by
comparing them against the results from real channel measurements data. In addition, the developed three dimensional geometrical scattering
channel model has been extended for multiple input multiple output wireless channel modeling applications. A three dimensional spatial
correlation function has been developed in terms of some of the physical channel's parameters, such as: displacements and orientation of
the employed antenna elements. The developed correlation function has been used to simulate and investigate the performance
of wireless multiple input multiple output systems in different scenarios.
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SIMULATION OF THE AERONAUTICAL RADIO CHANNEL FOR TELEMETRY APPLICATIONSMwangi, Patricia A. W., Haj-Omar, Amr, Montaque, Kishan 10 1900 (has links)
ITC/USA 2006 Conference Proceedings / The Forty-Second Annual International Telemetering Conference and Technical Exhibition / October 23-26, 2006 / Town and Country Resort & Convention Center, San Diego, California / The aeronautical channel is an air to ground channel characterized by multipath, high doppler shifts, Rayleigh fading and noise. Use of a channel sounder ensures proper estimation of the parameters associated with the impulse response of the channel. These estimates help us to characterize the radio channels associated with aeronautical telemetry. In order to have a satisfactory channel characterization, the amplitudes, phase shifts and delays associated with each multipath component in the channel model must be determined.
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Hardwarový simulátor únikového kanálu / Fading channel hardware simulatorPirochta, Pavel January 2010 (has links)
Fading channel is a communication channel that experiences different interference and fading due to multi-path signal propagation. The fading channel is designed by the finite impulse response filter with the time-varying impulse characteristic. The realisation of this filtr is based on the TDL (Tapped Delay Line) model, which simulate signal delay and signal attenuation in each branch. The aim of this thesis is to create the VHDL design of selected fading channel simulator and its description for hardware implementation into the FPGA.
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Application of Channel Modeling for Indoor Localization Using TOA and RSSHatami, Ahmad 31 May 2006 (has links)
"Recently considerable attention has been paid to indoor geolocation using wireless local area networks (WLAN) and wireless personal area networks (WPAN) devices. As more applications using these technologies are emerging in the market, the need for accurate and reliable localization increases. In response to this need, a number of technologies and associated algorithms have been introduced in the literature. These algorithms resolve the location either by using estimated distances between a mobile station (MS) and at least three reference points (via triangulation) or pattern recognition through radio frequency (RF) fingerprinting. Since RF fingerprinting, which requires on site measurements is a time consuming process, it is ideal to replace this procedure with the results obtained from radio channel modeling techniques. Localization algorithms either use the received signal strength (RSS) or time of arrival (TOA) of the received signal as their localization metric. TOA based systems are sensitive to the available bandwidth, and also to the occurrence of undetected direct path (UDP) channel conditions, while RSS based systems are less sensitive to the bandwidth and more resilient to UDP conditions. Therefore, the comparative performance evaluation of different positioning systems is a multifaceted and challenging problem. This dissertation demonstrates the viability of radio channel modeling techniques to eliminate the costly fingerprinting process in pattern recognition algorithms by introducing novel ray tracing (RT) assisted RSS and TOA based algorithms. Two sets of empirical data obtained by radio channel measurements are used to create a baseline for comparative performance evaluation of localization algorithms. The first database is obtained by WiFi RSS measurements in the first floor of the Atwater Kent laboratory; an academic building on the campus of WPI; and the other by ultra wideband (UWB) channel measurements in the third floor of the same building. Using the results of measurement campaign, we specifically analyze the comparative behavior of TOA- and RSS-based indoor localization algorithms employing triangulation or pattern recognition with different bandwidths adopted in WLAN and WPAN systems. Finally, we introduce a new RT assisted hybrid RSS-TOA based algorithm which employs neural networks. The resulting algorithm demonstrates a superior performance compared to the conventional RSS and TOA based algorithms in wideband systems."
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