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A WIDEBAND CHANNEL MODEL FOR AERONAUTICAL TELEMETRY — PART 1: GEOMETRIC CONSIDERATIONS AND EXPERIMENTAL CONFIGURATIONRice, Michael, Davis, Adam, Bettwieser, Christian 10 1900 (has links)
International Telemetering Conference Proceedings / October 21, 2002 / Town & Country Hotel and Conference Center, San Diego, California / This paper is the first of two papers that present a multipath channel model for wideband
aeronautical telemetry. Channel sounding data, collected at Edwards AFB, California at both L-Band
and lower S-Band, were used to generate channel model. In Part 1, analytic and geometric
considerations are discussed and the frequency domain modeling technique is introduced. In Part
2, the experimental results are summarized and a channel model composed of three propagation
paths is proposed.
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A WIDEBAND CHANNEL MODEL FOR AERONAUTICAL TELEMETRY — PART 2: MODELING RESULTSRice, Michael, Davis, Adam, Bettwieser, Christian 10 1900 (has links)
International Telemetering Conference Proceedings / October 21, 2002 / Town & Country Hotel and Conference Center, San Diego, California / This paper is the second of two papers that present a multipath channel model for wideband
aeronautical telemetry. Channel sounding data were collected at Edwards AFB, California at both
L-Band and lower S-Band. Frequency domain analysis techniques were used to evaluate candidate
channel models. The channel model is composed of three propagation paths: a line-of-sight path,
and two specular reflections. The first specular reflection is characterized by a relative amplitude
of 70% to 96% of the line-of-sight amplitude and and a delay of 10 – 80 ns. This path is the result
of “ground bounces” off the dry lake bed at Edwards and is a typical terrain feature at DoD test
ranges located in the Western USA. The amplitude and delay of this path are defined completely
by the flight path geometry. The second path is a much lower amplitude path with a longer delay.
The gain of this path is well modeled as a zero-mean complex Gaussian random variable. The
relative amplitude is on the order of 2% to 8% of the line-of-sight amplitude. The mean excess
delay is 155 ns with an RMS delay spread of 74 ns.
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Interference cancellation in impulse radioWang, Xufang., 王徐芳. January 2005 (has links)
published_or_final_version / abstract / Electrical and Electronic Engineering / Doctoral / Doctor of Philosophy
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Combined OFDM-equalisationArmour, Simon Martin Daniel January 2001 (has links)
No description available.
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Optimising signalling rate and internal diversity order for mobile cellular DS-CDMA systemsAllpress, Stephen Alan January 1993 (has links)
No description available.
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Propagation of radio signals into and within multi-storey buildings at 900 MHz and 1800 MHzDavies, Jonathan Gary January 1997 (has links)
No description available.
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Direction-of-arrival algorithms for space-time W-CDMA receiver structuresMorrison, Andrew January 2001 (has links)
No description available.
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A frequency-translating hybrid architecture for wideband analog-to-digital convertersJalali Mazlouman, Shahrzad 05 1900 (has links)
Many emerging applications call for wideband analog-to-digital converters and some require medium-to-high resolution. Incorporating such ADCs allows for shifting as much of the signal processing tasks as possible to the digital domain, where more flexible and programmable circuits are available. However, realizing such ADCs with the existing single stage architectures is very challenging. Therefore, parallel ADC architectures such as time-interleaved structures are used. Unfortunately, such architectures require high-speed high-precision sample-and-hold (S/H) stages that are challenging to implement.
In this thesis, a parallel ADC architecture, namely, the frequency-translating hybrid ADC (FTH-ADC) is proposed to increase the conversion speed of the ADCs, which is also suitable for applications requiring medium-to-high resolution ADCs. This architecture addresses the sampling problem by sampling on narrowband baseband subchannels, i.e., sampling is accomplished after splitting the wideband input signals into narrower subbands and frequency-translating them into baseband where identical narrowband baseband S/Hs can be used. Therefore, lower-speed, lower-precision S/Hs are required and single-chip CMOS implementation of the entire ADC is possible.
A proof of concept board-level implementation of the FTH-ADC is used to analyze the effects of major analog non-idealities and errors. Error measurement and compensation methods are presented. Using four 8-bit, 100 MHz subband ADCs, four 25 MHz Butterworth filters, two 64-tap FIR reconstruction filters, and four 10-tap FIR compensation filters, a total system with an effective sample rate of 200 MHz is implemented with an effective number of bits of at least 7 bits over the entire 100 MHz input bandwidth.
In addition, one path of an 8-GHz, 4-bit, FTH-ADC system, including a highly-linear mixer and a 5th-order, 1 GHz, Butterworth Gm-C filter, is implemented in a 90 nm CMOS technology. Followed by a 4-bit, 4-GHz subband ADC, the blocks consume a total power of 52 mW from a 1.2 V supply, and occupy an area of 0.05 mm2. The mixer-filter has a THD ≤ 5% (26 dB) over its full 1 GHz bandwidth and provides a signal with a voltage swing of 350 mVpp for the subsequent ADC stage.
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Wideband Micro-Power Generators for Vibration Energy HarvestingSoliman, Mostafa 21 August 2009 (has links)
Energy harvesters collect and convert energy available in the environment into
useful electrical power to satisfy the power requirements of autonomous systems.
Vibration energy is a prevalent source of waste energy in industrial and built environments.
Vibration-based energy harvesters, or vibration-based micro power
generators (VBMPGs), utilize a transducer, a mechanical oscillator in this application,
to capture kinetic energy from environmental vibrations and to convert it into
electrical energy using electromagnetic, electrostatic, or piezoelectric transduction
mechanisms.
A key design feature of all VBMPGs, regardless of their transduction mechanism,
is that they are optimally tuned to harvest vibration energy within a narrow
frequency band in the neighborhood of the natural frequency of the oscillator. Outside
this band, the output power is too low to be conditioned and utilized. This
limitation is exacerbated by the fact that VBMPGs are also designed to have high
quality factors to minimize energy dissipation, further narrowing the optimal operating
frequency band. Vibrations in most environments, however, are random and
wideband. As a result, VBMPGs can harvest energy only for a relatively limited
period of time, which imposes excessive constraints on their usability.
A new architecture for wideband VBMPGs is the main contribution of this
thesis. The new design is general in the sense that it can be applied to any of the
three transduction mechanisms listed above. The linear oscillator is replaced with
a piecewise-linear oscillator as the energy-harvesting element of the VBMPG. The
new architecture has been found to increase the bandwidth of the VBMPG during
a frequency up-sweep, while maintaining the same bandwidth in a frequency downsweep.
Experimental results show that using the new architecture results in a 313%
increase in the width of the bandwidth compared to that produced by traditional
architecture. Simulations show that under random-frequency excitations, the new
architecture collects more energy than traditional architecture.
In addition, the knowledge acquired has been used to build a wideband electromagnetic
VBMPG using MicroElectroMechanical Systems, MEMS, technology.
This research indicates that a variety of piecewise-linear oscillators, including impact
oscillators, can be implemented on MPG structures that have been built using
MEMS technology. When the scale of the MPGs is reduced, lower losses are likely
during contact between the moving oscillators and the stopper, which will lead to
an increase in bandwidth and hence in the amount of energy collected.
Finally, a design procedure has been developed for optimizing such wideband
MPGs. This research showed that wideband MPGs require two design optimization
steps in addition to the traditional technique, which is used in all types of
generators, of minimizing mechanical energy losses through structural design and
material selection. The first step for both regular and wideband MPGs minimizes
the MPG damping ratio by increasing the mass and stiffness of the MPG by a common
factor until the effect of size causes the rate at which energy losses increase
to accelerate beyond that common factor. The second step, which is specific to
wideband MPGs, tailors the output power and bandwidth to fit the Probability
Density Function, PDF, of environmental vibrations. A figure of merit FoM was
devised to quantify the quality of this fit. Experimental results show that with this
procedure, the bandwidth at half-power level increases to more than 600% of the
original VBMPG bandwidth.
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Efficient Modelling and Performance Analysis of Wideband Communication ReceiversEriksson, Andreas January 2011 (has links)
This thesis deals with Symbol Error Rate (SER)-simulation of wireless communications and its application into throughput analysis of UltraWideband (UWB) systems. The SERs will be simulated in C++ using the Monte Carlo method and when some are calculated, the rest will be estimated using a novel extrapolation method. These SER values will be very accurate and in this thesis go as low as 1.0e-14. Reaching that low values would otherwise be impossible using the traditional Monte Carlo method, because of very large computation time. However, the novel extrapolation method, can simulate a SER-curve in less than 30 seconds. It is assumed that the noise belongs to the Generalized Gaussian distribution family and among them noise from the Normal distribution (Gaussian noise) gives the best result. It is to be noted that Gaussian noise is the most commonly used in digital communication simulations. Although the program is used for throughput analysis of UWB, the program could easily be adapted to various signals. In this thesis, throughput analysis means a plot with symbol rate vs distance. From any given symbols, the user can, with a desired minimum SER, generate an extrapolated SER-curve and see what symbol rate can be achieved by the system, while obeying power constraints of signals imposed by international laws. The developed program is, by comparing with published theoretical results, tested for QAM and PSK cases, but can easily be extended to UWB systems.
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