Theory and Development of a Dynamic HITL Autotrack Evaluation System

King, Nathan, Davis, Steve

10 1900

ITC/USA 2013 Conference Proceedings / The Forty-Ninth Annual International Telemetering Conference and Technical Exhibition / October 21-24, 2013 / Bally's Hotel & Convention Center, Las Vegas, NV / Telemetry ground antenna tracking performance evaluation and measurement was previously performed by evaluating only the antenna drive system. The integrated nature of software controlled antenna systems has prompted a need to evaluate the entire tracking antenna system, as a whole. Particularly, the ability of an antenna to remain "locked" on a dynamic target must be able to be evaluated and quantified. This paper presents one method for evaluating the tracking ability of a telemetry antenna system and discusses a likely set of metrics to be used as figures of merit for antenna system tracking performance.

Telemetry

Autotrack

Simulator

Antenna

Tracking

Modeling and design of compact microwave components and systems for wireless communications and power transmission

Zepeda, Paola

30 September 2004

The contribution of the work here presented involves three main topics: Wireless Power Transmission (WPT) technology, phased array systems, and microwave components design and modeling. The first topic presents the conceptual design of a WPT system at 2.45GHz with 90% efficiency and 1MW of DC output power. Second, a comparative study between 2.45 and 35GHz WPT operation is provided. Finally, the optimization of a taper distribution with reduced thermal constraints on a sandwich transmitter is realized. For a 250- and 375-m antenna radius, 89.7% of collection efficiency with 29% reduction in maximum power density (compared to the Gaussian), and 93% collection efficiency with 39% reduction of maximum power density, are obtained respectively with two split tapers. The reduction in maximum power density and the use of split taper are important to alleviate the thermal problems in high power transmission. For the phased array project, the conceptual design of a small-scale system and in-depth analysis using two main approaches (statistical and field analysis) is realized. Practical aspects are addressed to determine the phased array main design features. The statistical method provides less accurate results than the field analysis since it is intended for large arrays. Careful theoretical analysis led to good correlation between statistical, field analysis and experimental results. In the components chapter, efficient loop transitions used in a patch antenna array are designed at K- and W-band. Measured insertion loss (IL) K-band loop is under 0.4dB. The K- and W-band antenna array measured broadside gains are 23.6dB at 24.125GHz and 25dB at 76.5GHz with return loss under 9.54dB from 24 to 24.4GHz and 12 dB from 75.1 to 77.3GHz, respectively. Also, a multilayer folded line filter is designed at 5.8GHz and compared to planar ring filters. Improved measured bandwidth from 2GHz to 7.5GHz and IL of 1.2dB are obtained with approximately half the size of a planar ring resonator. Thirdly, a simplified switch model is implemented for use in broadband phased-shifters. The model presents very good fit to the measured results with an overall total error under 3%, magnitude error less than 8%, and phase errors less than ±0.4°.

Microwave

wireless

power

antenna

array

Impact of Mutual Coupling among Antenna Arrays on the Performance of the Multipath Simulator System

Ramamoorthy, Dhayalini

January 2014

This thesis work presents a study on the impact of mutual coupling among antenna arrays on the performance of the multipath simulator (MPS) system. In MIMO systems, it is a wellknown fact that the mutual coupling significantly affects their system performance. The impact of mutual coupling on MIMO system performance is an important consideration for compact antenna arrays. Hence, it is very important to investigate the impact of mutual coupling on the accuracy of measurements in a MPS system. In this project, the impact of coupling within the MPS array antennas is addressed by performing simulations based on the proposed MPS scattering model which fulfills the far-field (Fraunhoferdistance) boundary conditions. The coupling phenomenon within the MPS array antennas is studied by designing a uniform circular array (UCA) of radius,R consisting of NMPS antennas with single device under test (DUT) antenna at the center. The elements of the array are matched half-wave dipole antennas and the phase of the array elements is kept constant throughout. In this work it is assumed that all the elements in the array are identical and located in the far-field region. This study is carried out by performing MPS simulations in HFSS at the LTE-A band of 2.6GHz. The approach used to model the entire system is by comparing the S-parameters (S21: Forward transmission coefficient parameter) between various array configuration. The simulation results suggest that the impact of mutual coupling increases with the number of MPS antennas and decreases with the radius of the MPS ring. Theradiated power is also measured with and without mutual coupling. Finally, it is concluded that the impact of coupling within the MPS antennas is best countered by designing a large MPS system (preferably R = 10λ or greater), despite the higher incurred costs.

MIMO

MPS system

Antenna array

Array design and beamforming for satellite earth terminals

Anderson, Paul David

12 1900

No description available.

Antenna arrays

Mobile communication systems

Design and Study of a New Ultra-wideband Pattern Diversity Antenna, for High-Gain Application

Rezazadeh, Navid

02 September 2014

A new Ultra-Wideband (UWB) pattern diversity antenna is proposed, designed and investigated in this thesis. The antenna is capable of radiating in directive and omni-directional modes. Three different versions of the design are studied to show the performance for different applications. The first design consists of a single radiating element fed from two sides by coaxial probes over a shaped ground plane. In-phase excitation of the ports produces omni-directional radiation patterns and out-of-phase excitation results in directive radiation in the boresight of the antenna. The shape of the radiator is a disk, which is modified in geometry to improve the isolation of the ports. The antenna shows impedance bandwidth from 6.8 GHz to more than 15 GHz. The second design is a dual-element version of the same antenna to equalize the radiation patterns in the E- and H-planes. The antenna requires four ports and has an impedance bandwidth from 7.4 GHz to more than 15 GHz. A microstrip power divider is then included, in the third design, which in addition to decreasing the number of extra circuits for feeding, decreases the lower frequency to 4.5 GHz, without changing the radiation patterns significantly throughout the bandwidth. A prototype of this antenna was fabricated and measured, and the results are presented. In the fifth chapter, an electromagnetic polarization filter is designed for the single element UWB antenna, to reduce the cross-polarization level. 7 dB reduction in the maximum level of cross-polarization is achieved, throughout the frequency band 8 - 11 GHz. The following chapter is dedicated to the study and performance of the microstrip-fed UWB antenna, when used as a feed for prime-focus reflectors. It is shown that the designed antenna is capable of feeding the reflector with efficiency as high as 75%, and more than 60%, over a wide bandwidth of 5.5 - 9 GHz.

Ultra-wideband

Antenna

Pattern Diversity

A Coplanar Waveguide UWB Antenna With Notch Filter

Wang, Qianqian

04 July 2013

Due to the release of 3.1-10.6 GHz band, UWB systems have a rapidly progressive development. They have been widely employed in short-range communication applications and large-bandwidth handheld devices. As part of the system, the UWB antenna plays an extremely important role. Due to the trend towards integrated printed circuits, co-planar waveguide technology is a feasible solution for designing the UWB antenna. This thesis focuses on designing a UWB co-planar waveguide antenna with a band-stop filter. This band-stop filter offers rejection to unwanted frequencies in the range of the operating band in order to avoid unnecessary interference from other communication applications and improve its own system’s performance. In addition, it can divide the whole wide band into a few sub-bands. This will create more flexibility for practical applications. The professional full-wave field solver software package CST Microwave Studio is used as the analysis tool to obtain the performances of this antenna. It operates from 3.1 GHz to 10.6 GHz with a VSWR < 2 in the pass bands, and a VSWR > 2 in the stop bands. The selected frequencies demonstrate nearly omni-directional characteristics in radiation patterns. Comparing with other published UWB antenna designs, relatively reasonable group delay results are achieved. Measurements on a fabricated prototype validate the design approach. / Graduate / 0537 / wang@uvic.ca

CPW

SIW

Notch Filter

Antenna

Self-optimization of Antenna Sectorization

Faxér, Sebastian

January 2014

Sectorization is a well-established method of increasing the capacity of telecommunicationnetworks. With modern Active Antenna Systems (AAS) comes the abilityto change sectorization order dynamically, both in horizontal and vertical plane.The purpose of this thesis is to investigate when (and what type of) sectorizationis benficial. A theoretical analysis as well as simulations are performed in orderto determine which quantities to look at when making the decision to apply sectorization.Based on the conclusions from these investigations, a self-optimizingalgorithm that only turns on sectorization when it increases network performanceis developed and evaluated. It is shown that large gains can be achieved by onlyturning on sectorization when the right conditions are met. Further, we show thatadditional gains can be seen if antenna parameters such as downtilt and distributionof transmission power between sectors are set properly. Self-optimizingalgorithms for tuning of these parameters are developed and evaluated as well.NyckelordKeywords

Investigation and Implementation of Coexistence Tool for Antennas

Carlsson, Robin

January 2014

With the increase of the number of radios and antennas on today’s systems, the risk of co-site interference is very high. Intermodulation product and antenna coupling are two common sources of interference. The thesis investigates some features of a radio system, like antenna types, receiver parameters, intermodulation products and isolation, and suggests how this knowledge can be used to minimize the risk of co-site interference. The goal is to maximize the isolation between the antennas, by good frequency planning, the use of filters and taking great care in antenna placement. A first version of an analysis software was developed where transmitters and receivers can be paired and evaluated. An intermodulation product calculator was also implemented, to easily find which products are an issue and where they originate. The goal of the software is to be simple to use and easy to adapt to different setups and situations. It should also be easy to upgrade with new features.

radio

antenna

co-site interference

Application of the moment method to the design of slotted waveguide array antennas

McCormick, A. H. I.

January 1988

No description available.

621.31042

Antenna theory/CAD use

Determination of the far field radiation patterns of UHF broadcast antennas from nearfield measurements /

Hancock, Darryl Thomas.

Unknown Date

Thesis (M Eng) -- University of South Australia, 1992

Antenna arrays.

Antennas (Electronics)

Television