Global ETD Search

1	Diffraction by Building Corners at 28 Ghz: Measurements and Modeling Tenerelli, Peter A. Jr. 24 August 1998 (has links) This thesis presents the results of a 28 GHz continuous-wave (CW) diffraction measurement campaign in the Washington, DC area. It describes the measurement approach including information on equipment and testing methods. Also described are the various parameters that affected the diffraction loss. Observed diffraction losses showed little dependence on polarization and building material. For diffraction angles greater than 5 degrees, a simple linear equation was fit to the data and accurately describes the diffraction loss. A logarithmic equation describes the dependence at smaller angles. The model developed shows very good agreement with theory and other measurements. Also included are an overview of the fixed wireless industry, a discussion of system design issues, and a review of the historical and mathematical development of diffraction theory. / Master of Science diffraction propagation LMDS 28 GHz measurements
2	A Study of Rough Surface Scattering Phenomena in the LMDS Band (28 GHz) Dillard, Cindy Lin 18 March 2003 (has links) In this study, the properties of the reflected paths and scattering phenomena were investigated in the LMDS band (28 GHz). We used the newly developed sampling swept time delay short pulse (SSTDSP) sounder to collect field data in certain locations on the Virginia Tech campus. The sounder collected the channel impulse response analog waveform, sampled, digitized and reconstructed it. The stored data were used to produce the power delay profile and other channel parameters. In particular, we collected scattered and reflected data regarding the channel response with different incident angle and distance set-ups from brick and limestone walls. We used the reflected pulse width and maximum excess delay derived from each power delay profile to analyze the rough surface scattering phenomena. We found that limestone and brick walls exhibited some diffuse scattering. The reflected pulse of a limestone wall had more maximum excess delay spread than did a brick wall at -15dB power threshold. The mean maximum excess delay for the reflected pulse of the limestone wall measurement set-ups was more than two times that of the brick wall. With equal transmitter and receiver distances to the wall, we found that as the incident angle increased, the maximum excess delay decreased but the perpendicular reflection coefficient increased. It is recommended that for future study, a second generation SSTDSP sounder will replicate the measurement with larger distance and angle set-ups as well as in non-line-of-sight areas. / Master of Science 28 GHz LMDS Radio wave propagation Scattering Rough surface
3	A wide-angle pattern diversity antenna system for mmWave 5G mobile terminals Sadananda, K.G., Elfergani, Issa T., Zebiri, C., Rodriguez, Jonathan, Koul, S.K., Abd-Alhameed, Raed 16 February 2022 (has links) Yes / A shared ground shared radiator with wide angular coverage for mmWave 5G smartphones is proposed in this paper. A four-element corporate-fed array with conventional impedance matched power divider is designed. Stepped impedance transformers are integrated with the corner most elements to achieve pattern diversity with wide angular coverage without signifi-cant compromise in gain. The proposed three-port shared radiator conformal commercial an-tenna could be easily integrated with commercial mmWave 5G smartphones. All the three ports’ excitations operate in the 28 GHz band. Radiation pattern bandwidth of the multi-port system is high. The gain variation is from 6 to11 dBi amongst the ports and across the operating spectrum. The highest mutual coupling is 10 dB, in spite of the electrically connected structure. The pro-posed shared radiator element has a wide angular coverage of 100°, maintaining high front-to-back ratio when the respective port is excited. Simulation and measurement results for the proposed structure are illustrated in detail. / This work is supported by the Moore4Medical project, funded within ECSEL JU in collaboration with the EU H2020 Framework Programme (H2020/2014-2020) under grant agreement H2020-ECSEL-2019-IA-876190, and Fundação para a Ciência e Tecnologia (ECSEL/0006/2019). Shared radiator Conformal mmWave 5G 28 GHz band
4	Channel Impulse Response and Its Relationship to Bit Error Rate at 28 GHz Miniuk, Mary 10 February 2004 (has links) Over the years, the Internet has become increasingly popular and people's dependence on it has increased dramatically. Whether it be to communicate to someone across the world, find blueprints, or check sports scores, the Internet has become a necessary resource for everyone. In emergency situations, this need increases further. After the terrorist attacks on the Pentagon, it took several days to restore communications. This is not an acceptable time frame when people's lives are at stake. Virginia Tech's Center for Wireless Telecommunication has developed a prototype of a rapidly deployable high bandwidth wireless communication system at 28 GHz (Local Multipoint Distribution Service frequency). This system provides a large bandwidth radio link to a disaster zone up to 5 km away and puts Ethernet speeds and 802.11 accesses to users within hours. Because of the possible variability in locations that the system can be deployed, it is necessary to find the most useable channel at the site as quickly as possible. In addition to 28GHz radio links, the system also has a built-in channel sounder that measures and captures the channel impulse response of the current channel. Until now, there has been limited research on the relationship between the channel impulse response and the usability of the channel quantified using bit error rate. This thesis examines several different channels captured by CWT's channel sounder and simulates the BER using Cadence's SPW with time-domain models of the channels. This thesis goes on further to show that BER greatly depends on the channel impulse response and the symbol rate. / Master of Science Power Delay Profile NLOS LMDS 28 GHz BER Channel Impulse Response
5	[en] INDOOR PROPAGATION MEASUREMENTS AT 28 AND 38 GHZ FOR APPLICATION IN THE 5TH GENERATION CELLULAR SYSTEMS / [pt] MEDIÇÕES DE PROPAGAÇÃO EM AMBIENTES FECHADOS NAS FAIXAS DE 28 E 38 GHZ PARA APLICAÇÃO EM SISTEMAS CELULARES DE QUINTA GERAÇÃO CRISTINE SIMOES FELISBINO 18 April 2022 (has links) [pt] O uso de dispositivos móveis cresceu exponencialmente nos últimos anos, tornando-se um desafio a melhoria da qualidade de sinal e o pleno atendimento a serviços que exigem altas taxas de dados e baixa latência. A fim de atender a crescente demanda de tráfego, as faixas de freqüências de ondas milimétricas começam a ser exploradas para aplicação à Quinta Geração de Comunicações Móveis. A partir de medições realizadas em ambientes fechados, nas faixas de freqüências de 28 GHz e 38 GHz, foi possível analisar o canal de comunicação com base nos modelos propagação para as faixas de freqüências de ondas milimétricas. / [en] Mobile usage has grown exponentially in recent years, making it a challenge to improve signal quality and fully support to services that require high data rates and low latency. In order to meet the growing traffic demand, millimeter-wave frequency bands are being explored for application to the 5th Generation of Mobile Communications. From measurements performed in indoor environments, in the 28 GHz and 38 GHz frequency range, it was possible to analyze the communication channel based on the propagation models for the millimeter wave frequency bands. [pt] COMUNICACOES MOVEIS [pt] PROPAGACAO EM AMBIENTES FECHADOS [pt] QUINTA GERACAO [pt] 5 G [pt] 38 GHZ [pt] 28 GHZ [pt] ONDAS MILIMETRICAS [en] MOBILE COMMUNICATIONS [en] PROPAGATION IN INDOOR ENVIRONMENTS [en] FIFTH GENERATION [en] 5 G [en] 38 GHZ [en] 28 GHZ [en] MILLIMETER WAVES
6	Performance Comparison of Harmonically Tuned Power Amplifiers at 28 GHz in SiGe BiCMOS Phan, Diem Thanh 07 March 2017 (has links) As the demand for wireless electronics is increasing, more and more gadgets are connected wirelessly and devices are being improved constantly. The need of the new research and development for advance electronics with high performances is the priority. The data transfer rates are improved for faster communication and better efficiency is to reduce the battery consumption in handheld devices. This thesis presents three single-stage power amplifiers (PAs): class-AB, class-F and inverse class-F (class-F-1) at 28 GHz. The PAs have identical input networks: input matching, base DC feed, and base stabilizing networks. At the load side, there is a different load network for each PA. Class-AB PA load network has a single inductor with a parasitic capacitor to create a resonance at 28GHz. Class-F PA load network is composed of a parallel network (one LC tank in series with an inductor) and a series network (one 3f0-resonance LC tank in series with a capacitor) to create a multi-resonance load network. Class-F-1 load network is composed of a parallel network (two LC tank in series with an inductor) and a series network (one 2f0-resonance LC tank in series with a capacitor) to have a multi-resonance network. The main purpose of using multi-resonance load networks in class-F and class-F-1 is to shape the collector currents and voltages in order to achieve the highest efficiency possible. The chosen bias point is VCE=2.3V and ICE~12mA. As the results, class-AB PA achieves the peak PAE of 44%, 15 dBm OP-1dB, >19 dBm Psat , and 10 dB Gp. Class-F PA achieves the peak PAE of 46%, 14.5 dBm OP-1dB, ~18 dBm Psat , and 10 dB Gp. Class-F-1 PA achieves the peak PAE of 45%, 15.1 dBm OP-1dB, >18 dBm Psat , and 10 dB Gp.. In order to compare the linearity performances among three PA classes, a two-tone signal and a modulated signal with different modulation schemes (QPSK, 16QAM, 64QAM, and 256QAM) are applied to the PAs to produce IM3, ACPR, and EVM. After the analysis and comparison on efficiency and linearity, class-F PA gives the highest efficiency but has the worst linearity while class-AB has the best linearity but has the worst efficiency among three. Class-F-1 PA results lies in the middle of two other classes in term of efficiency and linearity. / Master of Science 5G 28 GHz class-AB class-F class-F-1 harmonic tuned power amplifier SiGe PA linearity.
7	Multi-Polarized Channel Characterization Golmohamadi, Marcia 01 January 2019 (has links) Machine-to-machine (M2M) communication is becoming an important aspect of warehouse management, remote control, robotics, traffic control, supply chain management, fleet management and telemedicine. M2M is expected to become a significant portion of the Industrial Internet and, more broadly, the Internet of Things (IoT). The environments in which M2M systems are expected to operate may be challenging in terms of radio wave propagation due to their cluttered, multipath nature, which can cause deep signal fades and signal depolarization. Polarization diversity in two dimensions is a well-known technique to mitigate such fades. But in the presence of reflectors and retarders where multipath components arrive from any direction, we find the detrimental effects to be three-dimensional and thus consider herein mitigation approaches that are also 3D. The objectives of this dissertation are three. First, to provide a theoretical framework for depolarization in three dimensions. Second, to prepare a tripolar antenna design that meets cost, power consumption, and simplicity requirements of M2M applications and that can mitigate the expected channel effects. Finally, to develop new channel models in three dimensional space for wireless systems. Accordingly, this dissertation presents a complete description of 3D electromagnetic fields, in terms of their polarization characteristics and confirms the advantage of employing tripolar antennas in multipath conditions. Furthermore, the experimental results illustrate that highly variable depolarization occurs across all three spatial dimensions and is dependent on small changes in frequency and space. Motivated by these empirical results, we worked with a collaborating institution to develop a three-dimensional tripolar antenna that can be integrated with a commercially available wireless sensor. This dissertation presents the testing results that show that this design significantly improves channels over traditional 2D approaches. The implications of tripolar antenna integration on M2M systems include reduction in energy use, longer wireless communication link distances, and/or greater link reliability. Similar results are shown for a planar antenna design that enables four different polarization configurations. Finally, the work presents a novel three-dimensional geometry-based stochastic channel model that builds the channel as a sum of shell-like sub-regions, where each sub-region consists of groups of multipath components. The model is validated with empirical data to show the approach may be used for system analyses in indoor environments. 28-GHz Indoor Channels Circular Polarization Multipath Propagation Three Polarization Diversity Tri-polarized Antenna Electrical and Electronics
8	Coexistence of Wireless Systems for Spectrum Sharing Kim, Seungmo 28 July 2017 (has links) Sharing a band of frequencies in the radio spectrum among multiple wireless systems has emerged as a viable solution for alleviating the severe capacity crunch in next-generation wireless mobile networks such as 5th generation mobile networks (5G). Spectrum sharing can be achieved by enabling multiple wireless systems to coexist in a single spectrum band. In this dissertation, we discuss the following coexistence problems in spectrum bands that have recently been raising notable research interest: 5G and Fixed Satellite Service (FSS) at 27.5-28.35 GHz (28 GHz); 5G and Fixed Service (FS) at 71-76 GHz (70 GHz); vehicular communications and Wi-Fi at 5.85-5.925 GHz (5.9 GHz); and mobile broadband communications and radar at 3.55-3.7 GHz (3.5 GHz). The results presented in each of the aforementioned parts show comprehensively that the coexistence methods help achieve spectrum sharing in each of the bands, and therefore contribute to achieve appreciable increase of bandwidth efficiency. The proposed techniques can contribute to making spectrum sharing a viable solution for the ever evolving capacity demands in the wireless communications landscape. / Ph. D. Coexistence Spectrum Sharing mmW 28 GHz 70 GHz 5G Fixed Satellite Service Fixed Service 3.5 GHz Pulsed Radar OFDM LTE Wi-Fi 5.9 GHz DSRC IEEE 802.11ac
9	Millimeter-Wave Harmonically-Tuned Silicon Power Amplifiers for High Efficiency Mortazavi, Seyed Yahya 09 September 2016 (has links) This works demonstrates the feasibility of the inverse-Class-F harmonic tuning approach for mm-wave silicon PAs. This research addresses the challenges and limitations of the high efficiency inverse-Class-F PAs for mm-wave silicon technology. This work proposes different load networks to mitigate the challenges which are verified with implementations at different mm-wave frequencies with the highest power efficiency performances reported so far: PAE= 50% @ 24 GHz, PAE = 43% @ 41 GHz, and PAE = 23% @ 94 GHz. The design methodology and detailed analysis of the proposed load networks presented and verified with implementation and measured results. / Ph. D. Class-F class-F-1 5G harmonic tuned power amplifier inverse class F 28 GHz 38 GHz Ka-band PA SiGe PA

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