[en] MODULATION TECHNIQUES IN EHF / [pt] TÉCNICAS DE MODULAÇÃO EM EHF

MARIA GUILLERMINA ALBARRACIN POLO

23 August 2016

[pt] Devido às exigências da largura de banda, especialmente nas comunicações sem fios que são cada dia maiores pelo aumento do numero de usuários, é necessário estudar a banda de EHF(Extremely High Frequency). A transmissão e recepção de dados em EHF constitui uma possível solução para aliviar a escassez do espectro e satisfazer a crescente demanda de maiores velocidades tentado resolver as limitações dos sistemas atuais. As ondas de radio na banda EHF vão de 30 até 300 GHz e são chamadas ondas milimétricas, já que seus comprimentos de onda vão de 10 mm até 1 mm. Neste trabalho, a montagem de um sistema de geração e detecção de ondas de EHF a partir do batimento de dois lasers é apresentada. Técnicas de modulação e demodulação em fase, amplitude e frequência na faixa de 200-300 GHz são demonstradas. / [en] The capacity of wireless communications has started to reach the top and the unstoppable increase of users is becoming a problem because more bandwidth is needed, which has gave rise to the study of EHF (Extremely High Frequency) band. Transmission and reception of data in EHF is shown as a solution to alleviate the scarcity of the spectrum and to meet the request of faster speeds to solve the limitation of the actual systems. The range of radio waves in EHF band go from 30 to 300 GHz, and are called millimeter waves since their wavelengths are between 10mm and 1mm. In this work is presented a system capable to generate and detect EHF waves from the beating of two lasers, and at the same time different modulation and demodulation techniques (phase, amplitude and frequency) are presented.

[pt] EHF - EXTREMELY HIGH FREQUENCY

[pt] LOCK-IN AMPLIFIER

[pt] MODULACAO DE FREQUENCIA

[pt] MODULACAO DE AMPLITUDE

[pt] MODULACAO DE FASE

[en] EHF - EXTREMELY HIGH FREQUENCY

Design of a Super High Frequency (SHF) Extremely High Frequency (EHF) Satellite Communications (SATCOM) Terminal (SEST) for New Construction Naval Surface Ships using the systems engineering process

Harrell, Steven B.

16 February 2010

Alternative means of satisfying the high bandwidth and protected communications requirements for New Construction Naval Surface Ships in the midst of conflicting reduced radar cross section (RCS) requirements were investigated using the systems engineering process. <p>Various antenna, ranging from parabolic dish antennas to Luneberg lens antennas to phased array antennas, and feed and amplifier combinations were considered to provide a dual-band Super High Frequency (SHF) and Extremely High Frequency (EHF) Satellite Communications (SATCOM) Terminal (SEST). <p>Through the design of this hypothetical system, the various stages of the systems engineering process are considered-- definition of need, conceptual design, preliminary system design, production and installation, and utilization and support. Sample tasks are performed at each stage in the process (e.g., a system performance specification is prepared in the advanced system planning stage). <p>The set of technical solutions that remained in the preliminary design phase are compared based on life cycle costs. Two approaches are recommended -- one assuming lowest life cycle cost has highest priority and one assuming that the ability to communicate simultaneously on SHF and EHF has highest priority. / Master of Science

super high frequency

satellite communications

extremely high frequency

LD5655.V851 1996.H377

[en] TRANSMISSION AND RECEPTION OF DATA IN EHF / [pt] TRANSMISSÃO E RECEPÇÃO DE DADOS EM EHF

ANDY ALVAREZ ARELLANO

30 November 2017

[pt] Nos últimos anos, as bandas de frequências nas comunicações sem fio estão começando a saturar devido ao incremento do tráfego e o aumento dos usuários, é devido a isso que, é necessário estudar as bandas de frequências que não estão sendo utilizadas nas áreas das comunicações como a banda milimétrica e sub-milimétrica. A transmissão de dados na banda EHF o banda milimétrica constitui uma possível solução para conseguir transmitir maiores quantidades de informação a altas velocidades de transmissão aliviando as bandas de frequências atuais. Neste trabalho se estuda a transmissão de dados em frequências de 100, 200, 300 e 400 GHz, empregando a modulação Quadrature Phase-Shift Keying (QPSK) mediante uma arquitetura baseada no batimento de dois lasers, cujas frequências são combinadas em um Beam Splitter, para que a corrente resultante da soma dos campos elétricos dos dois lasers seja convertida em um sinal de alta frequência por meio de uma antena fotocondutora. O batimento dos dois lasers, com diferentes comprimentos de onda e com a mesma potência, ao interagir com uma antena fotocondutora dá como resultado uma frequência na ordem de Gigahertz. No experimento utilizaram-se dois tipos de diodos receptores, um de banda larga (menor que 4 GHz) e outro de banda estreita (menor que 1 MHz). As duas antenas foram testadas em diferentes distâncias e com diferentes frequências de portadora para verificar qual delas tinha o melhor desempenho na banda EHF para poder realizar a transmissão de dados. / [en] In recent years, the frequency bands in wireless communications are beginning to saturate due to the increase of traffic and the increase of users, and it for that reason that is necessary to study the frequency bands that are not begin used in the communication areas like millimeter and sub-millimeters bands. Data transmission in the EHF band is a possible solution to be able to transmit large amounts of information at high transmission speeds, alleviating current frequency bands. In this work, the transmission of data in frequencies of 100, 200, 300 and 400 Gigahertz is studied, using Quadrature phase-shift keying (QPSK) modulation with an architecture based on the beat of two lasers, whos frequencies are combined by means of Beam Splitter, so that result of the electric fields of two lasers is converted into a high frequency signal with the aid of a photoconductor antenna. The.beating of the two lasers, with different wavelengths and with the same power, when interacting with a photoconductor antenna results in a frequency in the order of Gigahertz. In the experiment, two types of receiver diodes were used, one Broadband (less than 4 GHz) and the other of narrowband (less than 1 MHz). The two antennas were tested at different distances and with different carrier frequencies to verify which one had the best performance in the EHF band in order to perform the data transmission.

[pt] EHF - EXTREMELY HIGH FREQUENCY

[en] EHF - EXTREMELY HIGH FREQUENCY

[pt] EVM - ERROR VECTOR MAGNITUDE

[en] EVM - ERROR VECTOR MAGNITUDE

Nanostructures de carbone dédiées aux interconnexions hautes fréquences / Carbon nanostructure dedicated to high frequency interconnects

Roux-Levy, Philippe

17 December 2018

A extrêmement hautes fréquences, les applications électroniques vont être confrontées à des challenges liés à la réduction des dimensions et la compacité des systèmes. Les limites physiques des matériaux conventionnels étant atteintes, de nouvelles alternatives sont nécessaires dans le domaine du nano-packaging. De nouveaux matériaux ont été étudiés pour remplacer les matériaux conventionnels. Parmi eux, le nanotube de carbone démontre une excellente conductivité électrique et thermique ainsi qu’une résistance physique extraordinaire. Il est donc un candidat de choix pour des applications comme les interconnexions, l’évacuation de chaleur, le blindage électromagnétique ou encore le renforcement structurel. Autant de points capitaux pour le nano-packaging moderne. Dans ce manuscrit, les nanotubes de carbone vont être étudiés en profondeur pour réaffirmer leurs propriétés électroniques et thermiques hors du commun. Nous nous concentrerons ensuite sur l’étude de deux types d’interconnexions à base de nanotubes de carbone : des interconnexions à base de plot en nanotubes de carbone utilisant la technologie Flip-Chip et des interconnexions sans-fil à base de monopole composé de nanotubes de carbone. Enfin, nous étudierons la possibilité de créer des composants passifs Radio-Fréquence à l’aide de structures en nanotubes de carbone. De nouvelles méthodes de fabrication des structures en CNT ont été utilisées au cours de ces travaux de thèse afin d’obtenir une compatibilité avec les technologies CMOS. / At extremely high frequency, electronic applications will have to challenge problems born from the size reduction and compactification of the systems. Physical limits of conventional materials will be reached and so new alternatives are necessary in the nano-packaging field. New materials have been studied to replace conventional materials. Among them, carbon nanotubes have shown extremely high electrical and thermal conductivity as well as extraordinary physical resistance. And so carbon nanotubes are a good candidate for applications such as interconnects, thermal management, electromagnetic shielding or structural reinforcement. All of those applications are capital for modern nano-packaging. In this manuscript, carbon nanotubes will be studied in depths to demonstrate again their incredible electronic and thermal properties. We will then focus on the study of two types of carbon nanotubes based interconnects: carbon nanotubes bumps based interconnects for Flip-Chip applications and wireless interconnects based on carbon nanotubes monopole antenna. Finally, we will study the possibility of creating passive RF components using carbon nanotubes structures. New ways of fabricating the carbon nanotubes structure were used in order to get a fabrication process of the prototype completely compatible with CMOS technologies.

Interconnexions

Nanotube de carbone

Extrêmement hautes fréquences

Flipchip

Composants RF

Nano-packaging

Interconnects

Carbon nanotubes

Extremely high frequency

Flip-chip

RF components

Nano-packaging

621.381 5