Initial access in 5G mmWave networks with different base station parameters / Initial access i 5G mmWave-nät med olika basstationsparametrar

Yang, Xiao

January 2022

Nowadays in the fifth generation (5G) communication systems, millimeter wave (mmWave) has aroused interest to not only industrial use but also network operators due to the massive amount of bandwidth available at mmWave frequencies. Initial access in cellular systems is an essential procedure in which new mobile user equipment (UE) establishes a connection with a base station (BS). However, mmWave relies on highly directional beamforming (BF) to overcome its severe path loss, while the initial access requires a wide beam to obtain sufficient information for beamforming. So the challenge is to handle the balance between highly directional mmWave and fast and reliable initial access. The high path loss of millimetre wave transmission dictates that multiple BSs may be closer and interfere more with each other. We focus our study on two BS parameters under the random search method. In our study, the beamwidth can be different for each BS, but a uniform number of slot limits needs to be chosen for all BSs. Our objective is to obtain the best parameters for each BS in a reasonable period of time. We build a systemlevel simulation in MATLAB and explored a variety of methods to select the best parameters, including reinforcement learning, supervised learning, and genetic algorithms. It is identified that the main challenge of applying reinforcement learning and supervised learning is the exponentially growing variety of BS parameters. A genetic algorithm is able to derive approximate best values in complex relational species. Therefore the genetic algorithm is considered to be able to be applied in scenarios with a high number of BSs. The result shows that reinforcement learning has great performance in a few BS cases, and the genetic algorithm is able to provide a large improvement over most of the BS methods with the same parameters. / I den femte generationens kommunikationssystem har millimetervågor väckt intresse, inte bara inom industrin utan även hos nätverksoperatörer, på grund av den enorma bandbredd som finns tillgänglig vid mmWave-frekvenser. Initial access i cellulära system är ett viktigt förfarande där ny mobil användarutrustning upprättar en anslutning till en basstation. mmWave är dock beroende av starkt riktad strålformning för att övervinna den allvarliga vägförlusten, medan den inledande åtkomsten kräver en bred stråle för att få tillräcklig information för strålformning. Utmaningen består alltså i att hantera balansen mellan mycket riktgivande mmWave och snabb och tillförlitlig initial access. Den höga vägförlusten för millimetervågsöverföring innebär att flera stationära basstationer kan vara närmare varandra och störa varandra mer. Vi fokuserar vår studie på två parametrar för BS med hjälp av metoden för slumpmässig sökning. I vår studie kan strålbredden vara olika för varje BS, men ett enhetligt antal slotgränser måste väljas för alla BS. Vårt mål är att få fram debästa parametrarna för varje BS på en rimlig tidsperiod. Vi bygger upp en simulering på systemnivå i MATLAB och utforskade en rad olika metoder för att välja de bästa parametrarna, bland annat förstärkningsinlärning, övervakad inlärning och genetiska algoritmer. Det konstateras att de största utmaningarna vid tillämpning av förstärkningsinlärning och övervakad inlärning är det exponentiellt växande utbudet av parametrar för BS. Genetisk algoritm kan härleda ungefärliga bästa värden i komplexa relationella arter. Därför anses den genetiska algoritmen kunna tillämpas i scenarier med ett stort antal BSs. Resultatet visar att förstärkningsinlärning har stor prestanda i ett fåtal BS-fall och att genetisk algoritm kan ge en stor förbättring jämfört med de flesta BS-metoder med samma parametrar.

Initial Access

Millimeter-Wave Network

Cell Search

Random Search

Genetic Algorithm

Machine Learning

Första åtkomst

Millimetervågsnätverk

Cell sökning

Slumpmässig sökning

Genetisk algoritm

Maskininlärning

Computer and Information Sciences

Data- och informationsvetenskap

Millimeter Wave Radar as Navigation Sensor on Robotic Vacuum Cleaner / Millimetervågsradar som navigationssensor på robotdammsugare

Blomqvist, Anneli

January 2020

Does millimeter-wave radar have the potential to be the navigational instrument of a robotic vacuum cleaner in a home? Electrolux robotic vacuum cleaner is currently using a light sensor to navigate through the home while cleaning. Recently Texas Instruments released a new mmWave radar sensor, operating in the frequency range 60-64 GHz. This study aims to answer if the mmWave radar sensor is useful for indoor navigation. The study tests the sensor on accuracy and resolution of angles and distances in ranges relevant to indoor navigation. It tests if various objects made out of plastic, fabric, paper, metal, and wood are detectable by the sensor. At last, it tests what the sensor can see when it is moving while measuring. The radar sensor can localize the robot, but the ability to detect objects around the robot is limited. The sensor’s absolute accuracy is within 3° for the majority of angles and around 1dm for most distances above 0.5 m. The resolution for a displacement of one object is 1°, respectively 5 cm, and two objects must be located at least 14° or 15 cm apart from each other to be recognized. Future tasks include removing noise due to antenna coupling to improve reflections from within 0.5 meter and figure out the best way to move around the sensor to improve the resolution. / Har radar med millimetervågor förutsättningar att vara navigationsutrustning för en robotdammsugare i ett hem? Electrolux robotdammsugare använder för närvarande en ljussensor för att navigera genom hemmet medan den städar. Nyligen släppte Texas Instruments en ny radarsensor med vågor i frekvensområdet 60-64 GHz. Denna studie syftar till att svara om radarsensorn är användbar för inomhusnavigering. Studien testar sensorn med avseende på noggrannhet och upplösning av vinklar och avstånd i områden som är relevanta för inomhusnavigering. Den testar om olika föremål tillverkade av plast, tyg, papper, metall och trä kan detekteras av sensorn. Slutligen testas vad sensorn kan se om den rör sig medan den mäter. Radarsensorn kan positionera roboten, men hinderdetektering omkring roboten är begränsad. För det mesta ligger sensorns absoluta noggrannhet inom 3° för vinklar och omkring 1dm för avstånd över 0,5 m. Upplösningen för en förflyttning av ett objekt är 1° respektive 5 cm, och två objekt måste placeras minst 14° eller 15 cm ifrån varandra för att båda kunna upptäckas. Kommande utmaningar är att ta bort antennstörningar som ger sämre reflektioner inom 0,5 meter och ta reda på det bästa sättet att förflytta sensorn för att förbättra upplösningen.

Millimeter wave radar

Robotic vacuum cleaner

Indoor navigation

Localization

Obstacle Detection

Millimeter radar

Robotdammsugare

Navigering inomhus

Positionering

Hinderdetektion

Elektroteknik och elektronik

Wideband Terrestrial Path Loss Measurement Results For Characterization of Pico-cell Radio Links at 38 GHz and 60 GHz Bands of Frequencies

Kukshya, Vikas

22 June 2001

The advent of Internet based digital services, and bandwidth-intensive business and personal applications has necessitated deployment of broadband network access technologies. Research analysts project that the U.S. market for broadband wireless networking will grow to nearly $2 billion by 2004 and Local Multipoint Distribution Services (LMDS) have enormous potential to emerge as the most reliable and cost-effective solution. However, in order to design and deploy LMDS systems, it is vital for system designers to be able to predict the behavior of mm-waves (28, 38 and 60GHz) during different weather conditions, especially rain. This research attempts to characterize the performance of pico-cell scenario broadband wireless channels by measuring path loss statistics during different weather conditions. Hardware and software components of a wideband direct-sequence spread spectrum (DSS) channel sounding system, used extensively throughout measurement campaigns, are discussed in detail in this dissertation. The measurement plan comprehensively describes the methodology, logistics, equipment setup, and calibration procedures for propagation measurement campaigns. Power Delay Profile (PDP) snapshots recorded during measurement campaigns are thoroughly analyzed using the 'Channel Imaging Analysis Suite' and Path Loss as well as Rain Attenuation statistics, calculated from recorded PDP data files, are classified and tabulated on the basis of measurement locations, propagation frequencies and antenna polarizations. Path Loss Exponent values are also calculated and Rain Attenuation statistics are compared with popular rain models. Results from Frequency Diversity measurement campaigns are also presented. / Master of Science

horizontal polarization

millimeter wave

pico-cell radio links

vertical polarization

frequency diversity

FSO

LMDS

60GHz

38GHz

rain attenuation

radiowave propagation

wireless communications

Multi-beam Antenna Array System with Butler Matrix for mmWave Applications

Wang, Xiaozhou

18 June 2024

The growing demand for high data rates, reliable connections, low latency, and increased user density has driven the operating frequency of modern wireless communication systems towards the millimeter-wave (mmWave) band. Large-scale antenna arrays capable of supporting simultaneous multi-beamforming are crucial for these mmWave systems. Passive beamforming networks, particularly Butler matrices (BM), offer several advantages for mmWave applications due to their low complexity, high energy efficiency, zero DC power consumption, and ability to generate multiple orthogonal beams. However, existing BM designs are often limited to low-order matrices, supporting a restricted number of radiating elements and featuring bulky cubic structures unsuitable for the microwave range. The contributions of this work include extensions in the Butler matrix order to support a massive antenna array, simplification of the Butler matrix topology to reduce the insertion loss, and layout optimization for straightforward antenna array integration. The novel multi-beam antenna systems for the one- and two-dimensional beamforming at mmWave band are designed and experimentally validated. First of all, a theoretical analysis of the Butler matrix topology is conducted to find effective solutions for matrix order extension, simplification, and loss reduction. Then, a multi-beam system consisting of a compact 8×8 one-dimension BM and an antenna array is implemented. To further extend the number of multi-beams, a 28 GHz multi-beam array system based on high-dimension 16 × 16 one-dimension BM and 1 × 16 linear antenna array is proposed. Additionally, a 28 GHz multi-beam array system fed by a planar 16 × 16 twodimensional Butler matrix is examined. Utilizing the proposed concept for the planarization of the cubic-formed two-dimensional Butler matrix, a system implemented with the multi-layer lamination in a dramatically reduced size provides 16 spatial orthogonal beams over a conical space. Furthermore, two new concepts for the planar and uni-planar 32 × 32 two-dimensional Butler matrix are developed not only for more beams but also to reduce the required signal layers.

info:eu-repo/classification/ddc/621

ddc:621

Low-cost SiGe circuits for frequency synthesis in millimeter-wave devices

Lauterbach, Adam Peter

January 2010

"2009" / Thesis (MSc (Hons))--Macquarie University, Faculty of Science, Dept. of Physics and Engineering, 2010. / Bibliography: p. 163-166. / Introduction -- Design theory and process technology -- 15GHz oscillator implementations -- 24GHz oscillator implementation -- Frequency prescaler implementation -- MMIC fabrication and measurement -- Conclusion. / Advances in Silicon Germanium (SiGe) Bipolar Complementary Metal Oxide Semiconductor (BiCMOS) technology has caused a recent revolution in low-cost Monolithic Microwave Integrated Circuit (MMIC) design. -- This thesis presents the design, fabrication and measurement of four MMICs for frequency synthesis, manufactured in a commercially available IBM 0.18μm SiGe BiCMOS technology with ft = 60GHz. The high speed and low-cost features of SiGe Heterojunction Bipolar Transistors (HBTs) were exploited to successfully develop two single-ended injection-lockable 15GHz Voltage Controlled Oscillators (VCOs) for application in an active Ka-Band antenna beam-forming network, and a 24GHz differential cross-coupled VCO and 1/6 synchronous static frequency prescaler for emerging Ultra Wideband (UWB) automotive Short Range Radar (SRR) applications. -- On-wafer measurement techniques were used to precisely characterise the performance of each circuit and compare against expected simulation results and state-of-the-art performance reported in the literature. -- The original contributions of this thesis include the application of negative resistance theory to single-ended and differential SiGe VCO design at 15-24GHz, consideration of manufacturing process variation on 24GHz VCO and prescaler performance, implementation of a fully static multi-stage synchronous divider topology at 24GHz and the use of differential on-wafer measurement techniques. -- Finally, this thesis has llustrated the excellent practicability of SiGe BiCMOS technology in the engineering of high performance, low-cost MMICs for frequency synthesis in millimeterwave (mm-wave) devices. / Mode of access: World Wide Web. / xxii, 166 p. : ill (some col.)

Frequency synthesizers

Millimeter wave devices

Semiconductors

Silicon compounds

Germanium compounds

Bipolar transistor

Metal oxide semiconductors

SiGe

BiCMOS

Voltage Controlled Oscillator (VCO)

Millimeter-wave (mm-wave)

Short Range Radar (SRR)

frequency prescaler

Development of superconducting bolometer device technology for millimeter-wave cosmology instruments

Otto, Ernst

January 2013

The Cold-Electron Bolometer (CEB) is a sensitive detector of millimeter-wave radiation, in which tunnel junctions are used as temperature sensors of a nanoscale normal metal strip absorber. The absorber is fed by an antenna via two Superconductor-Insulator-Normal metal (SIN) tunnel junctions, fabricated at both ends of the absorber. Incoming photons excite electrons, heating the whole electron system. The incoming RF power is determined by measuring the tunneling current through the SIN junctions. Since electrons at highest energy levels escape the absorber through the tunnel junctions, it causes cooling of the absorber. This electron cooling provides electro-thermal feedback that makes the saturation power of a CEB well above that of other types of millimeter-wave receivers. The key features of CEB detectors are high sensitivity, large dynamic range, fast response, easy integration in arrays on planar substrates, and simple readout. The high dynamic range allows the detector to operate under relatively high background levels. In this thesis, we present the development and successful operation of CEB, focusing on the fabrication technology and different implementations of the CEB for efficient detection of electromagnetic signals. We present the CEB detector integrated across a unilateral finline deposited on a planar substrate. We have measured the finline-integrated CEB performance at 280-315 mK using a calibrated black-body source mounted inside the cryostat. The results have demonstrated strong response to the incoming RF power and reasonable sensitivity. We also present CEB devices fabricated with advanced technologies and integrated in log-periodic, double-dipole and cross-slot antennas. The measured CEB performance satisfied the requirements of the balloon-borne experiment BOOMERANG and could be considered for future balloon-borne and ground-based instruments. In this thesis we also investigated a planar phase switch integrated in a back-to-back finline for modulating the polarization of weak electromagnetic signals. We examine the switching characteristics and demonstrate that the switching speed of the device is well above the speed required for phase modulation in astronomical instruments. We also investigated the combination of a detector and a superconducting phase switch for modulating the polarization of electromagnetic radiation.

539.7

Integrated silicon technology and hardware design techniques for ultra-wideband and next generation wireless systems

Huo, Yiming

18 May 2017

The last two decades have witnessed the CMOS processes and design techniques develop and prosper with unprecedented speed. They have been widely employed in contemporary integrated circuit (IC) commercial products resulting in highly added value. Tremendous e orts have been devoted to extend and optimize the CMOS process and its application for future wireless communication systems. Meanwhile, the last twenty years have also seen the fast booming of the wireless communication technology typically characterized by the mobile communication technology, WLAN technology, WPAN technology, etc. Nowadays, the spectral resource is getting increasingly scarce, particularly over the frequency from 0.7 to 6 GHz, whether the employed frequency band is licensed or not. To combat this dilemma, the ultra wideband (UWB) technology emerges to provide a promising solution for short-range wireless communication while using an unlicensed wide band in an overlay manner. Another trend of obtaining more spectrum is moving upwards to higher frequency bands. The WiFi-Alliance has already developed a certi cation program of the 60-GHz band. On the other side, millimeterwave (mmWave) frequency bands such as 28-GHz, 38-GHz, and 71-GHz are likely to be licensed for next generation wireless communication networks. This new trend poses both a challenge and opportunity for the mmWave integrated circuits design. This thesis combines the state-of-the-art IC and hardware technologies and design techniques to implement and propose UWB and 5G prototyping systems. First of all, by giving a thorough analysis of a transmitted reference pulse cluster (TRPC) scheme and mathematical modeling, a TRPC-UWB transceiver structure is proposed and its features and speci cations are derived. Following that, the detailed design, fabrication and veri cation of the TRPC-UWB transmitter front end and wideband voltage-controlled oscillators (VCOs) in CMOS process is presented. The TRPCUWB transmitter demonstrates a state-of-the-art energy e ciency of 38.4 pJ/pulse. Secondly, a novel system architecture named distributed phased array based MIMO (DPA-MIMO) is proposed as a solution to overcome design challenges for the future 5G cellular user equipment (UE) design. In addition, a prototyping design of on-chip mmWave antenna with radiation e ciency enhancement is presented for the IEEE 802.11ad application. Furthermore, two wideband K-band VCO prototypes based on two di erent topologies are designed and fabricated in a standard CMOS process. They both show good performance at center frequencies of 22.3 and 26.1 GHz. Finally, two CMOS mmWave VCO prototypes working at the potential future 5G frequency bands are presented with measurement results. / Graduate / 2018-04-30 / amenghym@gmail.com

UWB

Next Generation

Wireless Communication

CMOS

Silicon

5G

Voltage-controlled Oscillator (VCO)

Apple Inc.

Low Noise Amplifier

User Equipment

Base Station

Transmitter

Receiver

Antenna

System-on-Chip (SoC)

PCB

Millimeter Wave

Investigation of mm-wave imaging and radar systems / Etude de système d'imagerie et radar en ondes millimétriques

Zeitler, Armin

11 January 2013

Durant la dernière décade, les radars millimétriques en bande W (75 - 110 GHz) pour les applications civiles que ce soit dans le domaine de l'aide à la conduite ou de la sécurité. La maturité de ces systèmes et les exigences accrues en termes d'application, orientent actuellement les recherches vers l'insertion de fonctions permettant l'identification. Ainsi, des systèmes d'imagerie radar ont été développés, notamment à l'aide d'imagerie qualitative (SAR). Les premiers résultats sont très prometteurs, cependant, afin de reconstruire les propriétés électromagnétiques des objets, il faut travailler de manière quantitative. De nombreux travaux ont déjà été conduits en ondes centimétriques, mais aucun système d'imagerie quantitative n'existe, à notre connaissance, en gamme millimétrique. L'objectif du travail présenté dans ce manuscrit est de poser les bases d'un système d'imagerie quantitative en gamme millimétrique et de le comparer à l'imagerie radar de systèmes développés en collaboration avec l'Université d'Ulm (Allemagne). L'ensemble des résultats obtenus valide le processus développé pour d'imagerie quantitative. Les recherches doivent être poursuivies. D'une part le système de mesure doit évoluer vers un vrai système multi-incidences/multivues. D'autre part, le cas 2D-TE doit être implémenté afin de pouvoir traiter un objet 2D quelconque dans n'importe quelle polarisation. Enfin, les mesures à partir de systèmes radar réels doivent être poursuivies, en particulier pour rendre exploitables les mesures des coefficients de transmission. Ces dernières sont indispensables si l'on veut un jour appliquer les algorithmes d'inversion à des mesures issues de systèmes radar. / In the last decade, microwave and millimeter-wave systems have gained importance in civil and security applications. Due to an increasing maturity and availability of circuits and components, these systems are getting more compact while being less expensive. Furthermore, quantitative imaging has been conducted at lower frequencies using computational intensive inverse problem algorithms. Due to the ill-posed character of the inverse problem, these algorithms are, in general, very sensitive to noise: the key to their successful application to experimental data is the precision of the measurement system. Only a few research teams investigate systems for imaging in the W-band. In this manuscript such a system is presented, designed to provide scattered field data to quantitative reconstruction algorithms. This manuscript is divided into six chapters. Chapter 2 describes the theory to compute numerically the scattered fields of known objects. In Chapter 3, the W-band measurement setup in the anechoic chamber is shown. Preliminary measurement results are analyzed. Relying on the measurement results, the error sources are studied and corrected by post-processing. The final results are used for the qualitative reconstruction of all three targets of interest and to image quantitatively the small cylinder. The reconstructed images are compared in detail in Chapter 4. Close range imaging has been investigated using a vector analyzer and a radar system. This is described in Chapter 5, based on a future application, which is the detection of FOD on airport runways. The conclusion is addressed in Chapter 6 and some future investigations are discussed.

Diffraction électromagnétique

Algorithmes de filtrage

Rapport signal sur bruit

Algorithmes de reconstruction

Problèmes inverses

Radar

Electromagnetic diffraction

Millimeter wave measurements

Filtering algorithms

Signal to noise ratio

Reconstruction algorithms

Inverse problems

Radar

620

Tecnologias para defasadores baseados em MEMS e linhas de transmissão de ondas lentas. / Technologies for phase shifters based on MEMS and slow-wave transmission lines.

Robert Aleksander Gavidia Bovadilla

05 July 2018

O desenvolvimento deste trabalho foi motivado pela alta demanda de novas aplicações para o mercado do consumidor que necessitam de sistemas de transmissão e recepção de dados sem fio trabalhando na região de ondas milimétricas (mmW - entre 30 GHz e 300 GHz). Para estes tipos de sistemas, os defasadores são cruciais por definir o custo e o tamanho do dispositivo final. A pesquisa bibliográfica mostra que a melhor opção são os defasadores passivos do tipo linha carregada que utilizam Sistemas Microeletromecânicos (MEMS) como elemento de ajuste para a mudança de fase. Por esse motivo neste trabalho foi feito o estudo de diferentes tecnologias para o desenvolvimento de defasadores baseados em MEMS distribuídos e linhas de transmissão com efeito de ondas lentas de tipo shielded-CoPlanar Stripline (S-CPS) e shielded-Coplanar Waveguide (S-CPW). Foram estudadas três diferentes tecnologias: a tecnologia CMOS; a tecnologia dedicada desenvolvida pelo Laboratoire d\'électronique des technologies de l\'information (CEA-Leti) e a tecnologia in-house desenvolvida no Laboratório de Microeletrônica da Universidade de São Paulo. Utilizando a tecnologia CMOS foram fabricadas linhas de transmissão de tipo S-CPS utilizando a tecnologia de 250 nm da IHP (Innovations for High Performance Microelectronics) e a tecnologia de 0,35 µm da AMS (Austria Micro Systems). A tecnologia de 0,35 µm da AMS foi utilizada também para o desenvolvimento de defasadores de 2-bits e 3-bits baseados em linhas de transmissão de tipo S-CPW. Para estes defasadores foi definido um processo de liberação da camada de blindagem, reprodutível, que permitiu a atuação do dispositivo. Outros defasadores baseados em S-CPW que foram desenvolvidos anteriormente com a tecnologia dedicada CEA-LETI, foram modelados eletrostaticamente utilizando o Comsol MultiPhysics e o Ansys Workbench. Os modelos desenvolvidos permitiram entender o comportamento eletromecânico do defasador e foram utilizados reprojetar o defasador com um desempenho otimizado. Finalmente, visando o desenvolvimento dos dispositivos otimizados utilizando a tecnologia in house com os materiais e métodos disponíveis no Laboratório de Microeletrônica da USP (LME-USP), foram estudadas algumas etapas críticas do processo de fabricação. / The development of this work is motivated by the high demand for new applications for the consumer market that require wireless systems for data transmission and reception working in the millimeter wave region (mmW - between 30 GHz and 300 GHz). For these kinds of systems, the phase shifter are crucial to define the cost and size of the final device. The bibliographical research shows that the best option are the passive load line-type phase shifters using Microelectromechanical Systems (MEMS) as tuning element. Therefore, in this work, the study of different technologies for the development of phase shifter based on distributed MEMS and slow-wave transmission lines. The two types of transmission lines considered were the shielded-CoPlanar Stripline (S-CPS) and shielded-Coplanar Waveguide line (S-CPW). Three different technologies were studied: CMOS technology; the dedicated technology developed by the Laboratoire d\'électronique des technologies de l\'information (CEA-Leti) and the in-house technology developed at the Microelectronics Laboratory of the University of São Paulo. Using the CMOS technology, S-CPS-type transmission lines were fabricated using IHP\'s 250 nm CMOS technology and AMS\'s 0.35 µm CMOS technology. AMS\'s 0.35 µm technology has also been used for the development of 2-bit and 3-bit phase-shifters based on S-CPW type transmission lines. For these phase shifters, a reproducible shielding layer release process was defined that allowed the device to operate. Also, another phase shifter based in S-CPW-type transmission lines that were previously developed with dedicated CEA-LETI technology was electrostatically modeled using Comsol MultiPhysics and Ansys Workbench. The developed models allowed to understand the electromechanical behavior of the phase shifter and was used for a new design of the phase shifter with an optimized performance. Finally, in order to develop the optimized devices using the in-house technology with the materials and methods available at the USP Microelectronics Laboratory (LME-USP), some critical stages of the fabrication process were studied.

Defasador de ondas milimétricas

MEMS

Microeletrônica

Modelamento eletromecânico

Tecnologia CMOS

CMOS technology

Electromechanical modeling

MEMS

Millimeter wave phase shifter

S-CPS and S-CPW

Slow-wave transmission line

Tecnologias para defasadores baseados em MEMS e linhas de transmissão de ondas lentas. / Technologies for phase shifters based on MEMS and slow-wave transmission lines.

Bovadilla, Robert Aleksander Gavidia

05 July 2018

O desenvolvimento deste trabalho foi motivado pela alta demanda de novas aplicações para o mercado do consumidor que necessitam de sistemas de transmissão e recepção de dados sem fio trabalhando na região de ondas milimétricas (mmW - entre 30 GHz e 300 GHz). Para estes tipos de sistemas, os defasadores são cruciais por definir o custo e o tamanho do dispositivo final. A pesquisa bibliográfica mostra que a melhor opção são os defasadores passivos do tipo linha carregada que utilizam Sistemas Microeletromecânicos (MEMS) como elemento de ajuste para a mudança de fase. Por esse motivo neste trabalho foi feito o estudo de diferentes tecnologias para o desenvolvimento de defasadores baseados em MEMS distribuídos e linhas de transmissão com efeito de ondas lentas de tipo shielded-CoPlanar Stripline (S-CPS) e shielded-Coplanar Waveguide (S-CPW). Foram estudadas três diferentes tecnologias: a tecnologia CMOS; a tecnologia dedicada desenvolvida pelo Laboratoire d\'électronique des technologies de l\'information (CEA-Leti) e a tecnologia in-house desenvolvida no Laboratório de Microeletrônica da Universidade de São Paulo. Utilizando a tecnologia CMOS foram fabricadas linhas de transmissão de tipo S-CPS utilizando a tecnologia de 250 nm da IHP (Innovations for High Performance Microelectronics) e a tecnologia de 0,35 µm da AMS (Austria Micro Systems). A tecnologia de 0,35 µm da AMS foi utilizada também para o desenvolvimento de defasadores de 2-bits e 3-bits baseados em linhas de transmissão de tipo S-CPW. Para estes defasadores foi definido um processo de liberação da camada de blindagem, reprodutível, que permitiu a atuação do dispositivo. Outros defasadores baseados em S-CPW que foram desenvolvidos anteriormente com a tecnologia dedicada CEA-LETI, foram modelados eletrostaticamente utilizando o Comsol MultiPhysics e o Ansys Workbench. Os modelos desenvolvidos permitiram entender o comportamento eletromecânico do defasador e foram utilizados reprojetar o defasador com um desempenho otimizado. Finalmente, visando o desenvolvimento dos dispositivos otimizados utilizando a tecnologia in house com os materiais e métodos disponíveis no Laboratório de Microeletrônica da USP (LME-USP), foram estudadas algumas etapas críticas do processo de fabricação. / The development of this work is motivated by the high demand for new applications for the consumer market that require wireless systems for data transmission and reception working in the millimeter wave region (mmW - between 30 GHz and 300 GHz). For these kinds of systems, the phase shifter are crucial to define the cost and size of the final device. The bibliographical research shows that the best option are the passive load line-type phase shifters using Microelectromechanical Systems (MEMS) as tuning element. Therefore, in this work, the study of different technologies for the development of phase shifter based on distributed MEMS and slow-wave transmission lines. The two types of transmission lines considered were the shielded-CoPlanar Stripline (S-CPS) and shielded-Coplanar Waveguide line (S-CPW). Three different technologies were studied: CMOS technology; the dedicated technology developed by the Laboratoire d\'électronique des technologies de l\'information (CEA-Leti) and the in-house technology developed at the Microelectronics Laboratory of the University of São Paulo. Using the CMOS technology, S-CPS-type transmission lines were fabricated using IHP\'s 250 nm CMOS technology and AMS\'s 0.35 µm CMOS technology. AMS\'s 0.35 µm technology has also been used for the development of 2-bit and 3-bit phase-shifters based on S-CPW type transmission lines. For these phase shifters, a reproducible shielding layer release process was defined that allowed the device to operate. Also, another phase shifter based in S-CPW-type transmission lines that were previously developed with dedicated CEA-LETI technology was electrostatically modeled using Comsol MultiPhysics and Ansys Workbench. The developed models allowed to understand the electromechanical behavior of the phase shifter and was used for a new design of the phase shifter with an optimized performance. Finally, in order to develop the optimized devices using the in-house technology with the materials and methods available at the USP Microelectronics Laboratory (LME-USP), some critical stages of the fabrication process were studied.

CMOS technology

Defasador de ondas milimétricas

Electromechanical modeling

MEMS

MEMS

Microeletrônica

Millimeter wave phase shifter

Modelamento eletromecânico

S-CPS and S-CPW

Slow-wave transmission line

Tecnologia CMOS