Global ETD Search

41	Development and integration of silicon-germanium front-end electronics for active phased-array antennas Coen, Christopher T. 05 July 2012 (has links) The research presented in this thesis leverages silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) technology to develop microwave front-end electronics for active phased-array antennas. The highly integrated electronics will reduce costs and improve the feasibility of snow measurements from airborne and space-borne platforms. Chapter 1 presents the motivation of this research, focusing on the technological needs of snow measurement missions. The fundamentals and benefits of SiGe HBTs and phased-array antennas for these missions are discussed as well. Chapter 2 discusses SiGe power amplifier design considerations for radar systems. Basic power amplifier design concepts, power limitations in SiGe HBTs, and techniques for increasing the output power of SiGe HBT PAs are reviewed. Chapter 3 presents the design and characterization of a robust medium power X-band SiGe power amplifier for integration into a SiGe transmit/receive module. The PA design process applies the concepts presented in Chapter 2. A detailed investigation into measurement-to-simulation discrepancies is outlined as well. Chapter 4 discusses the development and characterization of a single-chip X-band SiGe T/R module for integration into a very thin, lightweight active phased array antenna panel. The system-on-package antenna combines the high performance and integration potential of SiGe technologies with advanced substrates and packaging techniques to develop a high performance scalable antenna panel using relatively low-cost materials and silicon-based electronics. The antenna panel presented in this chapter will enable airborne SCLP measurements and advance the technology towards an eventual space-based SCLP measurement instrument that will satisfy a critical Earth science need. Finally, Chapter 5 provides concluding remarks and discusses future research directions. Microwave circuits Phased array antenna SiGe Bipolar transistors Power amplifier (PA) T/R module RF circuits Phased array antennas Radio frequency integrated circuits Power amplifiers Amplifiers (Electronics)
42	Performance Optimization Of Monopulse Tracking Radar Sahin, Mehmet Alper 01 August 2004 (has links) (PDF) An analysis and simulation tool is developed for optimizing system parameters of the monopulse target tracking radar and observing effects of the system parameters on the performance of the system over different scenarios. A monopulse tracking radar is modeled for measuring the performance of the radar with given parameters, during the thesis studies. The radar model simulates the operation of a Class IA type monopulse automatic tracking radar, which uses a planar phased array. The interacting multiple model (IMM) estimator with the Probabilistic Data Association (PDA) technique is used as the tracking filter. In addition to modeling of the tracking radar model, an optimization tool is developed to optimize system parameters of this tracking radar model. The optimization tool implements a Genetic Algorithm (GA) belonging to a GA Toolbox distributed by Department of Automatic Control and System Engineering at University of Sheffield. The thesis presents optimization results over some given optimization scenarios and concludes on effect of tracking filter parameters, beamwidth and dwell interval for the confirmed track.
43	Ray Tracing Algorithm for Dielectric Domes / Algoritm för strålföljning i dielektriska kupoler Pubill, Maria January 2023 (has links) Almost hemispherical scanning capabilities are required for modern wireless communication systems to produce broad coverage without performance degradation. Phased array antennas are commonly used as a fully-electronic beam-steering solution for its rapidity in beam switching. However, the effective aperture for high scanning angles is reduced, causing a reduction of the gain with the cosine of the elevation angle. Quasi-optical systems are used to achieve high directivity for wide scanning in combination with phased arrays. An interesting solution is the dielectric dome antenna, where rotationally symmetric dielectric lenses are used to enhance the scanning performance of an antenna with limited scanning capabilities. Using a full-wave simulator to evaluate lenses combined with arrays is very time-consuming, making the lens design inefficient and laborious. In this work is presented a Ray-Tracing tool used to simulate in a fast and efficient way the far-field of two-dimensional dielectric lenses. While a full-wave simulation of a three-dimensional lens could take approximately 3 hours, the Ray-Tracing evaluation takes less than 3 minutes, making possible the full optimization and design of these lenses. A numerical calculation of the ray path is used to evaluate the phase of the electric field at the lens aperture, while the amplitude is evaluated using ray-tube power theory. The far-field radiation pattern of the lens antenna is calculated using the Kirchhoff-Fresnel diffraction formula. In this work, it is also presented a full study of the reflection and absorption losses, which is something that was not previously done in the state of the art. Matching layers are designed and evaluated to reduce the reflection losses at each interface. To demonstrate the effectiveness of this approach, we compare the radiation patterns produced by a two-dimensional dielectric dome antenna with those computed using COMSOL, showing a significant reduction in time and computational resources. / För moderna trådlösa kommunikationssystem krävs nästan halvklotformiga skanningsmöjligheter för att åstadkomma bred täckning utan försämrad prestanda. Fasstyrda antenner används vanligen som en helt elektronisk lösning för strålstyrning på grund av dess snabbhet vid byte av strålar. Den effektiva aperturen för höga skanningsvinklar minskar dock, vilket leder till att förstärkningen minskar med cosinus av elevationsvinkeln. Kvasiooptiska system används för att uppnå hög riktningsförmåga för bred avsökning i kombination med fasade matriser. En intressant lösning är den dielektriska kupolantennen, där rotationssymmetriska dielektriska linser används för att förbättra skanningsegenskaperna hos en antenn med begränsad skanningskapacitet. Att använda en fullvågssimulator för att utvärdera linser i kombination med matriser är mycket tidskrävande, vilket gör linsdesignen ineffektiv och arbetskrävande. I detta arbete presenteras ett Ray-Tracing-verktyg som används för att på ett snabbt och effektivt sätt simulera fjärrfältet för tvådimensionella dielektriska linser. Medan en fullvågssimulering av en tredimensionell lins kan ta ungefär 3 timmar tar strålföljningssimuleringen mindre än 3 minuter, vilket gör det möjligt att optimera och konstruera dessa linser fullt ut. En numerisk beräkning av strålbanan används för att utvärdera fasen hos det elektriska fältet vid linsaperturen, medan amplituden utvärderas med hjälp av strålrörsteori. Linsantennens strålningsmönster i fjärrfältet beräknas med hjälp av Kirchhoff-Fresnel-diffraktionsformeln. I detta arbete presenteras också en fullständig studie av reflektions- och absorptionsförlusterna, vilket är något som inte tidigare har gjorts inom detta forskningsområde. Anpassningsskikt utformas och utvärderas för att minska reflektionsförlusterna vid varje gränssnitt. För att visa hur effektivt detta tillvägagångssätt är, jämför vi strålningsdiagrammen som produceras av en dielektrisk kupolantenn med dem som beräknats med COMSOL, vilket visar på en betydande minskning av beräkningsresurserna. Array antenna dielectric dome Ray-Tracing reflection absorption losses matching layers Arrayantenn dielektrisk kupol strålföljning reflektion absorptionsförluster anpassningsskikt Elektroteknik och elektronik
44	Design, Development, And Integration Of A Meso-scale Eletrostatic Phase Shifter On Microwave Laminate Lata, Poonam 03 1900 (has links) (PDF) Recent developments in the area of microfabrication technologies, has enabled the fabrication of many radio frequency/microwave components with better performance and lower cost than possible with semiconductor based fabrication technology. Many of these microfabricated RF components such as switches and phase shifters, popularly known as RF MEMS, are aimed at reducing the insertion loss and improving other performance parameters such as linearity. For these devices size miniaturization is not necessarily important, as in practical subsystems, these components are integrated with RF front-ends on a laminate. This thesis deals with concepts of a low cost passive phase shifter fabricated in-situ on a microwave laminate. The operation of this Mesoscale Electrostatically actuated Phase shifter on microwave Laminate (MEPL) is similar to that of a micromachined distributed MEMS transmission line (DMTL) phase shifter. In spite of advantages of low losses, wide bandwidth, low DC power consumption and high linearity over semiconductor/MMIC technology, microfabricated phase shifters are often not used in field because of issues related to fabrication reliability, packaging and integration. On the other hand, the proposed MEPL will have all the advantages of conventional MEMS phase shifters with additional benefit of lower cost. Furthermore, these are integrable to form a monolithic phased array. A MEPL phase shifter of 50-bridges periodically distributed on the co-planar waveguide (CPW) transmission line is demonstrated in this thesis. MEMS air bridges are electrostatically actuated to vary the capacitance of the transmission line, which changes the phase velocity of the propagation RF signal, consequently phase at the output port. The realized MEPL is characterized for electromagnetic as well as electromechanical performance. The electromechanical characterization of this device is performed using a Laser Doppler Vibrometer (LDV). The measured data showed good agreement with the analytical data.. Major application of a phase shifter is in a phased array antenna system. MEPL is particularly suited for a monolithic phase array antenna. The proposed monolithic phased array antenna system fabrication approach utilizes extremely simple and economical modern printed circuit board technology to pattern the conventional microwave laminate and copper foil. A complete monolithic phased array antenna system is fabricated on a microwave laminate using an embedded phase shifter operating with electrostatic principles. Other components such as DC block and bias tee are integrated into the CPW-microstrip transitions to optimize the space and performance. Integrated phased array antenna is fabricated and tested to demonstrate the beam steering capability. Measured S11 is better than -15dB at the operating frequency of 9.8GHz. The beam steering capability is shown as proof of concept by showing the beam scan angle of 10deg with bias voltage of 125V. The mesoscale phase shifter demonstrated in this thesis has several advantages compared to micromachined phase shifters. The proposed fabrication approach does not use metal deposition/patterning process, which removes the need of high cost clean room and sophisticated films deposition equipments. Secondly, as there are no thin films used, stiction is not expected on phase shifters fabricated with this approach. Since this approach uses thicker metal films, the power handling capability is expected to be significantly higher than micromachined phase shifters. Since conventional phased array antenna system components are fabricated on a microwave laminate, micro machined phase shifters realized on semiconductor substrates are required to be packaged separately before integrating with such phased array circuits. Packaging of the micro-machined RF-MEMS/MEMS devices is still a major issue and contributes to a substantial part of the total cost. Unlike micromachined phase shifters which are required to be packaged and then embedded in phased array applications, device presented in this thesis is packaged in-situ. Compared to similar monolithic phased array antenna reported on silicon substrate which are limited by wafer size, these arrays can be easily extended for larger arrays on microwave laminate as these are available in large size. To summarize, the proposed fabrication approach for phase shifters overcomes many limitations of micromachined components for microwave applications while retaining most of their advantages compared to other existing approaches based on ferrites or semiconductor technologies. Microwave Laminate MEMS Microelectronic Mechanical Systems Phase Shifters - Fabrication Phased Antenna Arrays Mesoscale Phase Shifter Phased Array Antenna Phase Shifter Electronic Engineering
45	Conception de circuits intégrés pour antenne à pointage électronique destinée aux télécommunications par satellite en bande Ka / Integrated circuit design for electronically steerable antenna targeted towards SATCOM applications in Ka - band Lohou, Anaël 19 December 2018 (has links) Dans un monde où l’information va de plus en plus vite, il est important de pouvoir rester connecté en permanence. De nouvelles solutions émergent pour connecter les passagers à bord d’un avion grâce aux communications par satellite. Parmi elles, on retrouve les antennes à pointage électronique dans lesquelles cette thèse de doctorat s’intègre. Une étude sur les différentes antennes existantes ou en projet est présentée. Les puces électroniques MMIC AsGa permettent d’appliquer des lois d’amplitude et de phase pour chaque élément rayonnant d’une antenne réseau. Cette thèse de doctorat porte sur la conception d’un déphaseur, après avoir étudié les technologies et les topologies de celui-ci. Ensuite, la conception d’un amplificateur faible bruit à gain variable est proposée à partir d’un état de l’art. Les résultats de simulation et de mesures de ces deux fonctions sont exposés. / In a world where the information is moving faster and faster, it is important to be able to stay connected continuously. Some new solutions for air transport connectivity are in development thanks to the rise of satellite communications. This thesis work is part of an electronically steerable antenna array project, developed as a solution to achieve In-Flight Connectivity in Ka-band. A state- of-the art review on electronically steerable antenna arrays is also presented. In these arrays, each radiating element needs a specific amplitude and phase to obtain a scanning beam by adding their contribution. This thesis focus on the design of a GaAs MMIC chip inclusion two functions: a phase shifter and a variable-gain low-noise amplifier. The simulation and measurement results are presented for these two functions. Amplificateur faible bruit Déphaseur Technologie MMIC AsGa Bande Ka Connectivité en Vol Low noise amplifier Phase shifter GaAs MMIC technology Phased array antenna Ka-band In-flight connectivity 621.381
46	Measurements, Estimations and Calibration with a Fully Digital Array Magnér, Oscar January 2023 (has links) In modern digital communication, transmission and reception of information through electromagnetic signals requires digital devices that can process high data rates accurately despite being located in information heavy environments. One type of antenna receiver is the digital antenna array, which can steer its lobes electronically to increase or decrease sensitivity in specific directions. A rather recently developed system is the Wideband Digital Array Receiver, developed at Saab Surveillance in Järfälla and referred to as WiDAR. The implementations and possibilities of WiDAR are broad, but no matter its future applications, calibration is an essential feature to ensure truthful reception of data. Any type of electronic system risks errors due to hardware imperfections. The aim of this thesis is to explore and reduce these errors. Measurements with WiDAR were performed in a manner such that some of the intercepted signals were transmitted from a far away located FM and TV-mast. The data was then used to retrieve weights by calculating their relative transfer function, which were applied to calibrate all channels in the antenna array towards a chosen reference channel. These weights could then be on any accumulated set of data measured by WiDAR with hopes to compensate errors in both phase and magnitude. The results show that reducing errors this way was possible, working slightly better when calibrating phase than calibrating magnitude. If more advanced calibration is deemed necessary, further measurements could be performed to investigate where errors or variations occur by isolating different parts of the system. The calibration method used could be further developed by adding an online calibration procedure, meaning relative transfer functions are calculated in real time when performing measurements. WiDAR signal processing digital array broadband antenna array antenna antenna calibration direct sampling antenn bredbandig digital array array antenn direktsampling signalbehandling kalibrering WiDAR Saab AB SAAB Signal Processing Signalbehandling
47	Antenna Options for High Altitude IMT Base Stations (HIBS) in Cellular Networks Magnusson, Harald January 2022 (has links) This thesis is the result of a collaboration between Ericsson AB and Luleå University of Technology. A feasibility study has been conducted to investigate antenna options for the HIBS access link. The study contains two parts. Firstly, a link budget investigating the gain required from the antenna. The metric of concern in the link budget was SNR. Secondly, a wide area coverage investigation that explored coverage feasibility over an area with a radius of 100 km. The metrics of concern in this investigation were antenna gain and beamwidth. Two types of antennas have been included: parabolic reflector and phased array. Seven frequency bands have been studied: 0.7, 1.9, 2.7, 3.5, 6, 10, and 26 GHz. The first three bands shared a bandwidth of 20 MHz, the next three shared a bandwidth of 80 MHz, and the last band had a bandwidth of 100 MHz. This bandwidth difference was found to have a meaningful effect on SNR. The feasibility condition for the link budget was -6 dB SNR for uplink and 6 dB SNR for downlink. The link budget concluded that the first three bands (0.7, 1.9, and 2.7 GHz) are feasible with reasonably sized antennas. This meant a parabolic reflector dish diameter of 0.6 m for all three bands, or a phased array antenna with 4, 32, and 64 elements, respectively, that all resulted in a roughly equal physical size of the array. The 3.5 GHz frequency band was found to be feasible with a much larger antenna (512 element array). The bands above 3.5 GHz were not deemed feasible. The wide area investigation limited the antenna to a phased array antenna. Two cell layouts were considered for coverage: a 7 cell layout with one nadir cell surrounded by 6 cells and a 19 cell layout which encapsulates the former with another layer of 12 cells. The feasibility condition was that the half power beamwidth is equal to the angular size of a cell from the HIBS for each cell layer while maintaining gain. Beamwidth was controlled through array tapering and altering element configurations. This investigation concluded that coverage is feasible for two bands. In the 0.7 GHz band, the chosen option was a 7 cell layout using a single element antenna for the nadir cell and 3 by 1 arrays for the outer cells. In the 1.9 GHz band, the chosen option was a 19 cell layout with a single element antenna for the nadir cell, 5 by 1 arrays for the cells in the middle layer, and 8 by 5 arrays for the outer layer. Higher frequency bands required higher gain antennas which in turn did not provide adequate beamwidth for coverage. High altitude IMT Base Station (HIBS) High Altitude Platform Station (HAPS) Link Feasibility Coverage Feasibility Phased Array Antenna Parabolic Reflector Antenna Engineering and Technology Teknik och teknologier Aerospace Engineering Rymd- och flygteknik
48	Scann Loss Reduction on Phased Array Antenna / Scan Loss Reduction på Phased Array Antenn Zhang, Wanyu January 2022 (has links) Phased array antennas with small size and light weight are proposed to make signal transmitting more efficiently and accurately. These antennas have such advantages that they can realize beam scanning over a large range, accurately track and identify targets within the observation range. In beam scanning, the scan loss which is the difference between the scanned gain and broadside gain has a great impact on the performance of phased array antennas. This thesis aims to study how to reduce the scan loss while the beam is scanned over a wide range. One of the methods to reduce the scan loss is to widen the beam-width of the embedded radiation pattern. With the wide beam-width, the gain reduction due to beam scanning would be small. We propose a method to replace a conventional half-wavelength unit-cell in an array with a sub-array composed of 5 miniaturized elements with special phase/amplitude distribution. The size of the sub-array is finely tuned in this thesis to achieve the goal of wide beam-width without any grating lobe. Then, in order to further expand the beam-width, the ideal power divider is utilized to apply specific weight to the sub-array. The simulation result shows that the maximum scan loss for the considered case is 3.67dB over ±80° scan range with an voltage amplitude distribution of [0.234, 0.64, 0.26, 0.64, 0.234] (1) and a phase of 88° between the 5 sub-array elements, which can be realized by the ideal power divider. If the allowed gain reduction is relaxed to 5dB, the scan coverage can be extended to ±89°. / Fasstyrda antenner med eu liten storlek och låg vikt har förslegits för att göra signalöverföring effektivt och korrekt. Dessa antenner har stora fördelar i att de kan realisera stort område. De kan också följa och identifiera mål inom observationsområdet. Vid strålskanning är skanningsförlusten, som är skillnaden mellan den skannade förstärkningen och förstärkningen vid den breda sidan, följande har stor inverkan på prestandan hos fasstyrda antenner. Denna avhandling syftar till att studera hur man minskar skanningsförlusten när strålen skannar inom ett brett skanningsområde. En av metoderna för att minska skanningsförlusten är att bredda strålbredden i det inbyggda strålningsmönstret. Med en bred strålbredd blir förstärkningsminskningen på grund av strålskanning liten. Vi föreslår en metod för att ersätta en konventionell halvvågig enhetscell i en matris med en delmatris som består av 5 miniatyriserade element med speciell fas/amplitudfördelning. Storleken på delarrayen är finjusterad i denna avhandling för att uppnå målet med bred strålbredd utan någon gitterlob. För att ytterligare utöka strålbredden används sedan den ideala effektdelaren för att ge subarrayet en särskild vikt. Simuleringsresultatet visar att den maximala skanningsförlusten för det undersökta fallet är 3,67dB inom ±80° täckningsvinkel med amplitudfördelning av [0.234, 0.64, 0.26, 0.64, 0.234] (2) och fas av 88°, som kan realiseras av den idealiska effektdelaren. Om kravet på minskningen av förstårluing sänks till 5dB, kan täckningen breddas till ±89°. Phased Array Antenna Vivaldi Antenna Scan Loss Coverage Angle Sub-array Embedded Radiation Pattern Fasad Array Antenn Vivaldi Antenn Skanningsförlust Täckningsvinkel Sub-array Inbyggt strålmönster Elektroteknik och elektronik
49	Design of an Array of Patch-elements With a Band-pass Frequency Selective Surface Hybrid Radome : Analysis and characterisation of a frequency selective surface and a phased array antenna / Design av en fasstyrd gruppantenn med en bandpass frekvensselektiv yta hybrid radom : Analys och karaktärisering av en frevensselektiv yta och en fasstyrd gruppantenn Normark Frisk, Curt-Herman January 2022 (has links) A circular polarised phased array antenna and a frequency selective hybrid radome are designed and evaluated. The antenna system is well suited as a part of a communication link between platforms with a 600 MHz bandwidth and a centre frequency of 5 GHz. A prototype consisting of 8 x 8 patch elements has been designed, manufactured and characterised. The final configuration will be a compact, relatively inexpensive system with single-fed antenna elements. An array antenna with circular polarisation is suitable when the receiver must maintain a strong signal regardless of the relative antenna orientation. The radome protects the antenna and can also reduce both the radar cross section and interference from out-of-band signals. The main focus is to make sure that the phased array antenna and the radome work as one unit and maximise the field of view in which the polarisation is circular. The method to maximise the field of view is to reduce the coupling between antenna elements by using shorting via fences surrounding each element. Following this method results in a total array gain of 18 dBi, 25° half-power beamwidth and a ±35° maximum scan angle with maintained circular polarisation. Prototype measurements agree well with the simulated results. / En cirkulärpolariserad fasstyrd gruppantenn samt en frekvensselektiv hybrid-radom har designats och utvärderats. Antennsystemet lämpar sig väl som en kommunikationslänk mellan plattformar med en 600 MHz bandbredd och centerfrekvens 5 GHz. En prototyp besåtende av 8 × 8 patchelement har designats, tillverkats och karaktäriserats. Den slutgiltiga konfigurationen resulterade i ett kompakt och relativt billigt system med single-matade antennelement. En gruppantenn med cirkulär polarisation är lämplig när mottagaren måste bibehålla en stark signal oavsett antennens relativa orientering. Radomen skyddar antennen från väder och vind och kan även minska både radarmålsarean och störningar från utombandiga signaler. Huvudfokus är att se till att den fasstyrda gruppantennen och radomen fungerar som en enhet och maximerar scan-området i vilket polarisationen är cirkulär. Metoden för att maximera detta område är att minska kopplingen mellan antennelementen genom att använda ett kortslutande viastaket som omsluter varje element. Metoden resulterar i totalt 18 dBi array gain, 25° half-power beamwidth och en maximal utstyrningsvinkel på ±35° med bibehållen cirkulär polarisation. Prototypens mätresultat stämmer väl överens med simulationsresultaten. Frequency Selective Surface Microstrip Patch Element Circular Polarisation Phased Array Antenna Single Feed Frekvensselektiv Yta Mikrostrip Patchelement Cirkulär Polarisering Fasstyrd Gruppantenn Single-matad Elektroteknik och elektronik
50	Ray-Tracing Modeling of Grating Lobe Level Reduction by Using a Dielectric Dome Antenna / Strål-Spårnings-Modellering av Sänkning av Gallerlobsnivå Genom att Använda en Dielektrisk Kupolantenn Jonasson, Lukas January 2023 (has links) With the newly deployed fifth-generation telecommunications system and upcoming sixth-generation, high-gain antennas with hemispherical scanning capabilities are of high interest. Phased array antennas allow for fast scanning capabilities with electronic beam-steering. In an effort to reduce the number of antenna elements while maintaining the antenna aperture size, the element spacing is increased. However sparse arrays introduce grating lobes in the radiation pattern. An interesting solution to reduce the grating lobes is to integrate a lens with the array. Further, simulating the radiation pattern with a ray-tracing algorithm and the geometrical optics approximation makes for fast simulation times. The presented ray-tracing algorithm in this work speeds up the simulation by 43 times compared to a two-dimensional full-wave simulation. To model the full radiation pattern the rays are shot out from a single point across a set angular space. To emulate an element pattern the rays are excited with a set amplitude distribution. Here, two different methods of obtaining the amplitude are presented and compared to a two-dimensional full-wave COMSOL model. The lens is made from a dielectric, constructed from the conics equation with applied conformal matching layers. The ray path and phase distribution are calculated with Snell's law, the amplitude distribution at the lens aperture is calculated through the ray tube theory, and the radiation pattern with the Kirchhoff Diffraction formula. To optimize the lens shape and an array offset, the ray-tracing algorithm is coupled with a Particle Swarm Optimization algorithm. Two different arrays are used in this thesis, the first constructed from open-ended waveguides and the second using sub-arrays of the same waveguides. The optimized lens for the first array shows that a grating lobe suppression between 1.1-2.0 dB is achievable with a main lobe reduction between 0.2-0.3 dB for scanning to -20 degrees. For the array with sub-arrays, the main lobe suppression is between 0.3-0.9 dB, with a grating lobe suppression of up to 4.0 dB. / Med det nyligen lanserade femte generationens telekommunikationssystem och den kommande sjätte generationen är högförstärkningsantenner med halvsfäriska skanningsmöjligheter av stort intresse. Fasade array-antenner möjliggör snabb skanningskapacitet med elektronisk strålstyrning. I ett försök att minska antalet antennelement samtidigt som antennöppningens storlek bibehålls, ökas elementavståndet. Men glesa arrayer introducerar gallerlober i strålningsmönstret. En intressant lösning för att minska gallerloberna är att integrera en lins med arrayen. Vidare, simulering av strålningsmönstret med en strålspårningsalgoritm och den geometriska optiska approximationen ger snabba simuleringstider. Den presenterade strålspårningsalgoritmen i detta arbete snabbar upp simuleringen med 43 gånger jämfört med en tvådimensionell helvågssimulering. För att modellera hela strålningsmönstret skjuts strålarna ut från en enda punkt över ett fast vinkelutrymme. För att efterlikna ett elementmönster exciteras strålarna med en inställd amplitudfördelning. Här presenteras två olika metoder för att erhålla amplituden och jämförs med en tvådimensionell fullvågs-COMSOL-modell. Linsen är gjord av ett dielektrika konstruerat från koniska ekvationen med applicerade konforma matchande lager. Strålvägen och fasfördelningen beräknas med Snell-lagen, amplitudfördelningen vid linsöppningen beräknas genom strålrörsteorin och strålningsmönstret med Kirchhoff-diffraktionsformeln. För att optimera linsformen och en arrayförskjutning är strålspårningsalgoritmen kopplad med en Particle Swarm algoritm. Två olika arrayer används i denna avhandling, den första konstruerad av vågledare med öppen ände och den andra med hjälp av sub-arrayer av samma vågledare. Den optimerade linsen för den första arrayen visar att en gallerlobsundertryckning mellan 1,1-2,0 dB kan uppnås med en huvudlobsreduktion mellan 0,2-0,3 dB för skanning till -20 grader. För arrayen med sub-arrayer är undertryckningen av huvudloben mellan 0,3-0,9 dB, med en gallerlobundertryckning på upp till 4,0 dB. Array antenna Dielectric dome Ray-Tracing Grating lobe Particle Swarm optimization Gruppantenn Dielektrisk kupol Strålspårning Gallerlob Particle Swarm optimering Computer Sciences Datavetenskap (datalogi) Computer Engineering Datorteknik Elektroteknik och elektronik

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