A portable picocell antenna for 5G

Danelys Rodríguez Avila
EPFL, 2021
Thèse EPFL

Résumé

Deployable emergency communication systems are a backbone solution for replacing damaged network infrastructures and/or providing high-end services in case of an emergency event. It is important that such systems are up-to-date with the latest mobile network technology, for enabling connectivity to users and profiting from its enhanced capabilities. The advent of 5G promises higher data rates, lower latencies and improved quality of services when compared to previous generations. To achieve that, mm-Waves have been identified as a key element due to the wide available spectrum. The implementation of deployable emergency communication systems compatible with 5G mm-Waves technologies, thus benefiting from its prospective advantages, is of great interest. This thesis focuses on 5G mm-Waves antenna design for this kind of applications. The high network capacity demand, the unfavourable channel conditions at mm-Waves and the still underdeveloped related radio frequency (RF) technology define a group of challenging requirements on the antenna design. While directive antennas are required to mitigate the attenuation with distance at these bands, omnidirectional coverage still needs to be provided. In addition, wide bandwidth operation, high efficiency, and low cost and power consumption are desired. In this context, antennas with multibeam forming capabilities have been widely acknowledged as a key enabling technology to support 5G wireless communications, representing an attractive solution to provide omnidirectional coverage while supporting Multiple Input Multiple Output (MIMO) techniques.

In this thesis, the design and implementation of a broadband efficient multibeam antenna for a portable picocell station are investigated. The picocell scenario in the context of emergency communications is studied and the antenna link budget is calculated considering mm-Waves propagation properties and available information on the upcoming standard. This leads to the definition of the design requirements and a preliminary antenna architecture that consists of an MxN antenna fed by a hybrid beamforming network (HBFN). This architecture is a promising approach for making multibeam antennas cost- and energy-efficient according to the latest research. The synthesis of the HBFN was realized considering the design constraints in elevation and azimuth such that the subarray, fed by an analog beamforming network, provides a csc2 pattern shape in elevation while M subarrays are controlled by a digital beamforming network to generate multiple orthogonal beams in azimuth. The antenna subarray was designed, fabricated and measured. Based on this, a study of the antenna array beamsteering capabilities in azimuth was carried out. After investigating the main parameters involved in improving its performance, the subarray design was optimized accordingly. The proposed antenna consists in a 12x6 array that works at 26 GHz with an impedance bandwidth higher than 12%. The radiation pattern shape in elevation is preserved over 7.3% of bandwidth. The antenna gain is superior to 10 dBi along the band of interest with a maximum value of 15 dBi. Simulated and measured results were compared, and the antenna beamsteering performance was tested for different sets of constraints indicating promising capabilities for a wide range of deployment scenarios. The proposed and validated design meets the requirements of the targeted applications on a practical low-profile implementation.

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https://infoscience.epfl.ch/record/286797?ln=fr

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Danelys Rodríguez Avila
EPFL, 2021
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/286797?ln=fr

À propos de ce résultat

Concepts associés (18)

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Publications associées (23)

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This paper addresses the design of an antenna array for a portable picocell station with omnidirectional coverage. The proposed solution includes a stacked patch antenna as a single radiating element of the antenna array and a hybrid beamforming network. The antenna element works at 26 GHz with a bandwidth of 20% and a gain of approximately 8.5 dB along the operational bandwidth. The antenna is fed by a suspended stripline transitioned from a waveguide. This antenna element is used to compute a 5x12-element antenna array fed by the hybrid beamforming network. Results are analytically obtained for a fixed analog beamforming network that generates a csc squared pattern shape in elevation. Additionally, a digital beamforming network is computed to perform beamsteering for a desired set of constraints in the azimuth plane. Simulated results of the complete system yield promising insights on the capacity of the proposed design to provide omnidirectional coverage.

IEEE2019

Chargement

3D analysis and optimization of microwave circuits by the method of moments

Francisco Jesus Nunez

The design and minaturization of microwave circuits involves the analysis and optimization of a large varity of structures, which, in general, are based on arbritrary objects embedded in also arbritary media. The most common situation is found when optimizing terminal antennas, whose main constraint is the antenna's volume, which must be fitted into a specified space, which in general is the phone or laptop case. This kind of antennas can also include stratified media, oblique metallizations, dielectric objects, waveguide components, in their definition making their analysis more difficult from the numeric point of view. The complete treatment of this kind of problems has been performed traditionally using Finite Differences or Finite Elements software, while it is more rare to find Method of Moments implementations for the solution of this kind of general problems. The Method of Moments has a certain number of advantages as the inclusion of radiation conditions or stratified media in the Green's function of the problem. Due to this it is possible to mesh only the surfaces or boundary conditions that are not included in the Green's function definition, obtaining, for instance, a more natural radiation boundary condition compared to other fullwave methods. The other big concern is the optimization of this kind of structures. In general the structures we are dealing with in this work can have very irregular shapes, in order to fit within the required volume constraints. The traditional optimizations techniques based on the gradient or conjugated gradient are not efficient when optimizing functions containning multiple minima and a large search space, which is the case in the optimization of terminal antennas. When miniaturizing terminal antennas or just a simple microstrip filter, the number of unknowns can be very large, and the different optimization variables can vary within wide limits in the search space. In this situation the Genetic Algorithms are ideal for seeking the global optimum solution of our problem. This work covers the analysis and optimization of microwave circuits, including antennas and filters in microstrip and waveguide technologies, paying more attention to the implementation of the Method of Moments (MoM) in conjugation with the Mixed Potential Integral Equation (MPIE) and Electric/Magnetic Field Integral Equation (EFIE/MFIE). The work has been split into 3 main goals: The analysis of 3 dimensional structures in stratified media, including arbritary shaped dielectric bodies using the Method of Moments, (MPIE,EFIE,MFIE). The analysis of shielded environments and more precisely the analysis of retangular waveguide cavities with the Method of Moments. The implementation of several optimization techniques, emcompassed in the frame of genetic algorithms, for the design and miniaturization of terminal antennas and microstrip filters. Some relevant examples linked to the efficiency and accuracy of the different methods and techiques explained in this work are included in each chapter, yielding to practical results suitable to be used in real life design problems. The main contributions of this work can be summarized as follows: In Chapter 2 we have developed the interpolation of 3D Green's function to the general solution of dielectric objects embedded in multilayered media. The interpolation method itself is preceeded by a spectral extraction of the quasi-static terms. This technique, very often applied in complex images techniques, has been applied to our specific Green's function problem yielding very good results in terms of accuracy and Green's function computation time. Another contribution, also emcompassed in Chapter 2, is the integration of the static part of the field dyadic G̿EM, performed by splitting the field dyadic into TM and TE components, allowing then an analytical integration of the dyadic terms in stratified media. In the frame of shielded environments in Chapter 3, the most important contribution is the extension of Ewald's acceleration technique to full electric and magnetic problems, allowing the acceleration of the field dyadic G̿EM and thus permit the extension of the MoM to the simulation of arbritary metallic shapes coupled to apertures through Ewald's approach. In Chapter 4 the most important contribution is the implementation of a Bayesian optimiser based on the estimation of probability made by dependencies trees. The dependency tree based method found in [1] and later in [2] has been adapted to the terminal antenna miniaturization yielding to excellent results in optimisation time and quality of the solution provided by the optimiser. Our implementation of the dependency tree method was found to be better than the traditional method used in this kind of problems. Chapter 4 contains also an implementation of the growing cells method presented in [3] for the specific problem of optimising pseudo periodic structures, like microwave filters, yielding to a powerful interpolating method which accelerates the optimisation process of microwaves devices whose fitness response is very time consuming.

EPFL2006

Chargement

Effect of intelligent antennas on radio system planning and on mitigation

Juliane Iten Chaves Simoes

Smart antennas have been recently applied to improve the capacity and the performance of second generation wireless mobile communication systems. In general, smart antennas reduce the effects of multipath fading and improve the signal-to-noise-plus-interference ratio (SNIR). Additional advantages such as channel capacity increase in urban areas, coverage extension in urban areas and spectrum efficiency in general can be obtained with the aid of smart antennas at the base station. Drawbacks are the cost, and both hardware and software complexity. Smart antennas promise a clear advantage in multi-service traffic scenario in comparison with non-adaptive antenna techniques. It is generally accepted that the adaptive antennas technique will be a key enable for the success of the European third generation mobile communication system known as Universal Mobile Telecommunication System (UMTS). The first part of this thesis presents two types of smart antenna systems: switched beam antennas and adaptive arrays. It introduces statistical models for them and investigates the performance measures of cellular radio systems with and without smart antennas deployed at base stations. Employing Monte-Carlo methodology, a tool has been developed to analyze the interference between two different systems that share the same geographical area and have neighboring frequency channels. The statistical smart antennas model has been used to verify the mitigation of the interference compared with others antennas used at the base station. These simulations have been done for TDMA, FDMA and CDMA systems. Wireless communication operating at different frequencies on the non-ionizing radiation (NIR) region of the electromagnetic spectrum has greatly increased in the last few decades, with important benefits for the population. These include mobile communication, such as cellular telephone systems. However, the radiated electromagnetic field levels increased substantially in areas where people may stay during long periods each day. This may result in long-term exposure to the population. International guidelines and standards were developed aiming at protecting the population, and limiting the maximum radiation produced. The methods used by regulation authorities to evaluate the field levels at places of sensitive use yield very conservative results. They need thus to be refined prior to the introduction of adaptive antennas. In the second part of the thesis, a 3D ray tracing tool is developed to predict the propagation for real scenarios using UMTS systems. This tool takes into account 3D radiation diagrams and multipath propagation. It was used in real scenarios to compare the real field levels with the levels obtained by the approximate methods defined by the regulation standards. Finally, this tool was used to predict the field levels in a scenario containing smart antennas. Scenario not foreseen in the method described in the standards.

EPFL2008

Chargement

3D analysis and optimization of microwave circuits by the method of moments

Francisco Jesus Nunez

EPFL2006

Effect of intelligent antennas on radio system planning and on mitigation

Juliane Iten Chaves Simoes

EPFL2008