Optimised Ray Tracing for the SuperNEC Implementation of the Uniform Theory of Diffraction

Hartleb, Robert

26 February 2007

Student Number : 0006329K - MSc(Eng) Dissertation - School of Electrical and Information Engineering - Faculty of Engineering and the Built Environment / Geometric optimisations are presented for the UTD in SuperNEC which is a commercial electromagnetic software package. Path finding optimisations rapidly find propagation paths of electromagnetic waves by using back face culling to determine the visible plates of polyhedral structures and by using reflection and diffraction zones which use image theory and the law of diffraction to determine illuminated spatial regions. An octree reduces the number of intersections during the shadow tests. Numerical results show that overall the optimisations halve the run time of the software for models which consist of plates and cylinders. The path finding optimisations do not scale with model size, are limited to plates and introduce errors. The mean absolute error due to the path finding optimisations is on average 0:02 dB for first order rays and 0:17 dB for second order rays. The octree optimisation scales with model size, can be used with any geometry and any type of ray and does not cause errors.

uniform theory of diffraction

geometrical optimisations

ray tracing

Hybrid methods for computational electromagnetics in the frequency domain

Hagdahl, Stefan

January 2003

<p>In this thesis we study hybrid numerical methods to be usedin computational electromagnetics. We restrict the methods tospectral domain and scattering problems. The hybrids consist ofcombinations of Boundary Element Methods and Geometrical Theoryof Diffraction.</p><p>In the thesis three hybrid methods will be presented. Onemethod has been developped from a theoretical idea to anindustrial code. The two other methods will be presented mainlyfrom a theoretical perspective. We will also give shortintroductions to the Boundary Element Method and theGeometrical Theory of Diffraction from a theoretical andimplementational point of view.</p><p><b>Keywords:</b>Maxwell’s equations, Geometrical Theoryof Diffraction, Boundary Element Method, Hybrid methods,Electromagnetic Scattering</p>

Computational Electromagnetics

Hybrid Methods

Boundary Element Method

Geometrical Theory of Diffraction

Hybrid methods for computational electromagnetics in the frequency domain

Hagdahl, Stefan

January 2003

In this thesis we study hybrid numerical methods to be usedin computational electromagnetics. We restrict the methods tospectral domain and scattering problems. The hybrids consist ofcombinations of Boundary Element Methods and Geometrical Theoryof Diffraction. In the thesis three hybrid methods will be presented. Onemethod has been developped from a theoretical idea to anindustrial code. The two other methods will be presented mainlyfrom a theoretical perspective. We will also give shortintroductions to the Boundary Element Method and theGeometrical Theory of Diffraction from a theoretical andimplementational point of view. <b>Keywords:</b>Maxwell’s equations, Geometrical Theoryof Diffraction, Boundary Element Method, Hybrid methods,Electromagnetic Scattering / NR 20140805

Computational Electromagnetics

Hybrid Methods

Boundary Element Method

Geometrical Theory of Diffraction

A Uniform Geometrical Theory of Diffraction Model of Very-High-Frequency Omni-directional Range Systems for Improved Accuracy

Yellu, Augustine D.

26 September 2013

No description available.

Electromagnetics

Electrical Engineering

Omnirange

Doppler VOR

VOR

[en] SCANNING OF GREGORIAN OFF-SET ANTENNAS BY DISPLACEMENT OF FEEDER / [pt] VARREDURA DE ANTENAS GREGORIANAS OFF-SET POR DESLOCAMENTOS DO ALIMENTADOR

HELIO FRANCISCO DA SILVA

03 January 2007

[pt] Este trabalho tem por objetivo um estudo da viabilidade de se fazer varreduras com uma antena gregoriana off-set com deslocamentos apenas do alimentador. São localizadas as regiões focais para a antena receptora de modo a posicionar o alimentador de uma maneira simples. Também são apresentados os diagramas de radiação correspondentes a estes deslocamentos calculados segundo a Teoria Escalar da Difração; e as limitações de varreduras para a antena particular que serviu para testar a eficiência do método. / [en] This work is related to the study of the pattern of Gregorian off-set antennas, by displacement of the feeder. The position of the feeder is obtained, in a simple way, by determining the focal regions of the antennas, working in reception. The radiation patterns corresponding to different position of the feeder are also presented. Such patterns are calculated according to the scalar theory of diffraction. The useful range of scanning, for a given antenna, used to check the efficiency of the method, is determined.

[pt] ANTENA GREGORIANA OFF-SET

[pt] TEORIA ESCALAR DA DIFRACAO

[en] GREGORIAN OFF-SET ANTENNAS

[en] SCALAR THEORY OF DIFFRACTION

Evaluation of a terrain-sensitive, propagation path loss model based upon the geometrical theory of diffraction, modified for finite conductivity and local surface roughness

Ma, Richard

January 1983

No description available.

Terrain-Sensitive

Propagation Path Loss Model

Geometrical Theory of Diffraction

Finite Conductivity

local surface roughness

A UTD ray description for the collective fields radiated by large antenna phased arrays on a smooth convex surface

Janpugdee, Panuwat

12 September 2006

No description available.

conformal antenna phased arrays

asymptotic high-frequency ray solution

Hybrid Methods for Computational Electromagnetics in Frequency Domain

Hagdahl, Stefan

January 2005

<p>In this thesis we study hybrid numerical methods to be used in computational electromagnetics. The purpose is to address a wide frequency range relative to a given geometry. We also focus on efficient and robust numerical algorithms for computing the so called Smooth Surface Diffraction predicted by Geometrical Theory of Diffraction (GTD). We restrict the presentation to frequency domain scattering problems.</p><p>The hybrid methods consist in combinations of Boundary Element Methods and asymptotic methods. Three hybrids will be presented. One of them has been developed from a theoretical idea to an industrial code. The two other hybrids will be presented mainly from a theoretical perspective.</p><p>To be able to compute the Smooth Surface Diffracted field we introduce a numerical method that is to be used with surface curvature sensitive meshing, complemented with auxiliary data taken from a geometry database. By using two geometry representations we can show first order convergence and we then achieve an efficient and robust numerical algorithm. This numerical algorithm may be an essential part of an GTD implementation which in its turn is a component in the hybrid methods.</p><p>As a background to our new techiniques we will also give short introductions to the Boundary Element Method and the Geometrical Theory of Diffraction from a theoretical and implementational point of view.</p>

Maxwell's equations

Geometrical Theory of Diffraction

Smooth Surface Diffraction

Boundary Element Method

Hybrid methods

Electromagnetic Scattering

Numerical analysis

Numerisk analys

Hybrid Methods for Computational Electromagnetics in Frequency Domain

Hagdahl, Stefan

January 2005

In this thesis we study hybrid numerical methods to be used in computational electromagnetics. The purpose is to address a wide frequency range relative to a given geometry. We also focus on efficient and robust numerical algorithms for computing the so called Smooth Surface Diffraction predicted by Geometrical Theory of Diffraction (GTD). We restrict the presentation to frequency domain scattering problems. The hybrid methods consist in combinations of Boundary Element Methods and asymptotic methods. Three hybrids will be presented. One of them has been developed from a theoretical idea to an industrial code. The two other hybrids will be presented mainly from a theoretical perspective. To be able to compute the Smooth Surface Diffracted field we introduce a numerical method that is to be used with surface curvature sensitive meshing, complemented with auxiliary data taken from a geometry database. By using two geometry representations we can show first order convergence and we then achieve an efficient and robust numerical algorithm. This numerical algorithm may be an essential part of an GTD implementation which in its turn is a component in the hybrid methods. As a background to our new techiniques we will also give short introductions to the Boundary Element Method and the Geometrical Theory of Diffraction from a theoretical and implementational point of view.

Maxwell's equations

Geometrical Theory of Diffraction

Smooth Surface Diffraction

Boundary Element Method

Hybrid methods

Electromagnetic Scattering

Numerical analysis

Numerisk analys

Computational electromagnetics : software development and high frequency modeling of surface currents on perfect conductors

Sefi, Sandy

January 2005

In high frequency computational electromagnetics, rigorous numerical methods be come unrealistic tools due to computational demand increasing with the frequency. Instead approximations to the solutions of the Maxwell equations can be employed to evaluate th electromagnetic fields. In this thesis, we present the implementations of three high frequency approximat methods. The first two, namely the Geometrical Theory of Diffraction (GTD) and th Physical Optics (PO), are commonly used approximations. The third is a new invention that will be referred to as the Surface Current Extraction-Extrapolation (SCEE). Specifically, the GTD solver is a flexible and modular software package which use Non-Uniform Rational B-spline (NURBS) surfaces to model complex geometries. The PO solver is based on a triangular description of the surfaces and includes fas shadowing by ray tracing as well as contribution from edges to the scattered fields. GTD ray tracing was combined with the PO solver by a well thought-out software architecture Both implementations are now part of the GEMS software suite, the General ElectroMag netic Solvers, which incorporates state-of-the-art numerical methods. During validations both GTD and PO techniques turned out not to be accurate enough to meet the indus trial standards, thus creating the need for a new fast approximate method providing bette control of the approximations. In the SCEE approach, we construct high frequency approximate surface currents ex trapolated from rigourous Method of Moments (MoM) models at lower frequency. T do so, the low frequency currents are projected onto special basis vectors defined on th surface relative to the direction of the incident magnetic field. In such configuration, w observe that each component displays systematic spatial patterns evolving over frequenc in close correlation with the incident magnetic field, thus allowing us to formulate a fre quency model for each component. This new approach is fast, provides good control of th error and represents a platform for future development of high frequency approximations. As an application, we have used these tools to analyse the radar detectability of a new marine distress signaling device. The device, called "Rescue-Wing", works as an inflatabl radar reflector designed to provide a strong radar echo useful for detection and positionin during rescue operations of persons missing at sea. / QC 20101004

High frequency approximations

Maxwell’s equations

Method of Moments

Physical Optics

Geometrical Theory of Diffraction

Extraction Extrapolation

Numerical analysis

Numerisk analys