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Transcript
EEE 431 Computational methods in Electrodynamics Lecture 1 By Rasime Uyguroglu Science knows no country because knowledge belongs to humanity and is the torch which illuminates the world. Louis Pasteur Methods Used in Solving Field Problems Experimental methods Analytical Methods Numerical Methods Experimental Methods Expensive Time Consuming Sometimes hazardous Not flexible in parameter variation Analytical Methods Exact solutions Difficult to Solve Simple canonical problems Simple materials and Geometries Numerical Methods Approximate Solutions Involves analytical simplification to the point where it is easy to apply it Complex Real-Life Problems Complex Materials and Geometries Applications In Electromagnetics Design of Antennas and Circuits Simulation of Electromagnetic Scattering and Diffraction Problems Simulation of Biological Effects (SAR: Specific Absorption Rate) Physical Understanding and Education Most Commonly methods used in EM Analytical Methods Separation of Variables Integral Solutions, e.g. Laplace Transforms Most Commonly methods used in EM Numerical Methods Finite Difference Methods Finite Difference Time Domain Method Method of Moments Finite Element Method Method of Lines Transmission Line Modeling Numerical Methods (Cont.) Above Numerical methods are applied to problems other than EM problems. i.e. fluid mechanics, heat transfer and acoustics. The numerical approach has the advantage of allowing the work to be done by operators without a knowledge of high level of mathematics or physics. Review of Electromagnetic Theory Notations E: Electric field intensity (V/ m) H: Magnetic field intensity (A/ m) D: Electric flux density (C/ m2 ) B: Magnetic flux density (Weber/ m2 ) J: Electric current density (A/ m2 ) Jc :Conduction electric current density (A/ m2 ) Jd :Displacement electric current density(A/m2) :Volume charge density (C/m3) Historical Background Gauss’s law for electric fields: .D Gauss’s law for magnetic fields: .B 0 Historical Background (cont.) Ampere’s Law Faraday’s law D XH J t B XE t Electrostatic Fields Electric field intensity is a conservative field: XE 0 Gauss’s Law: .D * Electrostatic Fields Electrostatic fields satisfy: XE 0 or E.dl 0 Electric field intensity and electric flux density vectors are related as: D E ** The permittivity is in (F/m) and it is denoted as Electrostatic Potential In terms of the electric potential V in volts, E V *** Or V E .dl Poisson’s and Laplace’s Equation’s Combining Equations *, ** and *** Poisson’s Equation: v V 2 When v 0, Laplace’s Equation: V 0 2 Magnetostatic Fileds Ampere’s Law, which is related to BiotSavart Law: ˆ H . dl J . nds L s Here J is the steady current density. Static Magnetic Fields (Cont.) Conservation of magnetic flux or Gauss’s Law for magnetic fields: s ˆ 0 B. nds Differential Forms Ampere’s Law: XH J Gauss’s Law: .B 0 Static Magnetic Fields The vector fields B and H are related to each other through the permeability in (H/m) as: B H Ohm’s Law In a conducting medium with a conductivity (S/m) J is related to E as: J E Magnetic vector Potential The magnetic vector potential A is related to the magnetic flux density vector as: B XA Vector Poisson’s and Laplace’s Equations Poisson’s Equation: A J 2 Laplace’s Equation, when J=0: A0 2 Time Varying Fields In this case electric and magnetic fields exists simultaneously. Two divergence expressions remain the same but two curl equations need modifications. Differential Forms of Maxwell’s equations Generalized Forms B XE t .D D XH J t .B 0 Integral Forms Gauss’s law for electric fields: ˆ dv Q D.nds v s equ v Gauss’s law for magnetic fields: s ˆ 0 B.nds Integral Forms (Cont.) Faraday’s Law of Induction: B ˆ E . dl . nds L s t Modified Ampere’s Law: D ˆ H . dl ( J ). nds L s t Constitutive Relations D E B H J E Two other fundamental equations 1)Lorentz Force Equation: F Q( E uXB ) Where F is the force experienced by a particle with charge Q moving at a velocity u in an EM filed. Two other equations (cont.) Continuity Equation: v .J t