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ECE 546 Lecture 02 Review of Electromagnetics. Spring 2014. Jose E. Schutt-Aine Electrical & Computer Engineering University of Illinois jschutt@emlab.uiuc.edu. Electromagnetic Quantities. Electric field (Volts/m). Electric flux density (Coulombs/m 2 ). Magnetic field (Amperes/m).
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ECE 546 Lecture 02 Review of Electromagnetics Spring 2014 Jose E. Schutt-Aine Electrical & Computer Engineering University of Illinois jschutt@emlab.uiuc.edu
Electromagnetic Quantities Electric field (Volts/m) Electric flux density (Coulombs/m2) Magnetic field (Amperes/m) Magnetic flux density (Webers/m2) Current density (Amperes/m2) Charge density (Coulombs/m2)
Maxwell’s Equations Faraday’s Law of Induction Ampère’s Law Gauss’ Law for electric field Gauss’ Law for magnetic field
Constitutive Relations Permittivity e: Farads/m Permeability m: Henries/m Free Space
Electrostatics Assume no time dependence Poisson’s Equation if no charge is present Laplace’s Equation
Free Space Solution Faraday’s Law of Induction Ampère’s Law Gauss’ Law for electric field Gauss’ Law for magnetic field
Wave Equation Wave Equation can show that
Wave Equation separating the components
Wave Equation Plane Wave (a) Assume that only Ex exists Ey=Ez=0 (b) Only z spatial dependence This situation leads to the plane wave solution In addition, assume a time-harmonic dependence then
Plane Wave Solution solution where propagation constant In the time domain solution
Plane Wave Characteristics where propagation constant In free space
Solution for Magnetic Field then If we assume that then If we assume that intrinsic impedance of medium
Time-Average Poynting Vector Poynting vector W/m2 time-average Poynting vector W/m2 We can show that
Material Medium or s: conductivity of material medium (W-1m-1) since then
Wave in Material Medium g is complex propagation constant a: associated with attenuation of wave b: associated with propagation of wave
Wave in Material Medium Solution: decaying exponential Complex intrinsic impedance Magnetic field
Wave in Material Medium Phase Velocity: Wavelength: Special Cases 1. Perfect dielectric air, free space and
Wave in Material Medium 2. Lossy dielectric Loss tangent:
Wave in Material Medium 3. Good conductors Loss tangent:
Radiation - Vector Potential Assume time harmonicity ~ (1) (2) (3) (4)
Radiation - Vector Potential Using the property: : vector potential
Vector Potential Since a vector is uniquely defined by its curl and its divergence, we can choose the divergence of A Lorentz condition
Vector Potential D’Alembert’s equation
Vector Potential Three-dimensional free-space Green’s function Vector potential From A, get E and H using Maxwell’s equations
Vector Potential For infinitesimal antenna, the current density is: Calculating the vector potential, In spherical coordinates,
Vector Potential Resolving into components,
E and H Fields Calculate E and H fields
Far Field Approximation Note that:
Far Field Approximation Characteristics of plane waves • Uniform constant phase locus is a plane • Constant magnitude • Independent of q • Does not decay Similarities between infinitesimal antenna far field radiated and plane wave • E and H are perpendicular • E and H are related by h • E is perpendicular to H
Poynting Vector Time-average Poynting vector or TA power density E and H here are PHASORS
Time-Average Power Total power radiated (time-average)
Directivity For infinitesimal antenna,
Directivity Directivity: gain in direction of maximum value Radiation resistance: From we have: For infinitesimal antenna:
Radiation Resistance For free space, (for Hertzian dipole) The radiation resistance of an antenna is the value of a fictitious resistance that would dissipate an amount of power equal to the radiated power Pr when the current in the resistance is equal to the maximum current along the antenna A high radiation resistance is a desirable property for an antenna