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ENE 428 Microwave Engineering . Lecture 3 Polarization, Reflection and Transmission at normal incidence. RS. Uniform plane wave (UPW) power transmission. from. W/m 2. Polarization. UPW is characterized by its propagation direction and frequency.
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ENE 428Microwave Engineering Lecture 3 Polarization, Reflection and Transmission at normal incidence RS RS
Uniform plane wave (UPW) power transmission from W/m2 RS
Polarization • UPW is characterized by its propagation direction and frequency. • Its attenuation and phase are determined by medium’s parameters. • Polarization determines the orientation of the electric field in a fixed spatial plane orthogonal to the direction of the propagation. RS
Linear polarization • Consider in free space, • At plane z = 0, a tip of field traces straight line segment called “linearly polarized wave” RS
Linear polarization • A pair of linearly polarized wave also produces linear polarization At z = 0 plane At t = 0, both linearly polarized waves have their maximum values. RS
More generalized linear polarization • More generalized of two linearly polarized waves, • Linear polarization occurs when two linearly polarized waves are in phase out of phase RS
Elliptically polarized wave • Superposition of two linearly polarized waves that • If x = 0 and y = 45, we have RS
Circularly polarized wave • occurs when Exoand Eyo are equal and • Right hand circularly polarized (RHCP) wave • Left hand circularly polarized (LHCP) wave RS
Circularly polarized wave • Phasor forms: • for RHCP, • for LHCP, from Note: There are also RHEP and LHEP RS
Ex2 The electric field of a uniform plane wave in free space is given by , determine • f • The magnetic field intensity RS
c) d) Describe the polarization of the wave RS
Incident wave • Normal incidence – the propagation direction is normal to the boundary Assume the medium is lossless, let the incident electric field to be or in a phasor form since then we can show that RS
Transmitted wave • Transmitted wave Assume the medium is lossless, let the transmitted electric field to be then we can show that RS
Reflected wave (1) • From boundary conditions, At z = 0, we have and 1 = 2are media the same? RS
Reflected wave (2) • There must be a reflected wave and This wave travels in –z direction. RS
Reflection and transmission coefficients (1) • Boundary conditions (reflected wave is included) from therefore at z = 0 (1) RS
Reflection and transmission coefficients (2) • Boundary conditions (reflected wave is included) from therefore at z = 0 (2) RS
Reflection and transmission coefficients (3) • Solve Eqs. (1) and (2) to get Reflection coefficient Transmission coefficient RS
Types of boundaries: perfect dielectric and perfect conductor (1) From . Since 2 = 0 then = -1 and Ex10+= -Ex10- RS
Types of boundaries: perfect dielectric and perfect conductor (2) This can be shown in an instantaneous form as Standing wave RS
Standing waves (1) When t = m, Ex1 is 0 at all positions. and when z = m, Ex1 is 0 at all time. Null positions occur at RS
Standing waves (2) Since and , the magnetic field is or . Hy1 is maximum when Ex1 = 0 Poynting vector RS
Power transmission for 2 perfect dielectrics (1) Then 1and 2are both real positive quantities and 1 = 2= 0 Average incident power densities RS
Ex3 Let medium 1 have 1 = 100 and medium 2 have 2 = 300 , given Ex10+ = 100 V/m. Calculate average incident, reflected, and transmitted power densities RS
Wave reflection from multiple interfaces (1) • Wave reflection from materials that are finite in extent such as interfaces between air, glass, and coating • At steady state, there will be 5 total waves RS
Wave reflection from multiple interfaces (2) Assume lossless media, we have then we can show that RS
Wave reflection from multiple interfaces (2) Assume lossless media, we have then we can show that RS
Wave impedance w (1) Use Euler’s identity, we can show that RS
Wave impedance w (2) Since from B.C. at z = -l we may write RS
Input impedance in solve to get RS
Refractive index Under lossless conditions, RS