Transmission lines and electromagnetic waves
Created By
Prof. Ananth Krishnan via Swayam
- 0
- 12 weeks long
- Swayam
- English
Course Overview
Bridge course to practical aspects of engineering electromagnetics for entering Graduate students and senior undergraduate students. The course will involve hands on programming to visualize most aspects of electromagnetics and transmission lines. INTENDED AUDIENCE : M.Tech. 1st years and B.Tech. 3rd or 4th yearsPREREQUISITES : NilINDUSTRY SUPPORT : BEL, ISRO, Comsol, HFSS
Course Circullum
Week 1 : Circuit model of a lossless transmission line
a) Introducing space coordinate in circuit diagram
b) The notion of delay in a lossless interconnect
c) LC ladder equivalent
d) The spatial derivative in equations for V and I
e) Telegraphers equations
f) Decoupling to wave equation
g) Meaning of the analytical solution to wave equation - The existence of voltage and current waves
Week 2 : Programmatic approach to solving partial differential equations - Finite differences
a) Taylor’s series approximation to first and second derivatives
b) Partial derivatives
c) Octave/Matlab based solution to voltage in a capacitor (Laplace solver)
d) Meaning of Dirichlet and Neumann boundary conditions and the voltage in parallel plate capacitor
e) Octave/Matlab to solve wave equation
f) Octave/Matlab to solve Telegrapher’s equations
g) Implication of short circuit or open circuit in a transmission line
h) The reflection coefficient
i) Time domain reflectometry
j) Time of flight based inferences
k) Bounce diagrams and time evolution of voltage
Week 3 : Non-idealities in the transmission line circuit model
a) Resistor and conductor in circuit equivalent
b) Steady state AC in transmission line
c) The propagation constant and characteristic impedance
d) Impedance in the transmission line
e) Standing Wave and Voltage Standing Wave Ratio
f) Power in transmission line
Week 4 : Impedance matching
a) Quarter wavelength transformer
b) Stub based matching
Week 5 : Equivalence of Maxwell’s equations and telegraphers equations
Week 6 : Programmatic solutions to Maxwell’s equations using Octave/Matlab
Week 7 : Power and Poynting vector
Week 8 : Losses in propagation and propagation constant, Polarization (the only difference from transmission lines)
a) Linear, circular, elliptical
Week 9 : Reflection and transmission at interfaces (analogous to transmission lines)
a) Reflection coefficient and transmission coefficient
b) Standing waves
Effect of reflection and transmission on Polarization (different from transmission lines)
Week 10 : Dielectric-Dielectric and Dielectric-Metal interfaces, Fresnel coefficients,Brewsters angle,Total internal reflection
Week 11 : Parallel plate and rectangular waveguides, Modes of parallel plate and rectangular waveguides
Week 12 : The cut-off frequency, Dispersion
a) Introducing space coordinate in circuit diagram
b) The notion of delay in a lossless interconnect
c) LC ladder equivalent
d) The spatial derivative in equations for V and I
e) Telegraphers equations
f) Decoupling to wave equation
g) Meaning of the analytical solution to wave equation - The existence of voltage and current waves
Week 2 : Programmatic approach to solving partial differential equations - Finite differences
a) Taylor’s series approximation to first and second derivatives
b) Partial derivatives
c) Octave/Matlab based solution to voltage in a capacitor (Laplace solver)
d) Meaning of Dirichlet and Neumann boundary conditions and the voltage in parallel plate capacitor
e) Octave/Matlab to solve wave equation
f) Octave/Matlab to solve Telegrapher’s equations
g) Implication of short circuit or open circuit in a transmission line
h) The reflection coefficient
i) Time domain reflectometry
j) Time of flight based inferences
k) Bounce diagrams and time evolution of voltage
Week 3 : Non-idealities in the transmission line circuit model
a) Resistor and conductor in circuit equivalent
b) Steady state AC in transmission line
c) The propagation constant and characteristic impedance
d) Impedance in the transmission line
e) Standing Wave and Voltage Standing Wave Ratio
f) Power in transmission line
Week 4 : Impedance matching
a) Quarter wavelength transformer
b) Stub based matching
Week 5 : Equivalence of Maxwell’s equations and telegraphers equations
Week 6 : Programmatic solutions to Maxwell’s equations using Octave/Matlab
Week 7 : Power and Poynting vector
Week 8 : Losses in propagation and propagation constant, Polarization (the only difference from transmission lines)
a) Linear, circular, elliptical
Week 9 : Reflection and transmission at interfaces (analogous to transmission lines)
a) Reflection coefficient and transmission coefficient
b) Standing waves
Effect of reflection and transmission on Polarization (different from transmission lines)
Week 10 : Dielectric-Dielectric and Dielectric-Metal interfaces, Fresnel coefficients,Brewsters angle,Total internal reflection
Week 11 : Parallel plate and rectangular waveguides, Modes of parallel plate and rectangular waveguides
Week 12 : The cut-off frequency, Dispersion
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This Course Include:
Week 1 : Circuit model of a lossless transmission line
a) Introducing space coordinate in circuit diagram
b) The notion of delay in a lossless interconnect
c) LC ladder equivalent
d) The spatial derivative in equations for V and I
e) Telegraphers equations
f) Decoupling to wave equation
g) Meaning of the analytical solution to wave equation - The existence of voltage and current waves
Week 2 : Programmatic approach to solving partial differential equations - Finite differences
a) Taylor’s series approximation to first and second derivatives
b) Partial derivatives
c) Octave/Matlab based solution to voltage in a capacitor (Laplace solver)
d) Meaning of Dirichlet and Neumann boundary conditions and the voltage in parallel plate capacitor
e) Octave/Matlab to solve wave equation
f) Octave/Matlab to solve Telegrapher’s equations
g) Implication of short circuit or open circuit in a transmission line
h) The reflection coefficient
i) Time domain reflectometry
j) Time of flight based inferences
k) Bounce diagrams and time evolution of voltage
Week 3 : Non-idealities in the transmission line circuit model
a) Resistor and conductor in circuit equivalent
b) Steady state AC in transmission line
c) The propagation constant and characteristic impedance
d) Impedance in the transmission line
e) Standing Wave and Voltage Standing Wave Ratio
f) Power in transmission line
Week 4 : Impedance matching
a) Quarter wavelength transformer
b) Stub based matching
Week 5 : Equivalence of Maxwell’s equations and telegraphers equations
Week 6 : Programmatic solutions to Maxwell’s equations using Octave/Matlab
Week 7 : Power and Poynting vector
Week 8 : Losses in propagation and propagation constant, Polarization (the only difference from transmission lines)
a) Linear, circular, elliptical
Week 9 : Reflection and transmission at interfaces (analogous to transmission lines)
a) Reflection coefficient and transmission coefficient
b) Standing waves
Effect of reflection and transmission on Polarization (different from transmission lines)
Week 10 : Dielectric-Dielectric and Dielectric-Metal interfaces, Fresnel coefficients,Brewsters angle,Total internal reflection
Week 11 : Parallel plate and rectangular waveguides, Modes of parallel plate and rectangular waveguides
Week 12 : The cut-off frequency, Dispersion
a) Introducing space coordinate in circuit diagram
b) The notion of delay in a lossless interconnect
c) LC ladder equivalent
d) The spatial derivative in equations for V and I
e) Telegraphers equations
f) Decoupling to wave equation
g) Meaning of the analytical solution to wave equation - The existence of voltage and current waves
Week 2 : Programmatic approach to solving partial differential equations - Finite differences
a) Taylor’s series approximation to first and second derivatives
b) Partial derivatives
c) Octave/Matlab based solution to voltage in a capacitor (Laplace solver)
d) Meaning of Dirichlet and Neumann boundary conditions and the voltage in parallel plate capacitor
e) Octave/Matlab to solve wave equation
f) Octave/Matlab to solve Telegrapher’s equations
g) Implication of short circuit or open circuit in a transmission line
h) The reflection coefficient
i) Time domain reflectometry
j) Time of flight based inferences
k) Bounce diagrams and time evolution of voltage
Week 3 : Non-idealities in the transmission line circuit model
a) Resistor and conductor in circuit equivalent
b) Steady state AC in transmission line
c) The propagation constant and characteristic impedance
d) Impedance in the transmission line
e) Standing Wave and Voltage Standing Wave Ratio
f) Power in transmission line
Week 4 : Impedance matching
a) Quarter wavelength transformer
b) Stub based matching
Week 5 : Equivalence of Maxwell’s equations and telegraphers equations
Week 6 : Programmatic solutions to Maxwell’s equations using Octave/Matlab
Week 7 : Power and Poynting vector
Week 8 : Losses in propagation and propagation constant, Polarization (the only difference from transmission lines)
a) Linear, circular, elliptical
Week 9 : Reflection and transmission at interfaces (analogous to transmission lines)
a) Reflection coefficient and transmission coefficient
b) Standing waves
Effect of reflection and transmission on Polarization (different from transmission lines)
Week 10 : Dielectric-Dielectric and Dielectric-Metal interfaces, Fresnel coefficients,Brewsters angle,Total internal reflection
Week 11 : Parallel plate and rectangular waveguides, Modes of parallel plate and rectangular waveguides
Week 12 : The cut-off frequency, Dispersion
- Provider:Swayam
- Certificate:Paid Certificate Available
- Language:English
- Duration:12 weeks long
- Language CC: