Presentation is loading. Please wait.

Presentation is loading. Please wait.

ELECTROMAGNETICS AND APPLICATIONS Handouts: Info sheet (DRAFT), Syllabus (outline and schedule DRAFT) Lecture #1 slides (only this time) Luca Daniel.

Published byBrittany Park Modified over 9 years ago

Similar presentations

Presentation on theme: "ELECTROMAGNETICS AND APPLICATIONS Handouts: Info sheet (DRAFT), Syllabus (outline and schedule DRAFT) Lecture #1 slides (only this time) Luca Daniel."— Presentation transcript:

1 ELECTROMAGNETICS AND APPLICATIONS Handouts: Info sheet (DRAFT), Syllabus (outline and schedule DRAFT) Lecture #1 slides (only this time) Luca Daniel

2 L1-2 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “guided systems” Applications –digital electronics: e.g. analyze transients when you send a signal from the CPU chip to the GPU chip, or from your keyboard to your iPad CPU RAM GPU A/D D/A keyboard iPad

3 L1-3 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “guided systems” Applications –digital electronics: e.g. analyze transients when you send a signal from the CPU chip to the GPU chip, or from your keyboard to your iPad –analog and biomedical electronics: e.g. match load of RF cables bringing signal from power amplifier to MRI coil antennas to avoid reflections CPU RAM GPU A/D D/A PA

4 L1-4 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “guided systems” Applications –transport of light: e.g. fiber optics (around your globe and in your neighborhood cable company), –or on-chip silicon-photonics Fiber Communications Around the Globe Prof. Watts, MIT

5 L1-5 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “guided systems” Applications –transport of electricity in power-lines –fluids in oil pipes, or blood in arteries and micro-fluidic channels Prof. Han, MIT

6 L1-6 Course Outline and Motivations Electromagnetics: –How to analyze, design and couple energy to/from resonators Applications –e.g. in cellphone receivers: electrical (LC) resonator filters –and MEMs resonators filters LNA ADC I Q LO Micron Technology, Inc

7 L1-7 Course Outline and Motivations Electromagnetics: –How to analyze, design and couple energy to/from resonators Applications –optical resonators (e.g. lasers) Prof. Ippen, MIT

8 L1-8 Course Outline and Motivations Electromagnetics: –How to analyze, design and couple energy to/from resonators Applications –acoustical resonators (e.g. musical instruments and vocal chords, and... your own shower “room”) d vocal chords

9 L1-9 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “non-guided systems” Applications –wire antennas (e.g. inside your iPhone, or wireless router) –aperture antennas (e.g. satellite, radar, parabola TV)

10 L1-10 Course Outline and Motivations Electromagnetics: –How to transport signals and power on “non-guided systems” Applications –acoustical antennas (e.g. rock concert loudspeaker)

11 L3-11 Review of Fundamental Electromagnetic Laws Electromagnetic Waves in Media and Interfaces oWaves in homogeneous lossless and lossy media oPower flow and energy balance (Poynting Theorem) oWaves at interfaces Digital & Analog Communications oTEM transmission lines (Telegrapher eqn.) oTransients in digital communication wires oWaves in RF cables oTEM resonators Microwave Communications ometallic waveguides omicrowave cavity resonators Course Outline

12 L3-12 Optical Communications Wireless Communications oshort dipole radiation in near & far field oreceiving and transmitting antennas oarray of antennas owireless communication links oaperture antennas, and understand diffraction Acoustics Course Outline (continue…)

13 L1-13 Course Overview and Motivations Maxwell Equations (review from 8.02) –in integral form –in differential form –EM waves in homogenous lossless media –EM Wave Equation –Solution of the EM Wave equation  Uniform Plane Waves (UPW)  Complex Notation (phasors) –EM Waves in homogeneous lossy media Today’s Outline Next Time Today

14 L1-14 Faraday’s Law: Maxwell’s Equations (in integral form) Electric field[volts / meter] = [V / m] Electric displacement[amperes sec / m 2 ] = [A s / m 2 ]  Electric charge density[coulombs / m 3 ] = [C / m 3 ] Magnetic field[amperes / meter] = [A / m] Magnetic flux density[Tesla] = [T] = [Webers / m 2 ] = 10 4 [Gauss] Electric current density[amperes/m 2 ] = [A / m 2 ] Gauss’s Laws Ampere’s Law:

15 L1-15 If the material properties ε, μ and σ vary with: Field direction Field intensity Position Frequency Time the media is called: Anisotropic Non-linear Inhomogeneous Dispersive Non-Stationary Types of Media

16 L1-16 Maxwell’s Equations (in differential form) Stokes Theorem: Gauss Divergence Theorem:

17 L1-17 0 Second derivative in space  second derivative in time, therefore solution is any function with identical dependencies on space and time (up to a constant) Maxwell’s Equations (in homogeneous lossless media) 0 0 Faraday’s Law: Ampere’s Law: Gauss‘s Law  is homogeus [ ] Constitutive Relations

Download ppt "ELECTROMAGNETICS AND APPLICATIONS Handouts: Info sheet (DRAFT), Syllabus (outline and schedule DRAFT) Lecture #1 slides (only this time) Luca Daniel."

Similar presentations

ELECTROMAGNETICS AND APPLICATIONS

ELECTROMAGNETICS AND APPLICATIONS
ENE 428 Microwave Engineering

ENE 428 Microwave Engineering
Prof. Ji Chen Notes 15 Plane Waves ECE 3317 1 Spring 2014 z x E ocean.

Prof. Ji Chen Notes 15 Plane Waves ECE Spring 2014 z x E ocean.
Chapter 1 Electromagnetic Fields

Chapter 1 Electromagnetic Fields
Maxwell’s Equations and Electromagnetic Waves Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still.

Maxwell’s Equations and Electromagnetic Waves Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still.
MAXWELL’S EQUATIONS 1. 2 Maxwell’s Equations in differential form.

MAXWELL’S EQUATIONS 1. 2 Maxwell’s Equations in differential form.
EMLAB 1 Solution of Maxwell’s eqs for simple cases.

EMLAB 1 Solution of Maxwell’s eqs for simple cases.
Maxwell’s Equations The two Gauss’s laws are symmetrical, apart from the absence of the term for magnetic monopoles in Gauss’s law for magnetism Faraday’s.

Maxwell’s Equations The two Gauss’s laws are symmetrical, apart from the absence of the term for magnetic monopoles in Gauss’s law for magnetism Faraday’s.
ELEN 3371 Electromagnetics Fall 2008 1 Lecture 6: Maxwell’s Equations Instructor: Dr. Gleb V. Tcheslavski Contact: Office.

ELEN 3371 Electromagnetics Fall Lecture 6: Maxwell’s Equations Instructor: Dr. Gleb V. Tcheslavski Contact: Office.
General form of Faraday’s Law

General form of Faraday’s Law
Maxwell’s Equations and Electromagnetic Waves

Maxwell’s Equations and Electromagnetic Waves
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
RS 1 ENE 428 Microwave Engineering Lecture 1 Introduction, Maxwell’s equations, fields in media, and boundary conditions.

RS 1 ENE 428 Microwave Engineering Lecture 1 Introduction, Maxwell’s equations, fields in media, and boundary conditions.
Electromagnetic Engineering ECE292 Sophomore Seminar 18 March 2008.

Electromagnetic Engineering ECE292 Sophomore Seminar 18 March 2008.
So far Geometrical Optics – Reflection and refraction from planar and spherical interfaces –Imaging condition in the paraxial approximation –Apertures.

So far Geometrical Optics – Reflection and refraction from planar and spherical interfaces –Imaging condition in the paraxial approximation –Apertures.
ELECTROMAGNETICS AND APPLICATIONS Lecture 17 Metallic Waveguides Dispersion Relations Luca Daniel.

ELECTROMAGNETICS AND APPLICATIONS Lecture 17 Metallic Waveguides Dispersion Relations Luca Daniel.
ELECTROMAGNETICS AND APPLICATIONS Lecture 14 RLC Resonators with TEM feed & TEM Resonators Luca Daniel.

ELECTROMAGNETICS AND APPLICATIONS Lecture 14 RLC Resonators with TEM feed & TEM Resonators Luca Daniel.
Electromagnetic Waves

Electromagnetic Waves
Prof. Ji Chen Adapted from notes by Prof. Stuart A. Long Notes 4 Maxwell’s Equations ECE 3317 1 Spring 2014.

Prof. Ji Chen Adapted from notes by Prof. Stuart A. Long Notes 4 Maxwell’s Equations ECE Spring 2014.
8. Wave Reflection & Transmission

8. Wave Reflection & Transmission

Similar presentations

Ads by Google