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Fields and Waves I

Fields and Waves I. Lecture 1 Introduction to Fields and Waves K. A. Connor Electrical, Computer, and Systems Engineering Department Rensselaer Polytechnic Institute, Troy, NY. These Slides Were Prepared by Prof. Kenneth A. Connor Using Original Materials Written Mostly by the Following:.

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Fields and Waves I

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  1. Fields and Waves I Lecture 1 Introduction to Fields and Waves K. A. Connor Electrical, Computer, and Systems Engineering Department Rensselaer Polytechnic Institute, Troy, NY

  2. These Slides Were Prepared by Prof. Kenneth A. Connor Using Original Materials Written Mostly by the Following: • Kenneth A. Connor – ECSE Department, Rensselaer Polytechnic Institute, Troy, NY • J. Darryl Michael – GE Global Research Center, Niskayuna, NY • Thomas P. Crowley – National Institute of Standards and Technology, Boulder, CO • Sheppard J. Salon – ECSE Department, Rensselaer Polytechnic Institute, Troy, NY • Lale Ergene – ITU Informatics Institute, Istanbul, Turkey • Jeffrey Braunstein – Chung-Ang University, Seoul, Korea Materials from other sources are referenced where they are used. Those listed as Ulaby are figures from Ulaby’s textbook. Fields and Waves I

  3. Overview • Why study E&M? • Review of 5 experiments • Introduction to transmission lines • Introduction to the course webpages Fields and Waves I

  4. Why Study E&M? • Some good sources • http://www.ece.northwestern.edu/ecefaculty/taflove/WhyStudy.pdf Some info from this document follows. (Taflove) • Others? Fields and Waves I

  5. Why take Fields and Waves? • E and B are fundamental to Electrical Engineering • if you have “V”, there is an “E” • if you have “I”, there is a “B” V is Voltage I is Current E is Electric Field Intensity B is Magnetic Flux Density Fields and Waves I

  6. Relationship with Circuit Theory • Circuit Theory uses simplified (lumped) Models of components The model, however, does not include: • Details on how the components work • Components are not made up of C,L,R • Distributed Properties for example Transmission Lines • Electromagnetic Waves - like mWaves, Radio Waves, Optics • Applications such as Capacitive Sensors • Noise Fields and Waves I

  7. Relationship with Circuit Theory Many of these effects are more important at High Frequency Need to be considered when designing for High Speed Applications Fields and Waves I

  8. HOWEVER Current technology (with High Speed Computers) enables accurate circuit simulation Simulation Packages include: a) SPICE (from UC Berkeley) b) SABER (systems approach) • Accurate simulation requires understanding of “ components” and interactions • Interactions also need to be described by Models • Models are obtained by an understanding of EM Fields Question: Why do companies spend resources on developing models? Fields and Waves I

  9. Why Study E&M? (Taflove) Microwave energy scattering from missile antenna radome. Fields and Waves I

  10. Why Study E&M? • The bedrock of introductory circuit analysis, Kirchoff’s current and voltage laws, fail in most high-speed circuits. These must be analyzed using E&M theory. Signal power flows are not confined to the intended metal wires or circuit paths. • Microwave circuits typically process bandpass signals at frequencies above 3 GHz. Common circuit features include microstrip transmission lines, directional couplers, circulators, filters, matching networks, and individual transistors. Circuit operation is fundamentally based upon electromagnetic wave phenomena. • Digital circuits typically process low-pass pulses having clock rates below 2 GHz. Typical circuits include densely packed, multiple planes of metal traces providing flow paths for the signals, dc power feeds, and ground returns. Via pins provide electrical connections between the planes. Circuit operation is nominally not based upon electromagnetic wave effects. • The distinction between the design of these two classes is blurring. (Taflove) Fields and Waves I

  11. Why Study E&M? • False-color visualization (right) illustrating the coupling and crosstalk of a high-speed logic pulse entering and leaving a microchip embedded within a conventional dual in-line integrated-circuit package (left). The fields associated with the logic pulse are not confined to the metal circuit paths and, in fact, smear out and couple to all adjacent circuit paths. (Taflove) Fields and Waves I

  12. Review of 5 Experiments • Experiment 1 – Two-Wire Capacitor • Experiment 2 – Transformers • Experiment 3 – EMI Radiation • Experiment 4 – Motion Sensor • Experiment 5 – Transmission Lines Fields and Waves I

  13. Exp 1: Capacitor Two Wires Fields and Waves I

  14. Exp 1: Capacitor Fields and Waves I

  15. Exp 2: Transformers • Combination should look like a transformer • If acting as an ideal transformer, the voltage ratio should be correct • Transformers act more ideally at certain frequencies • Works better as a transformer when the secondary is tightly wound on the primary Fields and Waves I

  16. Exp 3: EMI radiation and wave propagation Unshielded Wire Coaxial Cable Pomona 3788 • An unshielded wire can act like a simple antenna • What frequencies are observed? Fields and Waves I

  17. Exp 4: Motion Sensor Magnetic Pickup Coil Fields and Waves I

  18. Exp 4: Motion Sensor Fields and Waves I

  19. The Analog Device Accelerometer • The ADI Accelerometer is an excellent example of a MEMS device in which a large number of very, very small cantilever beams are used to measure acceleration. A simplified view of a beam is shown here. http://www.flickr.com/photos/mitopencourseware/3362590885/ ENGR-4300 Electronic Instrumentation

  20. Exp 5: Transmission Lines The same signal passes through the short cable to channel 2 and the long cable (60-100 meters) to channel 1. Fields and Waves I

  21. Exp 5: Transmission Lines • What is observed? • Phase shift between input and output • Output signal is somewhat smaller than input on the long cable • When the terminating resistor is removed, the signal changes • The wires have finite resistance ( ) • What can we conclude from this? • Wire resistance is low so, for shorter cables, we can consider transmission lines to be lossless • What else? Fields and Waves I

  22. Transmission Lines • Connect to circuit theory • Demonstrate the need to understand R, L, C, & G per unit length parameters • Very useful devices (all EE, CSE, EPE students will use them someday) • Can be easily analyzed to find electric and magnetic fields Fields and Waves I

  23. Information Card • Name • Major (s) • Class Year • Degree Concentration Area • Technical jobs, internships or co-op experiences • Other schools attended • Professional goals • Comments or questions Fields and Waves I

  24. Transmission Line Transfer signal/power from A to B Fundamental Purpose of TL EXAMPLES: • Power Lines (60Hz) • Coaxial Cables • Twisted Pairs • Interconnects (approximates a parallel plate capacitor) • All have two conductors Fields and Waves I

  25. and effects are important for understanding Transmission Line Effects RELEVANT EFFECTS: • Time Delays • Reflections/Impedance Matching TL effects more important at high f (or short t) and long lengths But, calculations use V and I for predicting effects Fields and Waves I

  26. Transmission Line Model Cables have both L and C: C between conductors 2 wire example: L is a series effect Fields and Waves I

  27. Transmission Line Model Model of SHORT SECTION: L and C are distributed through the length of the cable Model the full length as: ….etc. Fields and Waves I

  28. Transmission Line Model Does L -C combination behave like a cable? How would you know? Time Delay ~ same as cable delay Each, , represents a length of cable = inductance/length = capacitance/length Fields and Waves I

  29. Transmission Line Model When is model of L - C combination valid? • need Dz small • chosen Dz is a compromise • works well at 600 kHz but not 6 MHz At 6 MHz, the L - C model is a low pass filter but coax-cable is not Fields and Waves I

  30. limit As Transmission Line Representation Fields and Waves I

  31. Transmission Line Representation Similarly, Obtain the following PDE: These are functions that move with velocity u Solutions are: Fields and Waves I

  32. Transmission Line Representation Functions that move with velocity u Example: wt =1 Wave moving to the right At t=0, At wt =1 wt =0 Fields and Waves I

  33. Using PSpice • We can use PSpice to do numerical experiments that demonstrate how transmission lines work Fields and Waves I

  34. PSpice OUTPUT INPUT Fields and Waves I

  35. Sine Waves • The form of the wave solution • First check to see that these solutions have the properties we expect by plotting them using a tool like Matlab Fields and Waves I

  36. Sine Waves • The positive wave u Fields and Waves I

  37. Solutions to the Wave Equation • Now we check to see that the sine waves are indeed solutions to the wave equation Fields and Waves I

  38. Solutions to the Wave Equation • Thus, our sine wave is a solution to the voltage or current equation • if or • u = the speed of wave propagation = the speed of light Fields and Waves I

  39. Velocity of Propagation Hosfelt • Check for RG58/U Cable • Inductance per unit length is 0.25 micro Henries per meter • Capacitance per unit length is 100 pico Farads per meter or 2/3 the speed of light Fields and Waves I

  40. From Digi-Key (Carol Cable) Fields and Waves I

  41. From Elpa (Lithuania) Capacitance Velocity ratio = .68 Fields and Waves I

  42. Coaxial Cable Parameters • Capacitance • Inductance Ulaby Fields and Waves I

  43. For Next Time • Download the Orcad PSpice Student Version if you do not already have it. • I will do some numerical experiments in class using PSpice • Do the reading • Acquaint yourself with the course webpages (open and WebCT) Fields and Waves I

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