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This module is part of the collection, A First Course in Electrical and Computer Engineering . The LaTeX source files for this collection were created using an optical character recognition technology, and because of this process there may be more errors than usual. Please contact us if you discover any errors.

Notes to teachers and students:

When we teach complex numbers to beginning engineering students, we encourage a geometrical picture supported by an algebraic structure . Every algebraic manipulation carried out in a lecture is accompanied by a care-fully drawn picture in order to fix the idea that geometry and algebra gohand-in-glove to complete our understanding of complex numbers. We assign essentially every problem for homework.

We use the MATLAB programs in this chapter to illustrate the theory of complex numbers and to develop skill with the MATLAB language. The numerical experiment introduces students to the basic quadratic equation of electrical and computer engineering and shows how the roots ofthis quadratic equation depend on the coefficients of the equation.

“Representing Complex Numbers in a Vector Space,” is a little demanding for freshmen but easily accessible to sophomores. It may becovered for additional insight, skipped without consequence, or covered after Chapter 4 . “An Electric Field Computation,” is well beyond most freshmen, and it is demanding for sophomores. Nonetheless, an expertin electromagnetics might want to cover the section "An electric Field Computation" for the insight it brings to the use of complex numbers for representing two-dimensional real quantities.

Introduction

It is hard to overestimate the value of complex numbers. They first arose in the study of roots for quadratic equations. But, as with so manyother great discoveries, complex numbers have found widespread application well outside their original domain of discovery. They are now used throughoutmathematics, applied science, and engineering to represent the harmonic nature of vibrating systems and oscillating fields. For example, complex numbers may be used to study

  1. traveling waves on a sea surface;
  2. standing waves on a violin string;
  3. the pure tone of a Kurzweil piano;
  4. the acoustic field in a concert hall;
  5. the light of a He-Ne laser;
  6. the electromagnetic field in a light show;
  7. the vibrations in a robot arm;
  8. the oscillations of a suspension system;
  9. the carrier signal used to transmit AM or FM radio;
  10. the carrier signal used to transmit digital data over telephone lines; and
  11. the 60 Hz signal used to deliver power to a home.

In this chapter we develop the algebra and geometry of complex numbers. In Chapter 3 we will show how complex numbers are used to build phasor representations of power and communication signals.

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Source:  OpenStax, A first course in electrical and computer engineering. OpenStax CNX. Sep 14, 2009 Download for free at http://cnx.org/content/col10685/1.2
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