Notes to Teachers and Students
It is essential to write out, term-by-term, every sequence and sum in this chapter. This demystifies the seemingly mysterious notation. The example on compound interest shows the value of limiting arguments in everyday life and gives ex some real meaning. The function ejθ, covered in the section "The Function of ejθ and the Unit Circle" and "Numerical Experiment (Approximating ejθ)", must be understood by all students before proceeding to "Phasors" . The Euler and De Moivre identities provide every tool that students need to derive trigonometric formulas. The properties of roots of unity are invaluable for the study of phasors in "Phasors" .
The MATLAB programs in this chapter are used to illustrate sequences and series and to explore approximations to \(\sinθ\) and \(\cosθ\). The numerical experiment in "Numerical Experiment (Approximating ejθ)" illustrates, geometrically and algebraically, how approximations to ejθ converge.
“Second-Order Differential and Difference Equations” is a little demanding for freshmen, but we give it a once-over-lightly to illustrate the power of quadratic equations and the functions ex and ejθ. This section also gives a sneak preview of more advanced courses in circuits and systems.
It is probably not too strong a statement to say that the function ex is the most important function in engineering and applied science. In this chapter we study the function ex and extend its definition to the function ejθ. This study clarifies our definition of ejθ from "Complex Numbers" and leads us to an investigation of sequences and series. We use the function ejθ to derive the Euler and De Moivre identities and to produce a number of important trigonometric identities. We define the complex roots of unity and study their partial sums. The results of this chapter will be used in "Phasors" when we study the phasor representation of sinusoidal signals.