Pole and Product Expansions, and Series Summation

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Pole and Product Expansions, and Series Summation ECE 6382 Fall 2016 David R. Jackson Notes 11 Pole and Product Expansions, and Series Summation Notes are from D. R. Wilton, Dept. of ECE

Pole Expansion of Meromorphic Functions Mitag-Leffler Theorem Then Note: Each individual series in the sum may not converge. Note that a pole at the origin is not allowed! (But we can always shift using z  z - z0. Or we can add a term to cancel a pole that appears at the origin.) Mittag-Leffler

Proof of Mittag-Leffler Theorem (putting over a common denominator)

Extended Form of the Mittag-Leffler Theorem Extended Mitag-Leffler Theorem Note: The first p terms are those of a Taylor series.

Example: Pole Expansion of cot z

Example: Pole Expansion of cot z (cont.) Figure showing the circles In this case N is always even.

Example: Pole Expansion of cot z (cont.)

Example: Pole Expansion of cot z (cont.) It isn’t necessary that the paths CN be circular; see the next slide.

Example: Pole Expansion of cot z (cont.) In this case N is always even. coth (x) ―

Example: Pole Expansion of cot z (cont.) Hence, we have

Other Pole Expansions The Mittag-Leffler theorem generalizes the partial fraction representation of a rational function to meromorphic functions.

Infinite Product Expansion of Entire Functions Weierstrass’s Factorization Theorem Weierstrass Then

Product Expansion Formula

Useful Product Expansions Product expansions generalize the factorization of the numerator and denominator polynomials of a rational function into products of their roots.

The Argument Principle First consider the following integral: where (The integer M can be either positive or negative.) So we have Note: The path C does not have to be a circle.

The Argument Principle (cont.) Next, we consider extending this to an arbitrary function that is analytic inside a region except for poles. The function may also have zeros. Assume that f (z) has a pole or a zero of order (multiplicity) Mn at z = an.

The Argument Principle (cont.) Therefore

The Argument Principle (cont.) Summary Note: In counting the zeros and poles, we include multiplicities. (For example, at a double zero, we add 2; at a double pole we add -2). Note: We assume that the function only has zeros and poles of finite order, and no other singularities.

The Argument Principle (cont.) Note: the argument must change continuously! Hence This is the result from which the “argument principle” gets its name.

The Argument Principle (cont.) Summary of equivalent forms:

The Argument Principle (cont.) Example The path C is a circle centered at (1.5, 0) of radius 1.

The Argument Principle (cont.) The original plot from Mathcad

The Argument Principle (cont.) We add 2 after  = .

Summation of Series

Summation of Series (cont.) Example Derive the following result: If I  0 as the path increases, we have

Summation of Series (cont.) Example Hence (factor of 2)