IV.3. Zeros of an Analytic Function

Similar documents
Section VI.31. Algebraic Extensions

III.2. Analytic Functions

13 Maximum Modulus Principle

Solutions Final Exam May. 14, 2014

NATIONAL UNIVERSITY OF SINGAPORE Department of Mathematics MA4247 Complex Analysis II Lecture Notes Part II

Complex Analysis Qualifying Exam Solutions

Cauchy Integral Formula Consequences

9. Series representation for analytic functions

CONSEQUENCES OF POWER SERIES REPRESENTATION

Math 220A Homework 4 Solutions

Continuity. Chapter 4

Continuity. Chapter 4

Math 220A - Fall Final Exam Solutions

f (n) (z 0 ) Theorem [Morera s Theorem] Suppose f is continuous on a domain U, and satisfies that for any closed curve γ in U, γ

An Introduction to Complex Analysis and Geometry John P. D Angelo, Pure and Applied Undergraduate Texts Volume 12, American Mathematical Society, 2010

1 + lim. n n+1. f(x) = x + 1, x 1. and we check that f is increasing, instead. Using the quotient rule, we easily find that. 1 (x + 1) 1 x (x + 1) 2 =

Supplement. The Extended Complex Plane

Chapter 11. Cauchy s Integral Formula

MORE CONSEQUENCES OF CAUCHY S THEOREM

8. Limit Laws. lim(f g)(x) = lim f(x) lim g(x), (x) = lim x a f(x) g lim x a g(x)

Theorem [Mean Value Theorem for Harmonic Functions] Let u be harmonic on D(z 0, R). Then for any r (0, R), u(z 0 ) = 1 z z 0 r

8.7 Taylor s Inequality Math 2300 Section 005 Calculus II. f(x) = ln(1 + x) f(0) = 0

Taylor and Maclaurin Series

Complex Analysis Homework 9: Solutions

Ma 530 Power Series II

PICARD S THEOREM STEFAN FRIEDL

5. Some theorems on continuous functions

1 Topology Definition of a topology Basis (Base) of a topology The subspace topology & the product topology on X Y 3

8 Further theory of function limits and continuity

2 Sequences, Continuity, and Limits

Math 220A Fall 2007 Homework #7. Will Garner A

1S11: Calculus for students in Science

Problem Set 5 Solution Set

Chapter 4: Open mapping theorem, removable singularities

Principle of Mathematical Induction

Math 328 Course Notes

8.5 Taylor Polynomials and Taylor Series

Notes on Complex Analysis

(a) For an accumulation point a of S, the number l is the limit of f(x) as x approaches a, or lim x a f(x) = l, iff

Chapter 2: Functions, Limits and Continuity

Fourth Week: Lectures 10-12

Thus f is continuous at x 0. Matthew Straughn Math 402 Homework 6

z b k P k p k (z), (z a) f (n 1) (a) 2 (n 1)! (z a)n 1 +f n (z)(z a) n, where f n (z) = 1 C

A Primer on Lipschitz Functions by Robert Dr. Bob Gardner Revised and Corrected, Fall 2013

Solutions to Complex Analysis Prelims Ben Strasser

Lecture 32: Taylor Series and McLaurin series We saw last day that some functions are equal to a power series on part of their domain.

MATH 131A: REAL ANALYSIS (BIG IDEAS)

Real Analysis Math 131AH Rudin, Chapter #1. Dominique Abdi

MA30056: Complex Analysis. Revision: Checklist & Previous Exam Questions I

INTEGRATION WORKSHOP 2004 COMPLEX ANALYSIS EXERCISES

Math 140A - Fall Final Exam

Section X.55. Cyclotomic Extensions

Complex Analysis Problems

Introduction to Proofs in Analysis. updated December 5, By Edoh Y. Amiran Following the outline of notes by Donald Chalice INTRODUCTION

Supplement. Algebraic Closure of a Field

Complex numbers, the exponential function, and factorization over C

MA30056: Complex Analysis. Exercise Sheet 7: Applications and Sequences of Complex Functions

3 FUNCTIONS. 3.1 Definition and Basic Properties. c Dr Oksana Shatalov, Fall

Chapter Six. More Integration

Math 341 Summer 2016 Midterm Exam 2 Solutions. 1. Complete the definitions of the following words or phrases:

VII.5. The Weierstrass Factorization Theorem

f(w) f(a) = 1 2πi w a Proof. There exists a number r such that the disc D(a,r) is contained in I(γ). For any ǫ < r, w a dw

Continuity. MATH 161 Calculus I. J. Robert Buchanan. Fall Department of Mathematics

Calculus I Exam 1 Review Fall 2016

ζ(u) z du du Since γ does not pass through z, f is defined and continuous on [a, b]. Furthermore, for all t such that dζ

Math Review for Exam Answer each of the following questions as either True or False. Circle the correct answer.

Section 9.7 and 9.10: Taylor Polynomials and Approximations/Taylor and Maclaurin Series

M17 MAT25-21 HOMEWORK 6

Characterisation of Accumulation Points. Convergence in Metric Spaces. Characterisation of Closed Sets. Characterisation of Closed Sets

Connectedness. Proposition 2.2. The following are equivalent for a topological space (X, T ).

CHAPTER 6. Limits of Functions. 1. Basic Definitions

Consequences of Continuity and Differentiability

and lim lim 6. The Squeeze Theorem

4. We accept without proofs that the following functions are differentiable: (e x ) = e x, sin x = cos x, cos x = sin x, log (x) = 1 sin x

III. Consequences of Cauchy s Theorem

P-adic Functions - Part 1

1.10 Continuity Brian E. Veitch

Section 8.7. Taylor and MacLaurin Series. (1) Definitions, (2) Common Maclaurin Series, (3) Taylor Polynomials, (4) Applications.

L p Functions. Given a measure space (X, µ) and a real number p [1, ), recall that the L p -norm of a measurable function f : X R is defined by

Department of Mathematics, University of California, Berkeley. GRADUATE PRELIMINARY EXAMINATION, Part A Fall Semester 2016

h(x) lim H(x) = lim Since h is nondecreasing then h(x) 0 for all x, and if h is discontinuous at a point x then H(x) > 0. Denote

AP Calculus (BC) Chapter 9 Test No Calculator Section Name: Date: Period:

PRACTICE PROBLEMS FOR MIDTERM I

Math 227 Sample Final Examination 1. Name (print) Name (sign) Bing ID number

The Plane of Complex Numbers

MAS331: Metric Spaces Problems on Chapter 1

Review of complex analysis in one variable

Exam 2 extra practice problems

MASTERS EXAMINATION IN MATHEMATICS SOLUTIONS

Exercises from other sources REAL NUMBERS 2,...,

From the definition of a surface, each point has a neighbourhood U and a homeomorphism. U : ϕ U(U U ) ϕ U (U U )

MT804 Analysis Homework II

MA3111S COMPLEX ANALYSIS I

Math 320: Real Analysis MWF 1pm, Campion Hall 302 Homework 8 Solutions Please write neatly, and in complete sentences when possible.

Most Continuous Functions are Nowhere Differentiable

UNIVERSITY OF CALICUT SCHOOL OF DISTANCE EDUCATION CORE COURSE. B.Sc. MATHEMATICS V SEMESTER. (2011 Admission onwards) BASIC MATHEMATICAL ANALYSIS

Chapter 8: Taylor s theorem and L Hospital s rule

Preliminary Exam 2018 Solutions to Morning Exam

Complex Variables Notes for Math 703. Updated Fall Anton R. Schep

Continuity. To handle complicated functions, particularly those for which we have a reasonable formula or formulas, we need a more precise definition.

Transcription:

IV.3. Zeros of an Analytic Function 1 IV.3. Zeros of an Analytic Function Note. We now explore factoring series in a way analogous to factoring a polynomial. Recall that if p is a polynomial with a zero a of multiplicity m, then p(z) = (z a) m t(z) for a polynomial t(z) such that t(a) 0. Definition. If f : G C is analytic and a G satisfies f(a) = 0, then a is a zero of multiplicity m 1 if there is analytic g : G C such that f(z) = (z a) m g(z) where g(a) 0. Note. The reader might be pleasantly surprised to know that after many years of studying Mathematics he is right now on the threshold of proving the Fundamental Theorem of Algebra. (page 76) Definition. An entire function is a function analytic in the entire complex plane. Entire functions are sometimes called integral functions. Note. An area of study in complex analysis is entire function theory. A classical book in this area is Ralph Boas Entire Functions (Academic Press, 1954). Results in this are often concern factorization and rates of growth (see Conway s Chapter XI). Note/Proposition IV.3.3. If f is an entire function then f(z) = infinite radius of convergence. a n z n with n=0

IV.3. Zeros of an Analytic Function 2 Theorem IV.3.4. Liouville s Theorem. If f is a bounded entire function then f is constant. Proof. Suppose f(z) M for all z C. By Cauchy s Estimate (Corollary IV.2.14) with n = 1, f (z) M/R for any disk B(z;R). Since f is entire, the inequality holds for all R and with R we see that f (z) = 0 for all z C. Therefore, f is a constant function by Proposition III.2.10. Note. Notice the quote on page 77! The reader should not be deceived into thinking that this theorem is insignificant because it has such a short proof. We have expended a great deal of effort building up machinery and increasing our knowledge of analytic functions. We have plowed, planted, and fertilized; we shouldn t be surprised if, occasionally, something is available for easy picking. Of course, Liouville s Theorem does not hold for functions of a real variable: Consider sin x, cosx, 1/(x 2 + 1). Note. As you will see in Field Theory, there is no purely algebraic proof of the Fundamental Theorem of Algebra. One proof (the one from my graduate algebra class) uses the fact that an odd degree real polynomial has a real zero. That is, it uses the Intermediate Value Theorem from analysis. We now give a proof of the Fundamental Theorem of Algebra which is analytic (i.e., uses analysis) and is based primarily on Liouville s Theorem.

IV.3. Zeros of an Analytic Function 3 Theorem IV.3.5. Fundamental Theorem of Algebra. If p(z) is a nonconstant polynomial then there is a complex number a with p(a) = 0. Proof. Assume not. ASSUME p(z) 0 for all z C. Let f(z) = 1/p(z). Then f is an entire function. If p is not constant, then p(z) = a n z n +a n 1 z n 1 + +a 1 z+a 0 where n 1 and so lim p(z) = lim z z z n (a n + a n 1 z 1 + + a 0 z n ) = lim z z n lim z an + a n 1 z 1 + + a 0 z n =. So lim f(z) = lim = 0. Therefore, for some R > 0 we have f(z) < 1 for z p(z) z > R. Since f is continuous on B(0;R) and B(0;R) is compact, there is a z 1 constant M > 0 such that f(z) M for z R by Corollary II.5.2. Then f is an entire function bounded by max{m, 1}. So by Liouville s Theorem (Theorem IV.3.4), f must be constant and so p is constant, a CONTRADICTION. So the assumption that p(z) 0 for all z C is false and p has some zero in C. Note. With this version of the Fundamental Theorem of Algebra, other versions follow (such as an nth degree complex polynomial can be factored into a product of n linear terms). Note. The following result puts some restrictions on analytic functions in terms of the zeros of the function.

IV.3. Zeros of an Analytic Function 4 Theorem IV.3.7. Let G be a connected open set and let f : G C be analytic. The following are equivalent. (a) f 0 on G, (b) there is a point a G such that f (n) (a) = 0 for all n Z, n 0, and (c) the set {z G f(z) = 0} has a limit point in G. Note. Theorem IV.3.7 does not hold for functions of a real variable (where we take analytic to mean continuously differentiable). Recall that e 1/x2, x > 0 f(x) = 0, x 0 is infinitely differentiable for all x R and f (n) (0) = 0 for all n Z, n 0, but f 0 on R (so (b) does not imply (a)). Recall x 2 sin(1/x), x 0 g(x) = 0, x = 0 has zeros {x R x = 1/(nπ),n Z} {0}. So g is continuously differentiable on R and the set of zeros has a limit point, but g 0 on R. That is, (c) does not imply (a). Corollary IV.3.8. If f and g are analytic on a region G (where G is an open connected set), then f g if and only if {z G f(z) = g(z)} has a limit point in G.

IV.3. Zeros of an Analytic Function 5 Note. Corollary IV.3.8 does not hold in R. Consider f(x) 0 and x 2 sin(1/x), x 0 g(x) = 0, x = 0. Note. Theorem IV.3.7 allows us to factor analytic functions as given in the following. Corollary IV.3.9. If f is analytic on an open connected set G and f is not identically zero then for each a G with f(a) = 0, there is n N and an analytic function g : G C such that g(a) 0 and f(z) = (z a) n g(z) for all z G. That is, each zero of f has finite multiplicity. Corollary IV.3.10. If f : G C is analytic and not constant, then for any a G where f(a) = 0, there is an R > 0 such that B(a;R) G and f(z) 0 for 0 < z a < R. Note. The following is extremely important! At least, I often use it in my complex research. Theorem IV.3.11. Maximum Modulus Theorem. If G is a region and f : G C is an analytic function such that there is a point a G with f(a) f(z) for all z G, then f is constant.

IV.3. Zeros of an Analytic Function 6 Recall. Exercise III.3.17 says: Let G be a region and suppose that f : G C is analytic such that f(g) is a subset of a circle or a line. Then f is constant. Now for the proof of the Maximum Modulus Theorem. Note. There are several other results and generalizations related to the Maximum Modulus Theorem in Section VI.1 An easy one is the following. Theorem VI.1.2. Maximum Modulus Theorem Second Version. Let G be a bounded open set in C and suppose f is a continuous function on G which is analytic in G. Then max{ f(z) z G} = max{ f(z) z G}. (G is G closure and G is the boundary of G.) Revised: 1/22/2018

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback