Section 2.2 Limits and Continuity

Slides:

Advertisements

Similar presentations

MAT 3749 Introduction to Analysis Section 2.1 Part 1 Precise Definition of Limits

Advertisements

1 Week 4 Complex numbers: analytic functions 1. Differentiation of complex functions 2. Cauchy’s Integral Theorem.

ESSENTIAL CALCULUS CH11 Partial derivatives

MA Day 24- February 8, 2013 Section 11.3: Clairaut’s Theorem Section 11.4: Differentiability of f(x,y,z) Section 11.5: The Chain Rule.

MAT 1221 Survey of Calculus Section 1.5 Limits

§2 Limits and continuity 2.1 Some important definitions and results about functions.

The right-hand limit of f (x), as x approaches a, equals L written: if we can make the value f (x) arbitrarily close to L by taking x to be sufficiently.

The Precise Definition of Limit Augustin-Louis Cauchy Karl Weierstrass.

Unit 12. Unit 12: Sequences and Series Vocabulary.

 Related Rates ◦ Idea:  Given two quantities that 1.Are somehow related 2.Changing (usually w.r.t. time)  The problem is to find how one of these quantities.

LIMITS AND CONTINUITY OF FUNCTIONS Introduction to Limits “ I’m nearing the limit of my patience” Consider the function determined by the formula Note.

Complex Differentiation Mohammed Nasser Department of statistics RU.

1.6 Limits involving infinity. Infinite limits Definition: The notation (read as “the limit of of f(x), as x approaches a, is infinity”) means that the.

1.3 The limit of a function. A rock falls from a high cliff. The position of the rock is given by: After 2 seconds: average speed: What is the instantaneous.

The Derivative. Definition Example (1) Find the derivative of f(x) = 4 at any point x.

Rules for Differentiating Univariate Functions Given a univariate function that is both continuous and smooth throughout, it is possible to determine its.

LIMITS 2. LIMITS 2.4 The Precise Definition of a Limit In this section, we will: Define a limit precisely.

Chapter 3 The Derivative Definition, Interpretations, and Rules.

The Secant-Line Calculation of the Derivative

CHAPTER Continuity Derivatives Definition The derivative of a function f at a number a denoted by f’(a), is f’(a) = lim h  0 ( f(a + h) – f(a))

MAT 3749 Introduction to Analysis Section 2.1 Part 3 Squeeze Theorem and Infinite Limits

Infinite Limits and Limits to Infinity: Horizontal and Vertical Asymptotes.

Section 1.4: Continuity and One-Sided Limits

Limits and Derivatives Concept of a Function y is a function of x, and the relation y = x 2 describes a function. We notice that with such a relation,

Section 2.1 INTRODUCTION TO LIMITS. Definition of a Limit  Limits allow us to describe how the outputs of a function (usually the y or f(x) values) behave.

Chapter 3 Limits and the Derivative Section 1 Introduction to Limits.

1.2 Finding Limits Graphically & Numerically. After this lesson, you should be able to: Estimate a limit using a numerical or graphical approach Learn.

MA Day 25- February 11, 2013 Review of last week’s material Section 11.5: The Chain Rule Section 11.6: The Directional Derivative.

1 Week 5 Linear operators and the Sturm–Liouville theory 1.Complex differential operators 2.Properties of self-adjoint operators 3.Sturm-Liouville theory.

Precise definition of limits The phrases “x is close to a” and “f(x) gets closer and closer to L” are vague. since f(x) can be arbitrarily close to 5 as.

Chapter 0ne Limits and Rates of Change up down return end.

The Derivative Function

In this section, we will consider the derivative function rather than just at a point. We also begin looking at some of the basic derivative rules.

Math 1304 Calculus I 2.4 – Definition for Limits.

Section 3.4 The Chain Rule. Consider the function –We can “decompose” this function into two functions we know how to take the derivative of –For example.

Math 1304 Calculus I 2.3 – Rules for Limits.

1.4 One-Sided Limits and Continuity. Definition A function is continuous at c if the following three conditions are met 2. Limit of f(x) exists 1. f(c)

3 DERIVATIVES.  Remember, they are valid only when x is measured in radians.  For more details see Chapter 3, Section 4 or the PowerPoint file Chapter3_Sec4.ppt.

Ch.3 The Derivative. Differentiation Given a curve y = f(x ) Want to compute the slope of tangent at some value x=a. Let A=(a, f(a )) and B=(a +  x,

In this section, we will investigate the idea of the limit of a function and what it means to say a function is or is not continuous.

Section 1.4 – Continuity and One-Sided Limits

11 PARTIAL DERIVATIVES.

DO NOW:  Find the equation of the line tangent to the curve f(x) = 3x 2 + 4x at x = -2.

Chapter 3 Limits and the Derivative Section 1 Introduction to Limits.

MTH 251 – Differential Calculus Chapter 3 – Differentiation Section 3.2 The Derivative as a Function Copyright © 2010 by Ron Wallace, all rights reserved.

MAT 1221 Survey of Calculus Section 2.2 Some Rules for Differentiation

Directional Derivatives. Example…What ’ s the slope of at (0,1/2)? What’s wrong with the way the question is posed? What ’ s the slope along the direction.

MAT 3730 Complex Variables Section 1.6 Planar Sets

Section 6.2* The Natural Logarithmic Function. THE NATURAL LOGARITHMIC FUNCTION.

Limits Involving Infinity Section 1.4. Infinite Limits A limit in which f(x) increases or decreases without bound as x approaches c is called an infinite.

3.1 Derivative of a Function Definition Alternate Definition One-sided derivatives Data Problem.

Section 15.2 Limits and Continuity. Let f be a function of two variables whose domain D includes points arbitrarily close to (a, b). Then we say the limit.

Math 1304 Calculus I 2.8 – The Derivative. Definition of Derivative Definition: The derivative of a function f at a number a, denoted by f’(a) is given.

MAT 3730 Complex Variables Section 2.4 Cauchy Riemann Equations

Limits and Continuity. Introduction Recall that for a function of one variable, the mathematical statement means that for x close enough to c, the difference.

2.4 – Definition for Limits

Week 4 Complex numbers: analytic functions

Section 6.2 Constructing Antiderivatives Analytically

Chain Rules for Functions of Several Variables

Complex Variables. Complex Variables Open Disks or Neighborhoods Definition. The set of all points z which satisfy the inequality |z – z0|

Derivative of a Function

Section 3.2 The Exponential, Trigonometric, and Hyperbolic Functions

Section 4.2 Contour Integrals

Relations and Functions

Week 4 Complex numbers: analytic functions

The Limit of a Function.

Limits and Continuity An introduction to Limits and how we will be using them.

1.5: Limits We will learn about: limits, finding limits,

2.2 Infinite Limits and Limits at Infinity

Presentation transcript:

Section 2.2 Limits and Continuity MAT 3730 Complex Variables Section 2.2 Limits and Continuity http://myhome.spu.edu/lauw

Preview We will follow a similar path of real variables to define the derivative of complex functions We will look at the conceptual idea of taking limits without going into the precise definition (MAT 3749 Intro Analysis)

Default All coefficients are complex numbers All functions are complex-valued functions

Recall (Real Variables) Functions Limits Continuity Derivatives

Complex Variables Functions Limits Continuity Derivatives Analyticity

Recall: Limits of Real Functions Left hand Limit Right Hand Limit Limit

Left-Hand Limit (Real Variables) y The left-hand limit is 2 when x approaches 3 Notation: Independent of f(3) 2 y=f(x) x 3

Left-Hand Limit (Real Variables) We write and say “the left-hand limit of f(x), as x approaches a, equals L” if we can make the values of f(x) arbitrarily close to L (as close as we like) by taking x to be sufficiently close to a and x less than a.

Right-Hand Limit (Real Variables) y The right-hand limit is 4 when x approaches 2 Notation: Independent of f(2) 4 y=f(x) x 2

Right-Hand Limit (Real Variables) We write and say “the right-hand limit of f(x), as x approaches a, equals L” if we can make the values of f(x) arbitrarily close to L (as close as we like) by taking x to be sufficiently close to a and x greater than a.

Limit of a Function (Real Variables) if and only if and Independent of f(a)

Observations The limit exists if the limits along all possible paths exist and equal The existence of the limit is independent of the existence and value of f(a)

Definition (Conceptual) w0 is the limit of f(z) as z approaches z0 , if f(z) stays arbitrarily close to w0 whenever z is sufficiently near z0

Observations (Complex Limits) The limit exists if the limits along all possible paths exist and equal There are infinitely many paths 2 paths with 2 different limits prove non-existence Use the precise definition to prove the existence The existence of the limit is independent of the existence and value of f(z0)

Observations (Complex Limits) The limit exists if the limits along all possible paths exist and equal There are infinitely many paths 2 paths with 2 different limiting values prove non-existence Use the precise definition to prove the existence The existence of the limit is independent of the existence and value of f(z0)

Observations (Complex Limits) The limit exists if the limits along all possible paths exist and equal There are infinitely many paths 2 paths with 2 different limiting values prove non-existence Use the precise definition to prove the existence The existence of the limit is independent of the existence and value of f(z0)

Definition Let f be a function defined in a nhood of z0. Then f is continuous at z0 if

The Usual…. We are going to state the following standard results without going into the details.

Theorem

Theorem

Common Continuous Functions

Example 1

MAT 3730 Complex Variables Section 2.3 Analyticity http://myhome.spu.edu/lauw

Preview We are going to look at Definition of Derivatives Rules of Differentiation Definition of Analytic Functions

Definition Let f be a function defined on a nhood of z0. Then the derivative of f at z0 is given by provided this limit exists. f is said to be differentiable at z0

Example 2

(The Usual…) Rules of Differentiation

Example 3 (a)

Example 3 (b)

(The Usual…) The Chain Rule

Definition A function f is said to be analytic on an open set G if it has a derivative at every point of G f is analytic at a point z0 means f is analytic on an nhood of a point z0

Example 4

Example 4

Next Class Section 2.4