Today: Limits Involving Infinity lim f(x) =  x -> a Infinite limits Limits at infinity lim f(x) = L x -> 

Slides:

Advertisements

Similar presentations

2.2 Limits Involving Infinity

Advertisements

Graph of Exponential Functions

C hapter 3 Limits and Their Properties. Section 3.1 A Preview of Calculus.

LIMITS The Limit of a Function LIMITS In this section, we will learn: About limits in general and about numerical and graphical methods for computing.

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.

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

1 Chapter 2 Limits and Continuity Rates of Change and Limits.

LIMITS The Limit of a Function LIMITS Objectives: In this section, we will learn: Limit in general Two-sided limits and one-sided limits How to.

APPLICATIONS OF DIFFERENTIATION 4. In Sections 2.2 and 2.4, we investigated infinite limits and vertical asymptotes.  There, we let x approach a number.

Exponential Growth and Decay Newton’s Law Logistic Growth and Decay

CHAPTER 2 LIMITS AND DERIVATIVES. 2.2 The Limit of a Function LIMITS AND DERIVATIVES In this section, we will learn: About limits in general and about.

LIMITS INVOLVING INFINITY Mrs. Erickson Limits Involving Infinity Definition: y = b is a horizontal asymptote if either lim f(x) = b or lim f(x) = b.

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

Chapter 1 Limit and their Properties. Section 1.2 Finding Limits Graphically and Numerically I. Different Approaches A. Numerical Approach 1. Construct.

Ms. Battaglia AB/BC Calculus. Let f be the function given by 3/(x-2) A limit in which f(x) increases or decreases without bound as x approaches c is called.

Exponential and Logarithmic Equations

Section 6.3 – Exponential Functions Laws of Exponents If s, t, a, and b are real numbers where a > 0 and b > 0, then: Definition: “a” is a positive real.

CHAPTER Continuity Derivatives and the Shapes of Curves.

LIMITS AND DERIVATIVES 2. In Sections 2.2 and 2.4, we investigated infinite limits and vertical asymptotes.  There, we let x approach a number.  The.

APPLICATIONS OF DIFFERENTIATION 4. A polynomial behaves near infinity as its term of highest degree. The polynomial behaves like the polynomial Near infinity.

1.3 Twelve Basic Functions

INTRODUCTORY MATHEMATICAL ANALYSIS For Business, Economics, and the Life and Social Sciences  2007 Pearson Education Asia Chapter 10 Limits and Continuity.

2.6 – Limits involving Infinity, Asymptotes

Rational Functions - Rational functions are quotients of polynomial functions: where P(x) and Q(x) are polynomial functions and Q(x)  0. -The domain of.

In Sections 2.2 and 2.4, we investigated infinite limits and vertical asymptotes.  There, we let x approach a number.  The result was that the values.

Chapter 1: Functions and Graphs

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

1 2.6 – Limits Involving Infinity. 2 Definition The notation means that the values of f (x) can be made arbitrarily large (as large as we please) by taking.

Copyright © 2010 Pearson Education, Inc. All rights reserved Sec

Limits and Derivatives

LIMITS AND DERIVATIVES The Limit of a Function LIMITS AND DERIVATIVES In this section, we will learn: About limits in general and about numerical.

Copyright © Cengage Learning. All rights reserved. 2 Limits and Derivatives.

INTRODUCTORY MATHEMATICAL ANALYSIS For Business, Economics, and the Life and Social Sciences  2011 Pearson Education, Inc. Chapter 10 Limits and Continuity.

3.4 Review: Limits at Infinity Horizontal Asymptotes.

–1 –5–4–3–2– Describe the continuity of the graph. Warm UP:

2.6 Limits at Infinity: Horizontal Asymptotes LIMITS AND DERIVATIVES In this section, we: Let x become arbitrarily large (positive or negative) and see.

Chapter 2: Limits 2.2 The Limit of a Function. Limits “the limit of f(x), as x approaches a, equals L” If we can make the values of f(x) arbitrarily close.

1.5 Infinite Limits. Find the limit as x approaches 2 from the left and right.

Limits Involving Infinity Infinite Limits We have concluded that.

Lesson 3.5 Limits at Infinity. From the graph or table, we could conclude that f(x) → 2 as x → Graph What is the end behavior of f(x)? Limit notation:

Section Infinite Limits

3.1 Exponential and Logistic Functions. Exponential functions Let a and b real number constants. An exponential function in x is a function that can be.

Suppose you drive 200 miles, and it takes you 4 hours. Then your average speed is: If you look at your speedometer during this trip, it might read 65 mph.

Section 2.2 The Limit of a Function AP Calculus September 10, 2009 CASA.

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.

College Algebra Chapter 3 Polynomial and Rational Functions Section 3.5 Rational Functions.

Infinite Limits Unit IB Day 5. Do Now For which values of x is f(x) = (x – 3)/(x 2 – 9) undefined? Are these removable or nonremovable discontinuities?

LIMITS The Limit of a Function LIMITS In this section, we will learn: About limits in general and about numerical and graphical methods for computing.

L OGISTIC E QUATIONS Sect. 8-6 continued. Logistic Equations Exponential growth (or decay) is modeled by In many situations population growth levels off.

College Algebra Chapter 3 Polynomial and Rational Functions

Graph Sketching: Asymptotes and Rational Functions

2.2 Limits Involving Infinity

Horizontal Asymptotes

OUR GOAL Find: Sec 2.2: Limit of Function and Limit Laws

Prep Book Chapter 3 - Limits of Functions

2.2 Limits at Infinity: Horizontal Asymptotes

Limits involving infinity

Chapter 2 Limits and Continuity

Limits and Continuity Chapter 2:.

More Properties of Functions

Notes Over 8.8 Evaluating a Logistic Growth Function

In symbol, we write this as

Limits, Continuity and Definition of Derivative

In symbol, we write this as

Chapter 12: Limits, Derivatives, and Definite Integrals

Calc Limits involving infinity

Consider the function Note that for 1 from the right from the left

AP Calculus Chapter 1, Section 5

Logistic Growth Evaluating a Logistic Growth Function

2.2 Infinite Limits and Limits at Infinity

Presentation transcript:

Today: Limits Involving Infinity lim f(x) =  x -> a Infinite limits Limits at infinity lim f(x) = L x -> 

CHAPTER Continuity Infinite Limits (see Sec 2.2, pp )

CHAPTER Continuity Definition Let f be a function defined on both sides of a, except possibly at a itself. Then lim f(x) =  x -> a means that the values of f(x) can be made arbitrarily large by taking x close enough to a.

Another notation for lim x - > a f(x) =  is “f(x) -- >  as x -- > a” For such a limit, we say: “the limit of f(x), as x approaches a, is infinity” “f(x) approaches infinity as x approaches a” “f(x) increases without bound as x approaches a”

What about f(x) = 1/x, as x -- > 0 ?

Definition The line x = a is called a vertical asymptote of the curve y = f(x) if at least one of the following statements is true: lim f(x) =  lim f(x) = -  lim f(x) = - . x -- > a + x -- > a - x -- > a +

Example:

Example Find the vertical asymptotes of f(x) = ln (x – 5).

CHAPTER Continuity Sec 2.6: Limits at Infinity f(x) = (x 2 -1) / (x 2 +1) f(x) = e x

CHAPTER Continuity 4 Sec 2.6: Limits at Infinity f(x) = tan -1 x f(x) = 1/x

CHAPTER Continuity Sec 2.6: Limits at Infinity animation

Let f be a function defined on some interval (a,  ). Then lim f (x) = L x - >  means that the values of f(x) can be made arbitrarily close to L by taking x sufficiently large. Definition: Limit at Infinity

Definition The line y = L is called a horizontal asymptote of the curve y = f(x) if either lim f(x) = L or lim f(x) = L. x ->  x -> -  lim tan - 1(x)= -  /2 x -> -  lim tan –1 (x) =  /2. x -> 

If n is a positive integer, then lim 1/ x n = 0 lim 1/ x n = 0. x-> -  x-> -  lim e x = 0. x-> - 

Example lim (7t 3 + 4t ) / (2t 3 - t 2 + 3). x-> - 

We know lim x-> -  e x = 0. What about lim x->  e x ? f(x) = e x

So lim t ->  Ae rt =  for any r > 0. Say P(t) = Ae rt represents a population at time t. This is a mathematical model of “exponential growth,” where r is the growth rate and A is the initial population. See Exponential Growth Model

Exponential growth (r > 0) Exponential decay (r < 0) For f(t) = Ae rt : Exponential Growth/Decay

A more complicated model of population growth is the logistic equation: P(t) = K / (1 + Ae –rt ) What is lim t ->  P(t) ? In this model, K represents a “carrying capacity”: the maximum population that the environment is capable of sustaining. Logistic Growth Model

Logistic equation as a model of yeast growth Logistic Growth Model