The Secant-Line Calculation of the Derivative

Slides:

Advertisements

Similar presentations

Tangent Lines Section 2.1.

Advertisements

The Derivative.

Tangent Lines Section 2.1.

DERIVATIVES 3. DERIVATIVES In this chapter, we begin our study of differential calculus.  This is concerned with how one quantity changes in relation.

The Derivative Eric Hoffman Calculus PLHS Sept

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.

THE DERIVATIVE AND THE TANGENT LINE PROBLEM

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

3.3 Differentiation Formulas

FURTHER APPLICATIONS OF INTEGRATION 9. In chapter 6, we looked at some applications of integrals:  Areas  Volumes  Work  Average values.

The Derivative. Objectives Students will be able to Use the “Newton’s Quotient and limits” process to calculate the derivative of a function. Determine.

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.

Chapter 3 The Derivative Definition, Interpretations, and Rules.

Rational Functions and Their Graphs. Example Find the Domain of this Function. Solution: The domain of this function is the set of all real numbers not.

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))

DIFFERENTIATION Differentiation is about rates of change. Differentiation is all about finding rates of change of one quantity compared to another. We.

CALCULUS I Chapter II Differentiation Mr. Saâd BELKOUCH.

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,

AP CALCULUS AB Chapter 4: Applications of Derivatives Section 4.5:

2.1 The Derivative and the Tangent Line Problem

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

Implicit Differentiation

Announcements Topics: -finish section 4.2; work on sections 4.3, 4.4, and 4.5 * Read these sections and study solved examples in your textbook! Work On:

Calculus 1.1: Review of Trig/Precal A. Lines 1. Slope: 2. Parallel lines—Same slope Perpendicular lines—Slopes are opposite reciprocals 3. Equations of.

Business Mathematics MTH-367 Lecture 21. Chapter 15 Differentiation.

Algebra of Limits Assume that both of the following limits exist and c and is a real number: Then:

Section 5.4a FUNDAMENTAL THEOREM OF CALCULUS. Deriving the Theorem Let Apply the definition of the derivative: Rule for Integrals!

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.

DIFFERENTIATION RULES

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

Unit 1 Limits. Slide Limits Limit – Assume that a function f(x) is defined for all x near c (in some open interval containing c) but not necessarily.

1.6 – Tangent Lines and Slopes Slope of Secant Line Slope of Tangent Line Equation of Tangent Line Equation of Normal Line Slope of Tangent =

The Derivative Function

Chapter 3.1 Tangents and the Derivative at a Point.

Determine if exists for the functions in the following graphs.

5.3 Definite Integrals and Antiderivatives Objective: SWBAT apply rules for definite integrals and find the average value over a closed interval.

Powerpoint Templates Page 1 Powerpoint Templates Review Calculus.

Math 1304 Calculus I 2.3 – Rules for Limits.

Implicit Differentiation Objective: To find derivatives of functions that we cannot solve for y.

Section 5.5 The Intermediate Value Theorem Rolle’s Theorem The Mean Value Theorem 3.6.

3 DIFFERENTIATION RULES. We have:  Seen how to interpret derivatives as slopes and rates of change  Seen how to estimate derivatives of functions given.

Aim: How do we find the derivative by limit process? Do Now: Find the slope of the secant line in terms of x and h. y x (x, f(x)) (x + h, f(x + h)) h.

1.8 The Derivative as a Rate of Change. An important interpretation of the slope of a function at a point is as a rate of change.

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

OBJECTIVES: To introduce the ideas of average and instantaneous rates of change, and show that they are closely related to the slope of a curve at a point.

Local Linear Approximation Objective: To estimate values using a local linear approximation.

Limits Involving Infinity Infinite Limits We have concluded that.

Learning Objectives for Section 10.4 The Derivative

Index FAQ The derivative as the slope of the tangent line (at a point)

Derivatives of Logarithmic Functions Objective: Obtain derivative formulas for logs.

3/18/2016Mr. Santowski - Calculus1 Lesson 31 (Day 2) - Limits Calculus - Mr Santowski.

Limits An Introduction To Limits Techniques for Calculating Limits

Differential and Integral Calculus Unit 2. Differential and Integral Calculus Calculus is the study of “Rates of Change”.  In a linear function, the.

Announcements Topics: -sections (differentiation rules), 5.6, and 5.7 * Read these sections and study solved examples in your textbook! Work On:

2.1 The Derivative and the Tangent Line Problem Objectives: -Students will find the slope of the tangent line to a curve at a point -Students will use.

Calculus Section 3.1 Calculate the derivative of a function using the limit definition Recall: The slope of a line is given by the formula m = y 2 – y.

§ 4.2 The Exponential Function e x.

Math 1304 Calculus I 2.3 – Rules for Limits.

§ 1.3 The Derivative.

The Tangent Line Problem

Techniques of Differentiation

Definition of the Derivative

Derivatives by Definition

THE DERIVATIVE AND THE TANGENT LINE PROBLEM

Tangent line to a curve Definition: line that passes through a given point and has a slope that is the same as the.

Tangent line to a curve Definition: line that passes through a given point and has a slope that is the same as the.

Tangent Line Recall from geometry

30 – Instantaneous Rate of Change No Calculator

Differentiation Using Limits of Difference Quotients

Presentation transcript:

The Secant-Line Calculation of the Derivative

We have said that the derivative gives the slope of the tangent line and presented formulas for calculating the derivative for various curves. However, we have not discussed how these formulas were derived.

The fundamental idea for calculating the slope of the tangent line at a point P is to approximate the tangent line very closely by secant lines. A secant line at P is a straight line passing through P and a nearby point Q on the curve.

As we take Q closer to P, the accuracy with which the slope of the secant line approximates the slope of the tangent line increases.

Suppose that the point P is (x, f(x)) and that Q is h horizontal units away from P. Q will have x-coordinate x+h, and y-coordinate f(x+h). Recall that the slope of a line is given by the slope of a line through points (x1,y1) and (x2, y2) =

Then slope of the secant line through the points P and Q is slope of secant line =

In order to improve the accuracy of our secant line approximation of the tangent line, we move Q closer to P by letting h approach 0. Then, the slope of the secant line approaches the slope of the tangent line and approaches f’(x)

Then, let h approach zero. The quantity To calculate f’(x) using a secant line approximation, calculate the difference quotient Then, let h approach zero. The quantity will approach f’(x).

Verification of the Power Rule for r = 2 Let f(x) = x2. By the Power Rule, f’(x) = 2x. By using the secant line approximation, we have slope of secant line =

As h approaches 0, 2x + h approaches 2x.

1.4 Limits and the Derivative

The notion of a limit is a fundamental idea of calculus. Although we did not explicitly state it, we were using the concept of a limit in the previous section.

Using the geometric reasoning from the previous section, we have the following procedure for calculating the derivative of a function f(x) at x = a.

Calculate the difference quotient Let h approach zero by allowing it to assume both positive and negative values arbitrarily close to but different from zero. The quantity will approach f’(a).

We say that the number f’(a) is the limit of the difference quotient as h approaches zero and we write this as

Consider the case where f(x) = x2 at x = 2. The difference quotient has the form Letting h approach zero from the positive side shows that the difference quotient approaches 4.

As does letting h approach zero from the negative side

In other words, 4 is the limit of the difference quotient as h approaches zero Since the value of the difference quotient approaches the derivative f’(2), we conclude that f’(2) = 4.

We say that f is differentiable at x = a if approaches some number as h approaches zero. If the difference quotient does not approach any specific number as h approaches zero, then we say f is nondifferentiable at x = a. We can look at limits in a more general way.

Let g(x) be a function and a be a number Let g(x) be a function and a be a number. We say that L is the limit of g(x) as x approaches a provided that g(x) can be made arbitrarily close to L by taking x sufficiently close (but not equal) to a. We write this as If, as x approaches a, g(x) does not approach a specific number, we say that the limit of g(x) as x approaches a does not exist.

Determine

We can examine the values of 3x – 5 as x approaches 2 from both sides

As x approaches 2, we see that 3x – 5 approaches 1. We conclude that

Determine if exists for the functions in the following graphs

Limit Theorems

Then we have the following theorems. Suppose that and both exist. Then we have the following theorems.

Examples

Limit of a Polynomial Function Let p(x) be a polynomial function and a any number. Then

Limit of a Rational Function Let r(x) = p(x)/q(x) be a rational function where p(x) and q(x) are polynomials. Let a be a number such that q(a) does not equal zero. Then,

The basic rules of differentiation are obtained from the limit definition of the derivative. There are three main steps for calculating the derivative of a function f(x) at x = a. 1. Write the difference quotient 2. Simplify the difference quotient. 3. Find the limit as h approaches zero.

Infinity and Limits Consider the function f(x) whose graph is As x increases, the value of f(x) approaches 2.

In this case, we say that the limit of f(x) as x approaches infinity is 2. We express this using limit notation as

Similarly, if we examine the following graph, we will note that as x grows large in the negative direction, the value of f(x) approaches 0.

We express this using limit notation as

Example