Presentation is loading. Please wait.

Presentation is loading. Please wait.

Section 3.2 Differentiability.

Published byFlorence Higgins Modified over 5 years ago

Similar presentations

Presentation on theme: "Section 3.2 Differentiability."— Presentation transcript:

1 Section 3.2 Differentiability

2 How f’(a) Might Fail to Exist
A corner, where the one-sided derivatives differ

3 How f’(a) Might Fail to Exist
A cusp, where the slopes of the secant lines approach  from one side and - from the other (an extreme case of a corner):

4 How f’(a) Might Fail to Exist
A vertical tangent, where the slopes of the secant lines approach either  or - from both sides.

5 How f’(a) Might Fail to Exist
A discontinuity, which will cause one or both of the one-sided derivatives to be nonexistent.

6 Example 1 Find all the points in the domain where f is not differentiable.

7 Example 2 Compute the numerical derivative.

8 Example 3 Compute the numerical derivative.

9 Example 4 Let f(x) = lnx. Use NDERIV to graph y = f’(x). Can you guess what function f’(x) is by analyzing its graph?

10 Differentiability Implies Continuity
Theorem 1: Differentiability Implies Continuity: If f has a derivative at x = a, then f is continuous at x = a.

11 Intermediate Value Theorem for Derivatives
Theorem 2: Intermediate Value Theorem for Derivatives: If a and b are any two points in an interval on which f is differentiable, then f’ takes on every value between f’(a) and f’(b).

Download ppt "Section 3.2 Differentiability."

Similar presentations

DERIVATIVE OF A FUNCTION 1.5. DEFINITION OF A DERIVATIVE OTHER FORMS: OPERATOR:,,,

DERIVATIVE OF A FUNCTION 1.5. DEFINITION OF A DERIVATIVE OTHER FORMS: OPERATOR:,,,
2.1 Tangent Line Problem. Tangent Line Problem The tangent line can be found by finding the slope of the secant line through the point of tangency and.

2.1 Tangent Line Problem. Tangent Line Problem The tangent line can be found by finding the slope of the secant line through the point of tangency and.
2.1 The derivative and the tangent line problem

2.1 The derivative and the tangent line problem
THE DERIVATIVE AND THE TANGENT LINE PROBLEM

THE DERIVATIVE AND THE TANGENT LINE PROBLEM
4.2 The Mean Value Theorem.

4.2 The Mean Value Theorem.
Derivative as a Function

Derivative as a Function
Chapter 2 Section 2 The Derivative!. Definition The derivative of a function f(x) at x = a is defined as f’(a) = lim f(a+h) – f(a) h->0 h Given that a.

Chapter 2 Section 2 The Derivative!. Definition The derivative of a function f(x) at x = a is defined as f’(a) = lim f(a+h) – f(a) h->0 h Given that a.
The Derivative. Def: The derivative of a function f at a number a, denoted f’(a) is: Provided this limit exists.

The Derivative. Def: The derivative of a function f at a number a, denoted f’(a) is: Provided this limit exists.
Differentiability, Local Linearity

Differentiability, Local Linearity
SECTION 3.1 The Derivative and the Tangent Line Problem.

SECTION 3.1 The Derivative and the Tangent Line Problem.
Today in Calculus Go over homework Derivatives by limit definition Power rule and constant rules for derivatives Homework.

Today in Calculus Go over homework Derivatives by limit definition Power rule and constant rules for derivatives Homework.
1 Discuss with your group. 2.1 Limit definition of the Derivative and Differentiability 2015 Devil’s Tower, Wyoming Greg Kelly, Hanford High School, Richland,

1 Discuss with your group. 2.1 Limit definition of the Derivative and Differentiability 2015 Devil’s Tower, Wyoming Greg Kelly, Hanford High School, Richland,
3.3 Rules for Differentiation AKA “Shortcuts”. Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is.

3.3 Rules for Differentiation AKA “Shortcuts”. Review from places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is.
AP CALCULUS AB Chapter 3: Derivatives Section 3.2: Differentiability.

AP CALCULUS AB Chapter 3: Derivatives Section 3.2: Differentiability.
Differentiability and Piecewise Functions

Differentiability and Piecewise Functions
Unit 1 Limits. Slide 2 1.1 Limits Limit – Assume that a function f(x) is defined for all x near c (in some open interval containing c) but not necessarily.

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.
3.2 Differentiability Objectives Students will be able to: 1)Find where a function is not differentiable 2)Distinguish between corners, cusps, discontinuities,

3.2 Differentiability Objectives Students will be able to: 1)Find where a function is not differentiable 2)Distinguish between corners, cusps, discontinuities,
Review Limits When you see the words… This is what you think of doing…  f is continuous at x = a  Test each of the following 1.

Review Limits When you see the words… This is what you think of doing…  f is continuous at x = a  Test each of the following 1.
Curve Sketching with Radical Functions

Curve Sketching with Radical Functions
1.4 Continuity  f is continuous at a if 1. is defined. 2. exists. 3.

1.4 Continuity  f is continuous at a if 1. is defined. 2. exists. 3.

Similar presentations

Ads by Google