Presentation is loading. Please wait.

Presentation is loading. Please wait.

3.3 Rules for Differentiation AKA “Shortcuts”. Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is.

Published byChristopher Griffin Modified over 9 years ago

Similar presentations

Presentation on theme: "3.3 Rules for Differentiation AKA “Shortcuts”. Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is."— Presentation transcript:

1 3.3 Rules for Differentiation AKA “Shortcuts”

2 Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is undefined) ▫Discontinuity (jump, hole, vertical asymptote, infinite oscillation) In other words, a function is differentiable everywhere in its domain if its graph is smooth and continuous.

3 3.2 Using the Calculator The calculator will find approximations for numerical derivatives. ▫Ex.: Find the slope of the tangent line of f(x) = x 3 at x = 5.

4 3.2 Differentiability Theorem: ▫If f has a derivative at x = a, then f is continuous at x = a. ▫If f is differentiable everywhere, it is also continuous everywhere.

5 3.2 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).

6 Derivatives of Constants Find the derivative of f(x) = 5. Derivative of a Constant: If f is the function with the constant value c, then, (the derivative of any constant is 0)

7 Power Rule What is the derivative of f(x) = x 3 ? From class the other day, we know f’(x) = 3x 2. If n is any real number and x ≠ 0, then In other words, to take the derivative of a term with a power, move the power down front and subtract 1 from the exponent.

8 Power Rule Example: ▫What is the derivative of Example : – What is the derivative of

9 Power Rule Example: ▫What is the derivative of Now, use power rule

10 Constant Multiple Rule Find the derivative of f(x) = 3x 2. 0 Constant Multiple Rule: If u is a differentiable function of x and c is a constant, then In other words, take the derivative of the function and multiply it by the constant.

11 Sum/Difference Rule Find the derivative of f(x) = 3x 2 + x Sum/Difference Rule: If u and v are differentiable functions of x, then their sum and difference are differentiable at every point where u and v are differentiable. At such points, In other words, if functions are separated by + or –, take the derivative of each term one at a time.

12 Example Find where horizontal tangent occurs for the function f(x) = 3x 3 + 4x 2 – 1. A horizontal tangent occurs when the slope (derivative) equals 0.

13 Example At what points do the horizontal tangents of f(x)=0.2x 4 – 0.7x 3 – 2x 2 + 5x + 4 occur? Horizontal tangents occur when f’(x) = 0 To find when this polynomial = 0, graph it and find the roots. Substituting these x-values back into the original equation gives us the points (-1.862, -5.321), (0.948, 6.508), (3.539, -3.008)

14 Product Rule If u and v are two differentiable functions, then Also written as: In other words, the derivative of a product of two functions is “1 st times the derivative of the 2 nd plus the 2 nd times the derivative of the 1 st.”

15 Product Rule Example: Find the derivative of

16 Quotient Rule If u and v are two differentiable functions and v ≠ 0, then Also written as: In other words, the derivative of a quotient of two functions is “low d-high minus high d-low all over low low.”

17 Quotient Rule Example: Find the derivative of

18 Higher-Order Derivatives f’ is called the first derivative of f f'' is called the second derivative of f f''' is called the third derivative of f f (n) is called the n th derivative of f

19 Higher-Order Derivatives Example Find the first four derivatives of

Download ppt "3.3 Rules for Differentiation AKA “Shortcuts”. Review from 3.2 4 places derivatives do not exist: ▫Corner ▫Cusp ▫Vertical tangent (where derivative is."

Similar presentations

3.3 Rules for Differentiation

3.3 Rules for Differentiation
The Derivative and the Tangent Line Problem

The Derivative and the Tangent Line Problem
Limits and Continuity Definition Evaluation of Limits Continuity

Limits and Continuity Definition Evaluation of Limits Continuity
The Power Rule  If we are given a power function:  Then, we can find its derivative using the following shortcut rule, called the POWER RULE:

The Power Rule  If we are given a power function:  Then, we can find its derivative using the following shortcut rule, called the POWER RULE:
Section 2.2 – Basic Differentiation Rules and Rates of Change.

Section 2.2 – Basic Differentiation Rules and Rates of Change.
Chapter 3 The Derivative Definition, Interpretations, and Rules.

Chapter 3 The Derivative Definition, Interpretations, and Rules.
Derivative as a Function

Derivative as a Function
W-up Get out note paper Find 12.3 notes

W-up Get out note paper Find 12.3 notes
Calculus Mrs. Dougherty’s Class. drivers Start your engines.

Calculus Mrs. Dougherty’s Class. drivers Start your engines.
AP CALCULUS PERIODIC REVIEW. 1: Limits and Continuity A function y = f(x) is continuous at x = a if: i) f(a) is defined (it exists) ii) iii) Otherwise,

AP CALCULUS PERIODIC REVIEW. 1: Limits and Continuity A function y = f(x) is continuous at x = a if: i) f(a) is defined (it exists) ii) iii) Otherwise,
Section 2.8 - Continuity. continuous pt. discontinuity at x = 0 inf. discontinuity at x = 1 pt. discontinuity at x = 3 inf. discontinuity at x = -3 continuous.

Section Continuity. continuous pt. discontinuity at x = 0 inf. discontinuity at x = 1 pt. discontinuity at x = 3 inf. discontinuity at x = -3 continuous.
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.

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.
9.3 Rational Functions and Their Graphs Rational Function – A function that is written as, where P(x) and Q(x) are polynomial functions. The domain of.

9.3 Rational Functions and Their Graphs Rational Function – A function that is written as, where P(x) and Q(x) are polynomial functions. The domain of.
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.
If the derivative of a function is its slope, then for a constant function, the derivative must be zero. example: The derivative of a constant is zero.

If the derivative of a function is its slope, then for a constant function, the derivative must be zero. example: The derivative of a constant is zero.
Techniques of Differentiation. I. Positive Integer Powers, Multiples, Sums, and Differences A.) Th: If f(x) is a constant, B.) Th: The Power Rule: If.

Techniques of Differentiation. I. Positive Integer Powers, Multiples, Sums, and Differences A.) Th: If f(x) is a constant, B.) Th: The Power Rule: If.
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. Yes No All Reals 3.2 5 To be differentiable, a function must be continuous and smooth. Derivatives will fail to exist at: cornercusp.

3.2 Differentiability. Yes No All Reals To be differentiable, a function must be continuous and smooth. Derivatives will fail to exist at: cornercusp.

Similar presentations

Ads by Google