Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter Two: Section Four The Chain Rule. Chapter Two: Section Four Up to this point all of our derivative rules have considered functions of x in their.

Published byHugo Malone Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter Two: Section Four The Chain Rule. Chapter Two: Section Four Up to this point all of our derivative rules have considered functions of x in their."— Presentation transcript:

1 Chapter Two: Section Four The Chain Rule

2 Chapter Two: Section Four Up to this point all of our derivative rules have considered functions of x in their definitions. What do we do if our function has a more complex argument? For example, consider the function y = (3x) 2.  If we think about the power rule we might be tempted to say that the derivative looks like 2(3 x )  If we expand the function to 9x 2 first and apply the constant product rule we get 18 x as the derivative.

3 Chapter Two: Section Four So, which of these derivatives is correct? Using the NDERIV function on your calculator (do you remember where it is found?) type the following two functions on your graphing calculator:

4 Chapter Two: Section Four Now, let’s look at the table of values that the calculator creates for us. Using my table set feature I asked the calculator to start at x = 0 and have a delta x of 1 as seen below:

5 Chapter Two: Section Four Your table of values should look like this: Where the values you are interested in are in the Y2 column. It looks like 18 x is the derivative of choice here.

6 Chapter Two: Section Four So, this means that the derivative of y = (3 x ) 2 is not simply 2(3 x ), but it is 2(3 x )*3. Make a guess about the derivative of each of the following functions and then check them with your calculator:  y = sin(2 x )  y = (4 x ) 5  y = (3x – 2) 2 [Hint: Check this algebraically first by expanding the binomial]  y = (sin x ) 2 Be prepared to discuss your findings in class.

7 Chapter Two: Section Four This chain rule, which relates the behavior of the derivative of a function to the idea of composition of functions, is a crucial tool for us. We will be working extensively with these kind of function compositions during the year. Ask some of your friends in Calculus BC, I think that they will verify that this is a pretty important derivative rule to look out for.

Download ppt "Chapter Two: Section Four The Chain Rule. Chapter Two: Section Four Up to this point all of our derivative rules have considered functions of x in their."

Similar presentations

Warm up Problem If , find .

Warm up Problem If , find .
Complex Functions These derivatives involve embedded composite, product, and quotient rules. The functions f or g must be derived using another rule.

Complex Functions These derivatives involve embedded composite, product, and quotient rules. The functions f or g must be derived using another rule.
MA 242.003 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.

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.
LIMITS 2. 2.2 The Limit of a Function LIMITS In this section, we will learn: About limits in general and about numerical and graphical methods for computing.

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.
Homework Homework Assignment #15 Read Section 3.7 Page 170, Exercises: 1 – 49 (EOO), 43 Rogawski Calculus Copyright © 2008 W. H. Freeman and Company.

Homework Homework Assignment #15 Read Section 3.7 Page 170, Exercises: 1 – 49 (EOO), 43 Rogawski Calculus Copyright © 2008 W. H. Freeman and Company.
Area between two curves: A standard kind of problem is to find the area above one curve and below another (or to the left of one curve and to the right.

Area between two curves: A standard kind of problem is to find the area above one curve and below another (or to the left of one curve and to the right.
The Derivative. Definition Example (1) Find the derivative of f(x) = 4 at any point x.

The Derivative. Definition Example (1) Find the derivative of f(x) = 4 at any point x.
A Dash of Limits. Objectives Students will be able to Calculate a limit using a table and a calculator Calculate a limit requiring algebraic manipulation.

A Dash of Limits. Objectives Students will be able to Calculate a limit using a table and a calculator Calculate a limit requiring algebraic manipulation.
Lesson # 4 The “Teens” Times Table People might say… Hey… This is a “teen” Lesson, intended for “teens”, That’s pretty Keen, If you know what I mean,

Lesson # 4 The “Teens” Times Table People might say… Hey… This is a “teen” Lesson, intended for “teens”, That’s pretty Keen, If you know what I mean,
The Chain Rule Section 2.4.

The Chain Rule Section 2.4.
Do-Now Solve the following integer problems: No Calculator! 1). -4 + 2 = 2). 26 + - 11 = 3). -14 + -5 = 4). 8 – 10 = 5). -13 + - 8 = 6). -16 + 20 = COMPLETE.

Do-Now Solve the following integer problems: No Calculator! 1) = 2) = 3) = 4). 8 – 10 = 5) = 6) = COMPLETE.
3 DIFFERENTIATION RULES.

3 DIFFERENTIATION RULES.
Chapter Two: Section Five Implicit Differentiation.

Chapter Two: Section Five Implicit Differentiation.
Ch 9.1 Power Series Calculus Graphical, Numerical, Algebraic by

Ch 9.1 Power Series Calculus Graphical, Numerical, Algebraic by
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.

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.
5.5 The Substitution Rule In this section, we will learn: To substitute a new variable in place of an existing expression in a function, making integration.

5.5 The Substitution Rule In this section, we will learn: To substitute a new variable in place of an existing expression in a function, making integration.
Calculus - Integration Semester 2. Derivatives are used to find SLOPES and RATES of CHANGE and Integrals are used to find AREAS or PRODUCTS of functions.

Calculus - Integration Semester 2. Derivatives are used to find SLOPES and RATES of CHANGE and Integrals are used to find AREAS or PRODUCTS of functions.
Rates of Change and Limits

Rates of Change and Limits
Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Slide 2- 1.

Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Slide 2- 1.
MAT 1221 Survey of Calculus Section 4.3 Derivatives of Exponential Functions

MAT 1221 Survey of Calculus Section 4.3 Derivatives of Exponential Functions

Similar presentations

Ads by Google