Presentation is loading. Please wait.

Presentation is loading. Please wait.

 The derivative of a function f(x), denoted f’(x) is the slope of a tangent line to a curve at any given point.  Or the slope of a curve at any given.

Published byArleen Banks Modified over 9 years ago

Similar presentations

Presentation on theme: " The derivative of a function f(x), denoted f’(x) is the slope of a tangent line to a curve at any given point.  Or the slope of a curve at any given."— Presentation transcript:

1

2  The derivative of a function f(x), denoted f’(x) is the slope of a tangent line to a curve at any given point.  Or the slope of a curve at any given point  Or the instantaneous rate of change of y with respect to x.

3 What is a tangent line?

4  Find the slope of the tangent line to the graph of f at the given x value 1. f(x) = x 2 at x = 2 2. f(x) = x 2 + 2x at x = -2  Answer to 1) f’(2) = 4  Answer to 2) f’(-2) = -2

5  The derivative function for example 1 is…  f’(x) = 2x  f’(2) = 4  The derivative function for example 2 is…  f’(x) = 2x + 2  f’(-2) = -2

6 Rules to find functions that will give you the slope of the tangent lines to a curve at any value of x

7  The derivative of any constant is 0.  That is….

8  For any real number ‘n’

9 Find the derivative of each function below.

10  Find the equation of the tangent line to the graph of f at the specified value of x. f(x) = 3x 4 – 2x + 1 at x = 0  Find the value(s) of “x” where the function has a horizontal tangent line

11 Find the derivative of each function below.

12

13  Derivatives of sine and cosine

14  Derivatives of natural logarithm and e x

15

16

17  DERIVATIVES OF DERIVATIVES  THE RATE OF CHANGE OF A RATE OF CHANGE  NOTATION:  If y or f(x)  1 st derivative y’ or f’(x)  2 nd derivative y’’ or f”(x)  3 rd derivative y’’’ or f’’’(x)  4 th or more y (4) or f (4) (x)

18  Find the 1 st and 2 nd derivatives of each.

19

20 The position of a car is given by the values in the following table. t(sec)012345 s(feet)0103270119178 a) Graph the position function on graph paper b) Use your graph to find the average velocity for the time periods below i) 2 to 5 seconds ii) 2 to 3 seconds c) Estimate the instantaneous velocity when t = 2

21

22  An average rate of change of a function is ALWAYS found by finding the slope of a secant line from time “a” to time “b”.  An Instantaneous rate of change of a function is found by finding the slope of the tangent line at time “a”. (the derivative!)  Sometimes an instantaneous rate can be estimated with an average rate if an equation is not known!

23 A ball is dropped from the top of a tower 450 meters above the ground. Its distance after ‘t’ seconds is given by the equation Find: a) The average velocity from t = 1 to t = 3 seconds b) The instantaneous velocity at t = 5 seconds.

24 a) b)

25  A particle moves along a line such that after ‘t’ seconds its position is given by the equation a) Find the velocity of the particle at exactly 2 seconds. b) Find the acceleration at 1 second.

26  Suppose that f and g are differentiable functions. Then….

27

28  Suppose that f and g are differentiable functions and g(x)  0. Then….

29

30  If y = sin x y’ = cos x  If y = cos x y’ = -sin x  If y = tan x y’ = sec 2 x  If y = cot xy’ = -csc 2 x  If y = sec xy’ = sec x tan x  If y = csc xy’ = -csc x cot x

31  Rule for taking the derivative of functions that are a composition of two or more functions.  y= f(g(x))

32  Find the derivative of each function.

33

34

35

36

Download ppt " The derivative of a function f(x), denoted f’(x) is the slope of a tangent line to a curve at any given point.  Or the slope of a curve at any given."

Similar presentations

4. The derivative of f is x2(x - 2)(x + 3) . At how many points will

4. The derivative of f is x2(x - 2)(x + 3) . At how many points will
Section 2.3 – Product and Quotient Rules and Higher-Order Derivatives

Section 2.3 – Product and Quotient Rules and Higher-Order Derivatives
Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(

Trigonometry Review Find sin(  /4) = cos(  /4) = tan(  /4) = Find sin(  /4) = cos(  /4) = tan(  /4) = csc(  /4) = sec(  /4) = cot(  /4) = csc(
1 Basic Differentiation Rules and Rates of Change Section 2.2.

1 Basic Differentiation Rules and Rates of Change Section 2.2.
Write the following trigonometric expression in terms of sine and cosine, and then simplify: sin x cot x Select the correct answer: 1234567891011121314151617181920.

Write the following trigonometric expression in terms of sine and cosine, and then simplify: sin x cot x Select the correct answer:
Pre calculus Problem of the Day Homework: p. 472 1-17 odds, 25-31 odds, 39-59 odds On the unit circle name all indicated angles by their first positive.

Pre calculus Problem of the Day Homework: p odds, odds, odds On the unit circle name all indicated angles by their first positive.
CHAPTER 2 THE DERIVATIVE.

CHAPTER 2 THE DERIVATIVE.
The Derivative. Objectives Students will be able to Use the “Newton’s Quotient and limits” process to calculate the derivative of a function. Determine.

The Derivative. Objectives Students will be able to Use the “Newton’s Quotient and limits” process to calculate the derivative of a function. Determine.
1.4 – Differentiation Using Limits of Difference Quotients

1.4 – Differentiation Using Limits of Difference Quotients
8 Indefinite Integrals Case Study 8.1 Concepts of Indefinite Integrals

8 Indefinite Integrals Case Study 8.1 Concepts of Indefinite Integrals
1 Instantaneous Rate of Change  What is Instantaneous Rate of Change?  We need to shift our thinking from “average rate of change” to “instantaneous.

1 Instantaneous Rate of Change  What is Instantaneous Rate of Change?  We need to shift our thinking from “average rate of change” to “instantaneous.
3.8 Derivatives of Inverse Trigonometric Functions.

3.8 Derivatives of Inverse Trigonometric Functions.
The derivative as the slope of the tangent line

The derivative as the slope of the tangent line
Aim: Basic Differentiation Course: Calculus Do Now: Aim: What are some of the basic rules of differentiation? On what interval(s) is the derivative of.

Aim: Basic Differentiation Course: Calculus Do Now: Aim: What are some of the basic rules of differentiation? On what interval(s) is the derivative of.
2.2 Differentiation Rules for Constant Multiples, Sums, Powers, Sines, and Cosines Constant Rule:The derivative of a constant is zero. Find the derivatives.

2.2 Differentiation Rules for Constant Multiples, Sums, Powers, Sines, and Cosines Constant Rule:The derivative of a constant is zero. Find the derivatives.
Basic Differentiation rules and rates of change (2.2) October 12th, 2011.

Basic Differentiation rules and rates of change (2.2) October 12th, 2011.
DIFFERENTIATION Differentiation is about rates of change. Differentiation is all about finding rates of change of one quantity compared to another. We.

DIFFERENTIATION Differentiation is about rates of change. Differentiation is all about finding rates of change of one quantity compared to another. We.
Calculus Section 2.2 Basic Differentiation Rules and Rates of Change.

Calculus Section 2.2 Basic Differentiation Rules and Rates of Change.
2-2: Differentiation Rules Objectives: Learn basic differentiation rules Explore relationship between derivatives and rates of change © 2002 Roy L. Gover.

2-2: Differentiation Rules Objectives: Learn basic differentiation rules Explore relationship between derivatives and rates of change © 2002 Roy L. Gover.
Calculus Chapter 3 Derivatives. 3.1 Informal definition of derivative.

Calculus Chapter 3 Derivatives. 3.1 Informal definition of derivative.

Similar presentations

Ads by Google