Presentation is loading. Please wait.

Presentation is loading. Please wait.

4.2 Critical Points Mon Oct 19 Do Now Find the derivative of each 1) 2)

Published byLynette Mason Modified over 8 years ago

Similar presentations

Presentation on theme: "4.2 Critical Points Mon Oct 19 Do Now Find the derivative of each 1) 2)"— Presentation transcript:

1 4.2 Critical Points Mon Oct 19 Do Now Find the derivative of each 1) 2)

2 HW Review

3 Critical points A number a in the domain of a given function f(x) is called a critical point of f(x) if f '(a) = 0 or f ’(x) is undefined at x = a. To find a critical point, we find the 1st derivative and set it equal to 0

4 Example 1: Find the critical point(s) of the polynomial function f given by f(x) = x 3 - 3x + 5

5 Solution Solution to Example 1. –The first derivative f ' is given by f '(x) = 3 x 2 - 3 –f '(x) is defined for all real numbers. Let us now solve f '(x) = 0 3 x 2 - 3 = 0 = 3(x-1)(x+1) =0 x = 1 or x = -1 –Since x = 1 and x = -1 are in the domain of f they are both critical points.

6 Example 2: Find the critical point(s) of the rational function f defined by f(x) = (x 2 + 7 ) / (x + 3)

7 Solution to Example 2. –Note that the domain of f is the set of all real numbers except -3. –The first derivative of f is given by f '(x) = [ 2x (x + 3) - (x 2 + 7 )(1) ] / (x + 3) 2 –Simplify to obtain f '(x) = [ x 2 + 6 x - 7 ] / (x + 3) 2 –Solving f '(x) = 0 x 2 + 6 x - 7 = 0 (x + 7)(x - 1) = 0 x = -7 or x = 1 f '(x) is undefined at x = -3 however x = -3 is not included in the domain of f and cannot be a critical point. The only criticalpoints of f are x = -7 and x = 1.

8 Example 3: Find the critical point(s) of function f defined by f(x) = (x - 2) 2/3 + 3

9 Solution to Example 3. –Note that the domain of f is the set of all real numbers. –f '(x) = (2/3)(x - 2) -1/3 = 2 / [ 3(x - 2) 1/3 ] – f ’(x) is undefined at x = 2 and since x = 2 is in the domain of f it is a critical point.

10 You try: Find the critical points a) f(x) = 2x 3 - 6 x - 13 b) f(x) = (x - 3) 3 - 5 c) f(x) = x 1/3 + 2 d) f(x) = x / (x + 4)

11 answers A) 1, -1 B) 3 C) 0 D) none

12 Extreme Values Extreme values refer to the minimum or maximum value of a function There are two types of extreme values: –Absolute extrema: the min or max value of the entire function or interval –Local extrema: the min or max value of a piece of a function

13 Absolute vs Local (pics) Absolute extrema may or may not exist Local extrema always exist

14 How to find absolute extrema 1) Find all critical points in an interval. 2) Test all critical points and endpoints into the original function 3) The biggest is the absolute max The smallest is the absolute min

15 Ex Find the extrema of the function on [0,6]

16 Ex 2 Find the max of the function on [-1, 2]

17 Ex 3 Find the extreme values of the function on [1, 4]

18 Ex 4 Find the min and max of the function on [0, 2pi]

19 You try Find the extrema of the given function on the indicated interval 1) 2)

20 Rolle’s Theorem Assume that f(x) is continuous on [a,b] and differentiable on (a,b). If f(a) = f(b), then there exists a number c between a and b such that f’(c) = 0

21 Ex Verify Rolle’s Theorem on [-2, 2]

22 Closure Find the min and max of the function on given interval HW: p.222 #1 5 7 21 35 47 55 65 78 83

Download ppt "4.2 Critical Points Mon Oct 19 Do Now Find the derivative of each 1) 2)"

Similar presentations

3.1 Extrema On An Interval.

3.1 Extrema On An Interval.
Maximum and Minimum Values

Maximum and Minimum Values
Maximum and Minimum Values (Section 3.1)

Maximum and Minimum Values (Section 3.1)
Extrema on an interval (3.1) November 15th, 2012.

Extrema on an interval (3.1) November 15th, 2012.
4.1 Maximum and Minimum Values. Maximum Values Local Maximum Absolute Maximum |c2|c2 |c1|c1 I.

4.1 Maximum and Minimum Values. Maximum Values Local Maximum Absolute Maximum |c2|c2 |c1|c1 I.
Copyright © 2008 Pearson Education, Inc. Publishing as Pearson Addison-Wesley Absolute Extrema OBJECTIVES  Find absolute extrema using Maximum- Minimum.

Copyright © 2008 Pearson Education, Inc. Publishing as Pearson Addison-Wesley Absolute Extrema OBJECTIVES  Find absolute extrema using Maximum- Minimum.
12.1 First Derivative and Graph

12.1 First Derivative and Graph
The mileage of a certain car can be approximated by: At what speed should you drive the car to obtain the best gas mileage? Of course, this problem isn’t.

The mileage of a certain car can be approximated by: At what speed should you drive the car to obtain the best gas mileage? Of course, this problem isn’t.
Section 5.1 – Increasing and Decreasing Functions The First Derivative Test (Max/Min) and its documentation 5.2.

Section 5.1 – Increasing and Decreasing Functions The First Derivative Test (Max/Min) and its documentation 5.2.
Section 4.1 Maximum and Minimum Values Applications of Differentiation.

Section 4.1 Maximum and Minimum Values Applications of Differentiation.
Extreme Values. NotationSet NotationPicture (a,b) [a,b] [a,b) (a,b] (a,∞) [a, ∞) a < x < b x > a Intervals Inequalities 1.If a < b then a + c < b + c.

Extreme Values. NotationSet NotationPicture (a,b) [a,b] [a,b) (a,b] (a,∞) [a, ∞) a < x < b x > a Intervals Inequalities 1.If a < b then a + c < b + c.
4.1 Extreme Values of Functions Objective: SWBAT determine the local or global extreme values of a function.

4.1 Extreme Values of Functions Objective: SWBAT determine the local or global extreme values of a function.
MAT 213 Brief Calculus Section 4.2 Relative and Absolute Extreme Points.

MAT 213 Brief Calculus Section 4.2 Relative and Absolute Extreme Points.
4.2 Critical Points Fri Dec 11 Do Now Find the derivative of each 1) 2)

4.2 Critical Points Fri Dec 11 Do Now Find the derivative of each 1) 2)
4.2 – The Mean Value Theorem

4.2 – The Mean Value Theorem
Ex: 3x 4 – 16x 3 + 18x 2 for -1 < x < 4 3.1 – Maximums and Minimums Global vs. Local Global = highest / lowest point in the domain or interval… Local =

Ex: 3x 4 – 16x x 2 for -1 < x < – Maximums and Minimums Global vs. Local Global = highest / lowest point in the domain or interval… Local =
MTH 251 – Differential Calculus Chapter 4 – Applications of Derivatives Section 4.1 Extreme Values of Functions Copyright © 2010 by Ron Wallace, all rights.

MTH 251 – Differential Calculus Chapter 4 – Applications of Derivatives Section 4.1 Extreme Values of Functions Copyright © 2010 by Ron Wallace, all rights.
Determine where a function is increasing or decreasing When determining if a graph is increasing or decreasing we always start from left and use only the.

Determine where a function is increasing or decreasing When determining if a graph is increasing or decreasing we always start from left and use only the.
AP CALCULUS AB FINAL REVIEW APPLICATIONS OF THE DERIVATIVE.

AP CALCULUS AB FINAL REVIEW APPLICATIONS OF THE DERIVATIVE.
Section 4.1 Maximum and Minimum Values

Section 4.1 Maximum and Minimum Values

Similar presentations

Ads by Google