Math 121 Winter 2010 Review Sheet

Similar documents
Bob Brown Math 251 Calculus 1 Chapter 4, Section 1 Completed 1 CCBC Dundalk

1 Lecture 25: Extreme values

MATH 151, FALL 2017 COMMON EXAM III - VERSION B

What do derivatives tell us about functions?

Exam 3 MATH Calculus I

MIDTERM 2. Section: Signature:

Review Guideline for Final

2015 Math Camp Calculus Exam Solution

Math 131. Increasing/Decreasing Functions and First Derivative Test Larson Section 3.3

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Math 115 Practice for Exam 2

Suppose that f is continuous on [a, b] and differentiable on (a, b). Then

Math 1314 Lesson 13: Analyzing Other Types of Functions

Math Section TTH 5:30-7:00pm SR 116. James West 620 PGH

MAT 122 Homework 7 Solutions

Test 3 Review. y f(a) = f (a)(x a) y = f (a)(x a) + f(a) L(x) = f (a)(x a) + f(a)

Daily WeBWorK. 1. Below is the graph of the derivative f (x) of a function defined on the interval (0, 8).

MATH 115 QUIZ4-SAMPLE December 7, 2016

Math 131 Final Exam Spring 2016

Math 112 (Calculus I) Midterm Exam 3 KEY

1) The line has a slope of ) The line passes through (2, 11) and. 6) r(x) = x + 4. From memory match each equation with its graph.

Spring 2015 Sample Final Exam

Use a graphing utility to approximate the real solutions, if any, of the equation rounded to two decimal places. 4) x3-6x + 3 = 0 (-5,5) 4)

Math 180, Exam 2, Practice Fall 2009 Problem 1 Solution. f(x) = arcsin(2x + 1) = sin 1 (3x + 1), lnx

Bob Brown Math 251 Calculus 1 Chapter 4, Section 4 1 CCBC Dundalk

A.P. Calculus Holiday Packet

MATH 2053 Calculus I Review for the Final Exam

Calculus 221 worksheet

x x implies that f x f x.

What makes f '(x) undefined? (set the denominator = 0)

DA 4: Maximum and Minimum Values

Review for the Final Exam

Lecture 9 - Increasing and Decreasing Functions, Extrema, and the First Derivative Test

Learning Target: I can sketch the graphs of rational functions without a calculator. a. Determine the equation(s) of the asymptotes.

Math 108, Solution of Midterm Exam 3

Determining the Intervals on Which a Function is Increasing or Decreasing From the Graph of f

Math 113 (Calculus 2) Exam 4

3.1 ANALYSIS OF FUNCTIONS I INCREASE, DECREASE, AND CONCAVITY

Solve the problem. Determine the center and radius of the circle. Use the given information about a circle to find its equation.

f (x) = 2x x = 2x2 + 4x 6 x 0 = 2x 2 + 4x 6 = 2(x + 3)(x 1) x = 3 or x = 1.

Sample Math 115 Midterm Exam Spring, 2014

Polynomial functions right- and left-hand behavior (end behavior):

MATH 115 SECOND MIDTERM EXAM

Math 180, Final Exam, Fall 2012 Problem 1 Solution

Student Study Session Topic: Interpreting Graphs

ExtremeValuesandShapeofCurves

a k 0, then k + 1 = 2 lim 1 + 1

Math 115 Second Midterm March 25, 2010

Final Exam Study Guide

Calculus 1 Math 151 Week 10 Rob Rahm. Theorem 1.1. Rolle s Theorem. Let f be a function that satisfies the following three hypotheses:

Announcements. Topics: Homework: - sections , 6.1 (extreme values) * Read these sections and study solved examples in your textbook!

3.4 Using the First Derivative to Test Critical Numbers (4.3)

Polynomial Degree Leading Coefficient. Sign of Leading Coefficient

AP Calculus BC Fall Final Part IA. Calculator NOT Allowed. Name:

7 + 8x + 9x x + 12x x 6. x 3. (c) lim. x 2 + x 3 x + x 4 (e) lim. (d) lim. x 5

Math 115 Practice for Exam 3

Exam 2 Solutions October 12, 2006

MATH 019: Final Review December 3, 2017

Math 1431 Final Exam Review

Math 180, Final Exam, Fall 2007 Problem 1 Solution

Answers for Calculus Review (Extrema and Concavity)

Sections Practice AP Calculus AB Name

4.1 Analysis of functions I: Increase, decrease and concavity

Maximum and Minimum Values (4.2)

Review all the activities leading to Midterm 3. Review all the problems in the previous online homework sets (8+9+10).

106 Chapter 5 Curve Sketching. If f(x) has a local extremum at x = a and. THEOREM Fermat s Theorem f is differentiable at a, then f (a) = 0.

1. Introduction. 2. Outlines

(e) 2 (f) 2. (c) + (d). Limits at Infinity. 2.5) 9-14,25-34,41-43,46-47,56-57, (c) (d) 2

Georgia Department of Education Common Core Georgia Performance Standards Framework CCGPS Advanced Algebra Unit 2

MAXIMA AND MINIMA CHAPTER 7.1 INTRODUCTION 7.2 CONCEPT OF LOCAL MAXIMA AND LOCAL MINIMA

Mathematic 108, Fall 2015: Solutions to assignment #7

UNIVERSITY OF REGINA Department of Mathematics and Statistics. Calculus I Mathematics 110. Final Exam, Winter 2013 (April 25 th )

As f and g are differentiable functions such that. f (x) = 20e 2x, g (x) = 4e 2x + 4xe 2x,

MTH Calculus with Analytic Geom I TEST 1

Written Homework 7 Solutions

Math 121: Final Exam Review Sheet

Math 1323 Lesson 12 Analyzing functions. This lesson will cover analyzing polynomial functions using GeoGebra.

Calculus I Midterm Exam. eftp Summer B, July 17, 2008

M408 C Fall 2011 Dr. Jeffrey Danciger Exam 2 November 3, Section time (circle one): 11:00am 1:00pm 2:00pm

4 3A : Increasing and Decreasing Functions and the First Derivative. Increasing and Decreasing. then

MA 113 Calculus I Fall 2015 Exam 3 Tuesday, 17 November Multiple Choice Answers. Question

4.2: What Derivatives Tell Us

APPLICATIONS OF DIFFERENTIATION

Section 5-1 First Derivatives and Graphs

Calculus with Analytic Geometry I Exam 8 Take Home Part.

Section 3.2 Polynomial Functions and Their Graphs

Sections 4.1 & 4.2: Using the Derivative to Analyze Functions

Math 16A Second Midterm 6 Nov NAME (1 pt): Name of Neighbor to your left (1 pt): Name of Neighbor to your right (1 pt):

Math 229 Mock Final Exam Solution

Name Date Period. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Name: Instructor: 1. a b c d e. 15. a b c d e. 2. a b c d e a b c d e. 16. a b c d e a b c d e. 4. a b c d e... 5.

Analysis of Functions

14 Increasing and decreasing functions

Calculus Example Exam Solutions

3.2. Polynomial Functions and Their Graphs. Copyright Cengage Learning. All rights reserved.

AB Calculus Diagnostic Test

Math 121 Calculus 1 Fall 2009 Outcomes List for Final Exam

Absolute Extrema. Joseph Lee. Metropolitan Community College

1. Which one of the following points is a singular point of. f(x) = (x 1) 2/3? f(x) = 3x 3 4x 2 5x + 6? (C)

Math 2250 Exam #3 Practice Problem Solutions 1. Determine the absolute maximum and minimum values of the function f(x) = lim.

Transcription:

Math 121 Winter 2010 Review Sheet March 14, 2010 This review sheet contains a number of problems covering the material that we went over after the third midterm exam. These problems (in conjunction with the problems in the previous review sheets) are meant to help you prepare for the final exam which is scheduled to take place on Thursday, March 18 th, 2010 from 8:00 am to 10:00 am. The answers to these problems are given at the end of the this review sheet for your convenience. Analysis of Functions II: Relative Extrema; Graphing Polynomials. 1. Use the given derivative to find all critical points of f, and at each critical point determine whether a relative maximum, relative minimum, or neither occurs. Assume in each case that f is continuous everywhere. (a) f (x) = x 2 (x 3 5). (b) f (x) = 2 3x 3 x+2. (c) f (x) = xe 1 x2. (d) f (x) = ln( 2 1+x 2 ). 2. (a) Show that f(x) = 1 x 5 and g(x) = 3x 4 8x 3 both have stationary points at x = 0. (b) What does the second derivative test tell you about the nature of these stationary points? (c) What does the first derivative test tell you about the nature of these stationary points? 3. Is the following statement true or false. If p(x) is a polynomial such that p (x) has a simple root at x = 1, then p has a relative extremum at x = 1. 4. Find the relative extrema for f(x) = sin 2x where 0 < x < π using both first and second derivative tests. 5. Use any method to find the relative extrema of the function f(x) = 1 + 3 x. 1

6. Give a graph of the polynomial p(x) = x 4 6x 2 + 5 and label the coordinates of the intercepts, stationary points, and inflection points. Absolute Maxima and Minima. 1. Determine whether the statement is true or false. Explain your answer. (a) If a function f is continuous on [a, b], then f has an absolute maximum on [a, b]. (b) If a function f is continuous on (a, b), then f has an absolute minimum on (a, b). (c) If a function f has an absolute minimum on (a, b), then there is a critical point of f in (a, b). (d) If a function f is continuous on [a, b] and f has no relative extreme values in (a, b), then the absolute maximum value of f exists and occurs either at x = a or at x = b. 2. Find the absolute maximum and minimum values of f, if any, on the given interval, and state where those values occur. (a) f(x) = x 2 x 2; (, + ). (b) f(x) = 4x 3 3x 4 ; (, + ). (c) f(x) = 2x 3 6x + 2; (, + ). (d) f(x) = x 2 x+1 ; ( 1, 5]. (e) f(x) = x 2/3 (20 x); [ 1, 20]. (f) f(x) = 1 + 1/x; (0, + ). (g) f(x) = 2x2 3x 3 x 2 2x+2 ; [1, + ). (h) f(x) = 2 cos x sin x ; [π/4, 3π/4]. { 4x 2, x < 1 (i) f(x) = (x 2)(x 3), x 1 ; [1/2, 7/2]. 3. Let f(x) = x 2 + px + q. Find the values of p and q such that f(1) = 3 is an absolute extremum of f on [0, 2]. Is this value an absolute maximum or an absolute minimum? 2

Solutions Analysis of Functions II: Relative Extrema; Graphing Polynomials. 1. (a) Critical Points x = 0, 5 1/3. x = 0 : neither; x = 5 1/3 relative minimum. (b) Critical Points x = 2, 2/3. x = 2 : relative minimum; x = 2/3 relative maximum. (c) Critical Points x = 0. x = 0 : relative minimum. (d) Critical Points x = 1, 1. x = 1 : relative minimum; x = 1 relative maximum. 2. (a) f (x) = 5x 4 and g (x) = 12x 3 24x 2 f (0) = g (0) = 0. (b) f (x) = 20x 3 and g (x) = 36x 2 48x f (0) = g (0) = 0, which yields no information. (c) There is no relative extremum at 0 for the function f nor the function g since there is no change in the signs of the derivatives f (x) and g (x) before and after 0. 3. True. By Theorem 4.2.5(c), the graph of p (x) crosses the x-axis at x = 1. By either case (a) or case (b) of Theorem 4.2.3, f has either a relative maximum or a relative minimum at x = 1. 4. x = 1: relative minimum. Absolute Maxima and Minima. 1. (a) True, by Theorem 4.4.2. (b) False. A( counter example is the function f(x) = tan x on the open interval π 2, ) π 2. This function has no absolute minimum (and no absolute maximum) on this open interval. (c) True, by Theorem 4.4.3. (d) True. The absolute maximum of f on [a, b] exists, by Theorem 4.4.2. If it occurred in (a, b), then it would also be a relative maximum. Since f has no relative maximum in (a, b), the absolute maximum must occur at either x = a or x = b. 2. Find the absolute maximum and minimum values of f, if any, on the given interval, and state where those values occur. (a) The function f has no absolute maximum but it has an absolute minimum of -9/4 that occurs at the critical point x = 1/2. 3

5. (b) The function f has no absolute minimum but it has an absolute maximum of 1 that occurs at the critical point x = 1. (c) The function f has neither an absolute maximum nor an absolute minimum since lim x ± f(x) = ±. (d) The function f has no absolute minimum since lim x 1 + f(x) =. However, f has an absolute maximum of 1/2 at x = 5 since f is increasing on the interval ( 1, 5] because f (x) = 3/(x + 1) 2 > 0 for all x in ( 1, 5]. (e) f (x) = 5(8 x) 3x 1/3, f (x) = 0 when x = 8 and f (x) does not exist when x = 0; f( 1) = 21, f(0) = 0, f(8) = 48, f(20) = 0. So, the absolute maximum is 48 at x = 8 and the absolute minimum is 0 at x = 0, 20. (f) f has neither an absolute maximum nor an absolute minimum on the open interval (0, + ) because it has no critical points on that interval. However, we note here that f is bounded from below because f(x) > 1 for all x > 0. (g) f (x) = x(x 2) (x 2 2x+2) 2, and for 1 x <, f (x) = 0 when x = 2. Thus, f has one relative extremum on the interval [1, + ) which is a relative maximum. Therefore, f has an absolute maximum of 5/2 at x = 2. Moreover, since f(1) = 2 = lim x + f(x), it follows that f has an abslute minimum of 2 at x = 1. (h) f 1 2 cos x (x) = sin 2 x ; f (x) = 0 on [π/4, 3π/4] only when x = π/3. Then, f(π/4) = 2 2 1, f(π/3) = 3, and f(3π/4) = 2 2 + 1. So, f has an absolute maximum value of 2 2 + 1 at x = 3π/4 and an absolute minimum value of 3 at x = π/3. 4

{ 4, x < 1 (i) f (x) = 2x 5, x > 1. So, f (x) = 0 when x = 5/2, and f (x) does not exist when x = 1 because lim x 1 + f(x) f(1) x 1 = 3 4 = f(x) f(1) lim x 1 x 1 ; f(1/2) = 0, f(1) = 2, f(5/2) = 1/4, f(7/2) = 3/4. So, the absolute maximum is 2 and the absolute minimum is 1/4. 3. f (x) = 2x+p which exists throughout the interval (0, 2) for all values of p so f (1) = 0 because f(1) is an extreme value. Thus, 2+p = 0 p = 2. Moreover, f(1) = 3 1 2 + ( 2)(1) + q = 3 q = 4. Thus, f(x) = x 2 2x + 4 and f(0) = 4, f(2) = 4 so f(1) is an absolute minimum. 5

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback