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This chapter explores graphs and derivatives to identify increasing and decreasing functions, find intervals of increase and decrease, and locate relative extrema. The second derivative test is used to determine concavity and the nature of extrema.
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Chapter 5 Graphs and the Derivative
Section 5.1 Increasing and Decreasing Functions
Your Turn 1 Find where the function is increasing and decreasing. Solution: Moving from left to right, the function is decreasing for x-values up to −1, then increasing for x-values from to −1 to 2. For x-values from 2 to 4, decreasing and increasing for all x-values larger than 4. In interval notation, the function is increasing on (−1, 2) and (4, ∞). Function is decreasing on (−∞, −1) and (2,4).
Your Turn 2 Find the intervals in which is increasing or decreasing. Graph the function. Solution: Here To find the critical numbers, set this derivative equal to 0 and solve the resulting equation by factoring. Continued
Your Turn 2 Continued The tangent line is horizontal at −3 or 5/3. Since there are no values of x where derivative fails to exist, the only critical numbers are −3 and 5/3. To determine where the function is increasing or decreasing, locate −3 and 5/3 on a number line. The number line is divided into three intervals namely, (−∞, −3), ( −3, 5/3), and (5/3, ∞). Now choose any value of x in the interval (−∞, −3), choosing − 4 and evaluating which is negative. Therefore, f is decreasing on (−∞, −3). Continued
Your Turn 2 Continued Now choose any value of x in the interval ( −3, 5/3), choosing x = 0 and evaluating which is positive. Therefore, f is increasing on ( −3, 5/3). Now choose any value of x in the interval (5/3, ∞), choosing x = 2 and evaluating which is negative. Therefore, f is decreasing on (5/3, ∞). Continued
Section 5.2 Relative Extrema
Your Turn 1 Identify the x-values of all points where the graph has relative extrema. Solution:
Your Turn 2 Find all relative extrema Solution: Here To find the critical numbers, set this derivative equal to 0 and solve the resulting equation by factoring. Continued
Your Turn 2 Continued The tangent line is horizontal at −3 or 5/3. Since there are no values of x where derivative fails to exist, the only critical numbers are −3 and 5/3. The number line is divided into three intervals namely, (−∞, −3), ( −3, 5/3), and (5/3, ∞). Any number from each of the three intervals can be used as a test point to find the sign of in each interval. Using − 4, 0, and 2 gives the following information. Continued
Your Turn 2 Continued Thus derivative is negative on(−∞, −3), positive on ( −3, 5/3), and negative on (5/3, ∞). Using the first derivative test, this means that the function has a relative maximum of f (5/3) = 670/27 and f has a relative minimum of f (−3) = −26.
Section 5.3 Higher Derivatives, Concavity, and the Second Derivative Test
Your Turn 1 Solution: To find the second derivative of f (x), find the first derivative, and then take its derivative.
Your Turn 2(a) Solution : Here, using the chain rule,
Your Turn 2(b) Solution: Use the product rule,
Your Turn 2(c) Solution: Here, we need the quotient rule.
