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Lesson 11 - Second Derivatives & Concavity

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1 Lesson 11 - Second Derivatives & Concavity
SL2 - Santowski SL2 - Santowski 11/29/2018

2 Fast Five 1. Determine the second derivative of 2. Solve
y = 3x4 – 3x3 + x2 + 3x + 6 y = ½ x4 + 5x3 – 5x + 2 2. Solve 3. Solve x3 – 4x > 0 SL2 - Santowski 11/29/2018

3 Lesson Objectives 1. Calculate second derivatives of functions
2. Define concavity and inflection point 3. Test for concavity in a function using the second derivative 4. Apply concepts of concavity, second derivatives, inflection points to a real world problem SL2 - Santowski 11/29/2018

4 (B) New Term – Concave Up
Concavity is best “defined” with graphs (i) “concave up” means in simple terms that the “direction of opening” is upward or the curve is “cupped upward” An alternative way to describe it is to visualize where you would draw the tangent lines  you would have to draw the tangent lines “underneath” the curve SL2 - Santowski 11/29/2018

5 (B) New Term – Concave down
Concavity is best “defined” with graphs (ii) “concave down” means in simple terms that the “direction of opening” is downward or the curve is “cupped downward” An alternative way to describe it is to visualize where you would draw the tangent lines  you would have to draw the tangent lines “above” the curve SL2 - Santowski 11/29/2018

6 (B) New Term – Concavity
In keeping with the idea of concavity and the drawn tangent lines, if a curve is concave up and we were to draw a number of tangent lines and determine their slopes, we would see that the values of the tangent slopes increases (become more positive) as our x- value at which we drew the tangent slopes increase This idea of the “increase of the tangent slope is illustrated on the next slides: SL2 - Santowski 11/29/2018

7 (B) New Term – Concavity
SL2 - Santowski 11/29/2018

8 (C) Calculus & Concavity
If f ``(x) >0, then f(x) is concave up If f ``(x) < 0, then f(x) is concave down If f ``(x) = 0, then f(x) is neither concave nor concave down The second derivative also gives information about the “extreme points” or “critical points” or max/mins on the original function (Recall SDT): If f `(x) = 0 and f ``(x) > 0, then the critical point is a minimum point (picture y = x2 at x = 0) If f `(x) = 0 and f ``(x) < 0, then the critical point is a maximum point (picture y = -x2 at x = 0) SL2 - Santowski 11/29/2018

9 (C) Calculus & Concavity
The first derivative also tells us information about the concavity of a function f(x) If f `(x) is increasing on an interval (a,b), then f(x) is concave up on that interval (a,b) If f `(x) is decreasing on an interval (a,b), then f(x) is concave down on that interval (a,b) SL2 - Santowski 11/29/2018

10 (D) Inflection Points & Calculus
Let f(x) be a differentiable function on an interval (a,b). A point x = a is called an inflection point if the function is continuous at the point and the concavity of the graph changes at that point. Using Calculus, the IP can by either f’’(a) = 0 or f”(a) does not exist. However, if f”(a) = 0, we should still test on either side of x = a to see IF the concavity changes SL2 - Santowski 11/29/2018

11 (E) Example Ex 1. Find where the curve y = 4x3 - 3x2 + 1 is concave up and concave down and determine the co-ordinates of the inflection point(s). Then use this info to sketch the curve SL2 - Santowski 11/29/2018

12 (E) Example Ex 2. Determine the intervals of concavity and inflection points of f(x) = 3x5 – 5x For this question, you will solve graphically and then verify algebraically SL2 - Santowski 11/29/2018

13 (E) Example Ex 3. For the function f(x) = ¼x4 – 2x3 + 2
(a) Determine the critical point(s), (b) Determine the intervals of increase and decrease (c) Determine the second derivative (d) HENCE, determine the inflection point(s) (e) Sketch the function, with the correct “curvatures” SL2 - Santowski 11/29/2018

14 (E) Example – Second Derivative Test
Ex 4. For the function f(x) = x3 + 3x2 – 9x + 3 (a) Determine the critical point(s), (c) Determine the second derivative (d) HENCE, determine the inflection point(s) (e) use the information about the second derivative to classify the critical points as maximums or minimums or neither SL2 - Santowski 11/29/2018

15 (E) Example – Second Derivative Test
Ex 5. For the function f(x) = 2x3 – 5x2 – 4x + 3 (a) Determine the critical point(s), (c) Determine the second derivative (d) HENCE, determine the inflection point(s) (e) use the information about the second derivative to classify the critical points as maximums or minimums or neither SL2 - Santowski 11/29/2018

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