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Lesson 7: Applications of the Derivative

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1 Lesson 7: Applications of the Derivative
MATH 1314 Lesson 7: Applications of the Derivative

2 Meaning of a Derivative:

3 f'(x) f'(4)

4 tangent(3,f(x))

5 Root(f'(x))

6 intersect(f'(x),g(x))

7 f''(x) f’’ (5)

8 Popper 4 Find the slope of the tangent line at the given x-value.
f(x) = 3x2 – x at x = -1 -5 B. -1 C. -7 D. 6 2. f(x) = -x2 – 2x at x = 0 -2 B. -1 C. 2 D. 1 3. f(x) = x3 + x2 at x = 2 A. -2 B. 10 C. 2 D. 16

9 Popper 4 Continued 4. Find all values of x for which the slope of the tangent line to the function is horizontal: f(x) = -x2 – 2x -2 B. -1 C. 2 D. 1 5. Find all values of x for which the slope of the tangent line to the function is horizontal: f(x) = x2 + 4x -4 B. -2 C. 0 D. 4 6. Find all values of x for which the slope of the tangent line to the function is horizontal: f(x) = -10x5 A B. -1 C D. 0

10 Word Problems:

11 Instantaneous vs. Average Rate of Change

12 Position, Velocity, and Acceleration

13

14

15

16

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18 Free Fall

19 root(f(t)) f'(6.352)

20 f'(3) -12 Falling

21 2.625 root(f'(t))

22 -32 f''(t)

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24

25

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28

29 Popper 5: The function d(t) = 4t2 + 32t models the distance covered by a car t seconds after starting from rest. Find the distance covered by the car after 3 seconds. Find the distance covered by the car after 5 seconds. 150 B C D. 260 E. 132 3. Find the velocity of the car when t = 4. Find the velocity of the car when t = 7. A. 88 B. 64 C. 48 D. 60 E. 55

30 Popper 5 Continued: The function d(t) = -t3 + 15t2 + 32t models the distance covered by a car t seconds after starting from rest. 5. Find the acceleration of the car when t = Find the acceleration of the car when t = 4. A. 63 B. 6 C. 75 D. 12 E. 204

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