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Basic Differentiation rules and rates of change (2.2) October 12th, 2011.

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1 Basic Differentiation rules and rates of change (2.2) October 12th, 2011

2 I. The constant rule Thm. 2.2: The Constant Rule: The derivative of a constant function is 0. So, if c is a real number, then. Thm. 2.2: The Constant Rule: The derivative of a constant function is 0. So, if c is a real number, then.

3 II. THe power rule Thm. 2.3: The Power Rule: If n is a rational number, then the function is differentiable and. For f to be differentiable at x=0, n must be a number such that is defined on an interval containing 0. *When n=1,. Therefore,. Thm. 2.3: The Power Rule: If n is a rational number, then the function is differentiable and. For f to be differentiable at x=0, n must be a number such that is defined on an interval containing 0. *When n=1,. Therefore,.

4 A. Using the power rule Ex. 1: Find the derivative of each function. (a) (b) (c) (d) (e) (f) Ex. 1: Find the derivative of each function. (a) (b) (c) (d) (e) (f)

5 You Try: Find the derivative of each function. (a) (b) (c) (d) You Try: Find the derivative of each function. (a) (b) (c) (d)

6 B. Finding the slope of a graph Ex. 2: Find the slope of the graph of when (a) x = -2 (b) x = 0 (c) x = 2 Ex. 2: Find the slope of the graph of when (a) x = -2 (b) x = 0 (c) x = 2

7 You Try: Find the slope of the graph of when (a) x = -1 (b) x = 1 You Try: Find the slope of the graph of when (a) x = -1 (b) x = 1

8 C. finding an equation of a tangent line Ex. 3: Find an equation of the tangent line to the graph of when x = 2. Ex. 3: Find an equation of the tangent line to the graph of when x = 2.

9 You Try: Find an equation of the tangent line to the graph of when x = -3. You Try: Find an equation of the tangent line to the graph of when x = -3.

10 III. the constant multiple rule Thm. 2.4: The Constant Multiple Rule: If f is a differentiable function and c is a real number, then cf is also differentiable and. Thm. 2.4: The Constant Multiple Rule: If f is a differentiable function and c is a real number, then cf is also differentiable and.

11 Ex. 4: Find the derivative of each function. (a) (b) (c) (d) Ex. 4: Find the derivative of each function. (a) (b) (c) (d)

12 You Try: Find the derivative of each function. (a) (b) (c) You Try: Find the derivative of each function. (a) (b) (c)

13 IV. The sum and difference rules Thm. 2.5: The Sum and Difference Rules: The sum or difference of two differentiable functions f and g is also differentiable and

14 Ex. 5: Find the derivative of each function. (a) (b) Ex. 5: Find the derivative of each function. (a) (b)

15 You Try: Find the derivative of each function. (a) (b) You Try: Find the derivative of each function. (a) (b)

16 V. Derivatives of Sine and Cosine Thm. 2.6: Derivatives of Sine and Cosine Functions:

17 Ex. 6: Find the derivative of each function. (a) (b) Ex. 6: Find the derivative of each function. (a) (b)

18 You Try: Find the derivative of each function. (a) (b) You Try: Find the derivative of each function. (a) (b)

19 VI. Rates of change *The function s is called the position function and gives the position of an object with respect to the origin as a function of time t. The change in position over a period of time is given by and we know rate = distance/time, so we know the average velocity is average velocity = (change in distance)/(change in time) =. *The function s is called the position function and gives the position of an object with respect to the origin as a function of time t. The change in position over a period of time is given by and we know rate = distance/time, so we know the average velocity is average velocity = (change in distance)/(change in time) =.

20 A. finding average velocity of a falling object Ex. 7: Given the position function, find the average velocity over the interval [2, 2.1].

21 You Try: Given the position function s(t)= sin t, find the average velocity over the interval [0, ].

22 *The instantaneous velocity of an object at time t is So, the velocity function v(t) is given by the derivative of the position function s(t). *The speed of an object is given by the absolute value of the velocity (velocity has direction, but speed cannot be negative). *The instantaneous velocity of an object at time t is So, the velocity function v(t) is given by the derivative of the position function s(t). *The speed of an object is given by the absolute value of the velocity (velocity has direction, but speed cannot be negative).

23 *The position of a free-falling object (neglecting air resistance) under the influence of gravity is given by where is the initial height, is the initial velocity, and g is the acceleration due to gravity. (On Earth, feet per second per second or meters per second per second). *The position of a free-falling object (neglecting air resistance) under the influence of gravity is given by where is the initial height, is the initial velocity, and g is the acceleration due to gravity. (On Earth, feet per second per second or meters per second per second).

24 B. Using the derivative to find velocity Ex. 8: At time t = 0, a person jumps off a cliff that is 980 meters above the ground. The position of the person is given by where s is measured in meters and t is in seconds. (a) When does the person hit the ground? (b) What is the person’s velocity at impact? Ex. 8: At time t = 0, a person jumps off a cliff that is 980 meters above the ground. The position of the person is given by where s is measured in meters and t is in seconds. (a) When does the person hit the ground? (b) What is the person’s velocity at impact?

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