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Calculus For AP Physics C. The derivative: The derivative is the slope of a line at a particular point. The line is the graph of a function which we.

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Presentation on theme: "Calculus For AP Physics C. The derivative: The derivative is the slope of a line at a particular point. The line is the graph of a function which we."— Presentation transcript:

1 Calculus For AP Physics C

2 The derivative:

3 The derivative is the slope of a line at a particular point. The line is the graph of a function which we will call f(x). To graphically determine the slope of a curved line you must first draw a tangent line to the curve at the point of interest.

4 The derivative:

5 We can mathematically determine the slope by taking the derivative of the function and then evaluating it at the point of interest. There are two primary ways of denoting the derivative of a function. f '(x) and

6 The derivative: The power rule: Where f(x) = x n f '(x) = nx n–1

7 The derivative: The derivative of a polynomial is also very simple, as each term can be evaluated separately. Where f(x) = 5x 3 + 2x 2 – 8x +4 f '(x) = 15x 2 +4x – 8

8 The derivative: Derivatives of trigonometric functions:

9 The derivative: Special derivatives:

10 The derivative: The Product Rule: When a function consists of the product of two terms, each of which contains the variable, the product rule must be used to determine the derivative. The general form of the product rule is (fg)' = f 'g + fg'

11 The derivative: Here is an example. f(x) = (4x 2 + 9x)(2x 4 + 6x 2 – 3) 8x + 9 (8x + 9)(2x 4 + 6x 2 – 3) 8x 3 + 12x (4x 2 + 9x)(8x 3 + 12x) f '(x) = (8x + 9)(2x 4 + 6x 2 – 3) + (4x 2 + 9x)(8x 3 + 12x)

12 The derivative: Quotient Rule: When a function consists of the quotient of two terms, each of which contains the variable, the quotient rule must be used to determine the derivative. The general form of the product rule is:

13 The derivative: The derivative of the numerator is 12x 2 + 4x The derivative of the denominator is 10x + 8 Lo d hi – hi d lo over lo 2

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15 The derivative: f(x) = (4x 2 + 9x) 4 n = 4 n – 1 = 3 du = 8x + 9 Putting it all together our answer is f '(x) = 4(4x 2 + 9x) 3 (8x + 9)

16 Integration:

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18 Integration is in essence the opposite of the derivative. An integral gives the area between a curve on a graph and the x-axis.

19 Integration:

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21 The integral of a simple function can be computed as follows:

22 Integration: f(x) = 6x 2 + 2x – 4f '(x) = 12x + 2 If we integrate the derivative we will have

23 Differential Equations: Using a differential equation, write an expression for the position of a particle with a velocity given by: v = 2t 2 – 5. The position x at t = 3 s is 5 m.

24 Kinematic Equations: Velocity is change in position.

25 Kinematic Equations: Acceleration is change in velocity.

26 Deriving Kinematic Equations:

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31 Position, velocity, and acceleration:

32 For a case of constant, but non zero, acceleration, draw a graph of (a) acceleration vs. time, (b) velocity vs. time, and (c) position vs. time.

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34 Kinematics terms: 1)Distance – how far something moves 2)Displacement – how far for initial to final location  Symbols for 1 & 2: d, x, y, h, l, r, s 3)Speed – distance per time 4)Velocity – displacement per time  Symbol for 3 & 4: v 5)Acceleration – rate of change of velocity  Symbol for 5: a 6)Scalar – magnitude (amount or size) only 7)Vector – magnitude and direction

35 Types of acceleration: 1)Positive – speed increases in the positive direction or decreases in the negative 2)Negative – speed decreases in the positive direction or increases in the negative 3)Centripetal – direction changes

36 Using the kinematic equations: vfvf v0v0 atx v f = v 0 + at X x f = x 0 + v 0 t + ½at 2 X v f 2 = v 0 2 + 2a(x f – x 0 ) X x f = x 0 + ½(v f + v 0 )t X x f = x 0 + v f t – ½at 2 X

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38 Determine the time for an object to fall a distance d near Earth’s surface.

39 Determine the time for a projectile’s flight on level ground.

40 Trig functions of common angles: 030456090 sin01 cos10 tan01-

41 Projectile motion Projectiles undergo unpowered flight, typically moving horizontally and vertically. Horizontal and vertical motion for a projectile is completely independent! For projectiles, horizontal acceleration is ALWAYS zero

42 Horizontal motion x = vt

43 Projectile motion The velocity of a projectile launched at an angle must be separated into horizontal and vertical components!

44 A softball is hit at 41.3 m/s at an angle of 35.0° above the horizontal. Determine (a) how long it is in the air, (b) how high it goes, and (c) how far it travels. v x = (41.3)(cos 35) = 33.8 m/s v y = (41.3)(sin 35) = 23.7 m/s a) v yf = v y0 + at -v y0 = v y0 + gt -23.7 = 23.7 + (-10)t t = 4.74 s

45 A softball is hit at 41.3 m/s at an angle of 35.0° above the horizontal. Determine (a) how long it is in the air, (b) how high it goes, and (c) how far it travels. v x = (41.3)(cos 35) = 33.8 m/s v y = (41.3)(sin 35) = 23.7 m/s b) v yf 2 = v y0 2 + 2ad 0 = (23.7) 2 + 2(-10)d d = 28.1 m

46 A softball is hit at 41.3 m/s at an angle of 35.0° above the horizontal. Determine (a) how long it is in the air, (b) how high it goes, and (c) how far it travels. v x = (41.3)(cos 35) = 33.8 m/s v y = (41.3)(sin 35) = 23.7 m/s c) x = v x t x = (33.8)(4.74) d = 160. m

47 A football is thrown horizontally at 15 m/s from a height of 20. m. With what velocity does it strike the ground? v yf 2 = v y0 2 + 2ad v yf 2 = 0 + 2(10)(20) v yf = 20. m/s v f = 25 m/s at 37° WRT vertical

48 An accelerating car emerges from behind a building and observer #1 notes that the car travels 50. m in 3.0 s. Observer #2 notes that the car travels 75 m in 4.0 s. What is the acceleration of the car? d = v 0 t + ½at 2 50 = v 0 (3) + ½a(3) 2 75 = v 0 (4) + ½a(4) 2 16.7 = v 0 + 1.5a 18.8 = v 0 + 2a v 0 = 16.7 – 1.5a v 0 = 18.8 – 2.0a 16.7 – 1.5a = 18.8 – 2.0a a = 4.16 m/s 2

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50 Vectors Vector quantities can be represented by arrows called vectors. The length of a vector should be proportional to its size. Vectors are added head to tail

51 r1r1 r2r2 R ?

52 r1r1 r2r2 R

53 Unit vectors Unit vectors have a length of 1 and are used only for direction DirectionUnit Vector +x+x –x–x +y+y –y–y +z+z –z–z

54 Determine the acceleration of a 2.0 kg particle with the velocity vector Determine the force acting on the particle Determine the magnitude of the acceleration at t = 2s

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56 When a high-speed passenger train travelling at 161 km/h rounds a bend, the engineer is shocked to see that a locomotive has improperly entered onto the track from a siding and is a distance D = 676 m ahead. The locomotive is moving at 29.0 km/h. The engineer of the high-speed train immediately applies the brakes. What must be the magnitude of the resulting deceleration if a collision is to be just avoided?

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59 Relative motion A car is moving at 50 km/h on a rainy day. Raindrops that hit the side window make an angle on the glass of 60° relative to the vertical. Determine the speed of the raindrop relative to (a) the car and (b) the earth. (a) 57.7 km/h (b) 28.9 km/h 60° 50 km/h 60° 30° 57.7 km/h 28.9 km/h

60 When a high-speed passenger train travelling at 161 km/h rounds a bend, the engineer is shocked to see that a locomotive has improperly entered onto the track from a siding and is a distance D = 676 m ahead. The locomotive is moving at 29.0 km/h. The engineer of the high-speed train immediately apples the brakes. What must be the magnitude of the resulting deceleration if a collision is to be just avoided? v 0 = 44.72 – 8.06 = 36.66 m/s v f = 0 m/s d = 676 m a = ?

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62 Centripetal motion Centripetal means center seeking r is the radius of the circle or curve Centripetal acceleration is also known as radial “Normal” acceleration is known as linear or tangential

63 A car travelling at 90.0 km/h slows as it enters a sharp curve (r = 150. m). After 15.0 seconds, the car has slowed to 50.0 km/h. Determine the acceleration of the car at this point.


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