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Kinematics Freely Falling Bodies. Goal 2: Build an understanding of linear motion. Objectives – Be able to: 2.03 Analyze acceleration as rate of change.

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Presentation on theme: "Kinematics Freely Falling Bodies. Goal 2: Build an understanding of linear motion. Objectives – Be able to: 2.03 Analyze acceleration as rate of change."— Presentation transcript:

1 Kinematics Freely Falling Bodies

2 Goal 2: Build an understanding of linear motion. Objectives – Be able to: 2.03 Analyze acceleration as rate of change in velocity. 2.04 Using graphical and mathematical tools, design and conduct investigations of linear motion and the relationships among:  Position.  Average velocity.  Instantaneous velocity.  Acceleration.  Time.

3 Freely Falling Bodies (a)In the presence of air resistance, the acceleration of the rock is greater than that of the paper. (b)In the absence of air resistance, both the rock and the paper have the same acceleration. The law of falling bodies applies only in vacuum, not in the air that we are familiar with.

4 Freely Falling Bodies Astronaut David Scott performed a lunar free- fall experiment on the surface of the moon in 1970. He dropped a hammer and a feather simultaneously in the airless vacuum of space… …both experienced the same acceleration due to lunar gravity and hit the lunar surface at the same time.

5 Freely Falling Bodies The acceleration of a freely falling body is called the acceleration due to gravity, g. The acceleration due to gravity is directed downward, toward the center of the earth. Near the earth’s surface, g is approximately g = - 9.80 m/s 2 or - 32 ft/s 2

6 Freefall Example A Falling Stone A stone is dropped from rest from the top of a tall building. After 3.00 s, of free-fall, what is the displacement y of the stone? Reasoning The upward direction is chosen as the positive direction. The initial velocity is zero since the stone is dropped from rest. The acceleration due to gravity is negative, since it points downward. BIG FOUR #3 is the appropriate equation to choose. yavv0v0 t ?-9.80 m/s 2 0 m/s3.00 s

7 Freefall Example A Falling Stone A stone is dropped from rest from the top of a tall building. After 3.00 s, of free-fall, what is the displacement y of the stone? Solution Substituting directly into BIG FOUR #3, y f = y i + v 0 t + ½at 2 y f = 0 m + (0 m/s)(3.00 s) + ½(-9.80 m/s 2 )(3.00 s) 2 y f = -44.1 m

8 Example The Velocity of a Falling Stone After 3.00 s, of free-fall, what is the velocity v of the stone? Reasoning Because of the acceleration due to gravity, the magnitude of the stone’s downward velocity increases by 9.80 m/s during each second of free-fall. The data for the stone are the same as the previous example. Choosing BIG FOUR #2 offers a direct solution. yavv0v0 t -9.80 m/s 2 ?0 m/s3.00 s

9 Example The Velocity of a Falling Stone After 3.00 s, of free-fall, what is the velocity v of the stone? Solution Substituting directly into BIG FOUR #2, v = v 0 + at v = 0 m/s + (-9.80 m/s)(3.00 s) v = -29.4 m/s

10 Example How High Does It Go? A football game customarily begins with a coin toss to determine who kicks off. The referee tosses a coin up with an initial speed of 5.00 m/s. In the absence of air resistance, how high does the coin go above its point of release? Reasoning The coin is given an upward initial velocity, but the acceleration due to gravity points down. Since the velocity and acceleration point in opposite directions, the coin slows as it moves up. Eventually, the velocity of the coin becomes 0 m/s at its highest point. With these data, choose BIG FOUR #4, v f 2 = v i 2 + 2ay to find the maximum height, yavv0v0 t ?-9.80 m/s 2 0 m/s+5.00 m/s

11 Example How High Does It Go? A football game customarily begins with a coin toss to determine who kicks off. The referee tosses a coin up with an initial speed of 5.00 m/s. In the absence of air resistance, how high does the coin go above its point of release? Solution Rearranging BIG #4, we find that the maximum height of the coin above the release point is v 2 – v 0 2 (0 m/s) 2 – (5.00 m/s) 2 y = ----------- = -------------------------------- 2a 2(-9.80 m/s 2 ) y = 1.28 m

12 Example How Long Is It In the Air? According to the data in the picture, what is the total time the coin is in the air before returning to its release point? Reasoning During the time the coin travels up, gravity causes its speed to decrease to zero. On the way down, however, gravity causes the coin to regain the lost speed. Thus, the time for the coin to go up is equal to the time for it to come down. In other words, the total time traveled is twice for the time for the upward motion. The data for the coin during the trip are the same as the previous example: Choose BIG FOUR #2: v = v 0 + at yavv0v0 t ?-9.80 m/s 2 0 m/s+5.00 m/s

13 Example How Long Is It In the Air? According to the data in the picture, what is the total time the coin is in the air before returning to its release point? Solution Rearranging BIG FOUR #2, find that v – v 0 0 m/s – (+5.00 m/s) t = --------- = -------------------------- = 0.510 s a -9.80 m/s 2 The total up-and-down time is twice this value, or 1.02 s

14 Example How Long Is It In the Air? According to the data in the picture, what is the total time the coin is in the air before returning to its release point? It is possible to determine the total time by another method... … when the coin is tossed up and returns to its release point, the displacement for the entire trip is y = 0 m. With this value for the displacement, BIG FOUR #3 y = y 0 + v 0 t + ½ at 2 can be used to find the time for the entire trip.

15 Acceleration Due To Gravity The next two examples illustrate that the expression “freely falling” does not necessarily mean an object is falling down. A freely falling object is any object either moving up or down under the influence of gravity. In either case, the object always experiences the same downward acceleration due to gravity.

16 Conceptual Example Acceleration Versus Velocity There are three parts to the motion of the coin pictured: On the way up, the coin has a velocity vector that is directed upward and has a decreasing magnitude. At the top, the coin momentarily has zero velocity. On the way down, the coin has a downward-pointing velocity vector with an increasing magnitude. The question is … In the absence of air resistance, does the acceleration of the coin, like the velocity, change from one part of the motion to another?

17 Conceptual Example Acceleration Versus Velocity Reasoning and Solution Since air resistance is absent, the coin is in free- fall motion. Therefore, according to the Law of Falling Bodies, the acceleration vector due to gravity has the same, constant, magnitude of 9.80 m/s 2 and points down … during both the up and down portions of the motion. In the absence of air resistance, does the acceleration of the coin, like the velocity, change from one part of the motion to another?

18 Conceptual Example Acceleration Versus Velocity Reasoning and Solution Important! Just because the coin’s instantaneous velocity is zero at the top of the motional path, don’t think that the acceleration vector is also zero there… … Acceleration is the rate at which velocity changes, and the velocity at the top is still undergoing a rate of change … even if v = 0 for a moment! In fact the acceleration at the top has the same magnitude of 9.80 ms/ 2 at every other point of the motion! In the absence of air resistance, does the acceleration of the coin, like the velocity, change from one part of the motion to another?

19 Conceptual Example Acceleration Versus Velocity Reasoning and Solution The coin’s velocity vector changes from moment to moment, but its acceleration vector does not change. In the absence of air resistance, does the acceleration of the coin, like the velocity, change from one part of the motion to another?

20 Conceptual Example Taking Advantage of Symmetry Picture (a) shows a pellet, having been fired from a gun, moving straight up from the edge of a cliff. The initial speed of the pellet is 30 m/s. It goes straight up and then falls back down, eventually hitting the ground beneath the cliff. In (b) the pellet has been fired straight downward at the same initial speed. In the absence of air resistance, does the pellet in part (b) strike the ground beneath the cliff with a smaller, a greater, or the same speed as the pellet in part (a)?

21 Conceptual Example Taking Advantage of Symmetry Reasoning and Solution Because air resistance is absent, the motion is free-fall, and the symmetry inherent in free-fall motion offers an immediate answer to the question. Picture (c) shows why. This part of the drawing show the pellet after it has been fired upward and then fallen back down to its starting point.

22 Conceptual Example Taking Advantage of Symmetry Reasoning and Solution Part (c) is just like part (b) where the pellet is actually fired downward with a speed of 30 m/s. Consequently, whether the pellet s fired as in part (a) or (b), it starts to move downward from the cliff edge ata speed of 30 m/s. In either case, there is the same acceleration due to gravity and the same displacement from the cliff edge to the ground below.

23 Conceptual Example Taking Advantage of Symmetry Reasoning and Solution Under these conditions, the pellet reaches the ground with the same speed no matter in which vertical direction it is fired initially.

24 Goal 2: Build an understanding of linear motion. Objectives – Be able to: 2.03 Analyze acceleration as rate of change in velocity. 2.04 Using graphical and mathematical tools, design and conduct investigations of linear motion and the relationships among:  Position.  Average velocity.  Instantaneous velocity.  Acceleration.  Time.

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