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Free Fall

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Free Fall J. Frank Dobie H.S. Free Fall Free-falling object falling falls only under the influence of gravity. Free-falling object is in a state of free fall. – PowerPoint PPT presentation

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Title: Free Fall


1
Free Fall
  • J. Frank Dobie H.S.

2
Free Fall
  • Free-falling object falling falls only under the
    influence of gravity.
  • Free-falling object is in a state of free fall.
  • Two important characteristics
  • 1. Free-falling objects do not encounter
  • air resistance.
  • 2. All free-falling objects on Earth
  • accelerate downwards at a rate of
  • 9.81 m/s2.

3
1. Free falling objects fall only under
the influence of what ?
  • Free falling objects fall only under the
    influence of gravity.

4
2. What does an acceleration of -9.81 m/s2
really mean?
  • Every second the object is increasing its
    velocity 9.81 m/s downward.

5
3. What is the direction of the acceleration
during free fall?
  • Free fall is acceleration that is directed
    downward.

6
4. What is absent when an object is undergoing
free fall?
  • Air resistance is absent during free fall.

7
5. Is an object thrown upward undergoing free
fall?
  • Yes, any object released in the air is undergoing
    free fall.

8
6. If an object is thrown downward, is it
undergoing free fall?
  • An object thrown downward is undergoing free
    fall.

9
  • Free-falling objects are accelerating
  • downwards at a rate of 9.81m/s2.
  • A ticker tape trace of it motion is a
  • model that depicts the acceleration.
  • The diagram at the right shows the ticker
  • tape trace that shows the position every
  • 0.1 second.
  • The distance the ball travels
  • every interval of time is increasing is a
  • sign that the ball is speeding up as it
  • falls downward.
  • The acceleration is
  • directed downward in the same direction
  • the speed is increasing.

10
7. What is the value of the acceleration due to
gravity?
  • The acceleration due to gravity is
  • -9.81m/s2.

11
Acceleration of Gravity
  • The acceleration of a free-falling object is so
    important that it is known as the
  • acceleration of gravity.
  • Physicists have a special symbol to denote it
    --- the symbol g.
  • The numerical value for the acceleration of
    gravity is most accurately known as 9.81 m/s2.
  • We will use 10m/s2 during conceptual
    understanding of the acceleration.

12
8. What is the symbol for the acceleration due
to gravity?
  • The symbol for the acceleration due to gravity is
    g.

13
9. Does the acceleration due to gravity change at
your location on the earth?
  • The acceleration due to gravity does not change
    at a particular location on the earth.

14
Velocity and Time Pattern
  • A velocity and time table for a free-falling
    object being dropped from rest would look like
    the following
  • Time(s) Velocity(m/s), downward
  • 0 0
  • 1 10
  • 2 20
  • 3 30
  • 4 40
  • 5 50
  • Remember, the acceleration of 10m/s2 causes the
    velocity to increase 10 m/s per s.

15
Speed Pattern during Free Fall
  • Assuming that the position of a
  • free-falling ball dropped from a
  • position of rest is shown every
  • 1 second, the speed of the ball
  • will be shown to increase as
  • depicted in the diagram at the right.
  • (This diagram is not drawn to scale.)

16
10. If you follow the pattern for the speed
during free fall when an object is released
from rest 10 m/s, 20 m/s, what would be
the next two values for the speed?
  • The next two values for the speed would be 30 m/s
    and 40 m/s.

17
Representing Free Fall by Graphs
  • Position vs. Time Graphs for free-falling objects
  • Observe that the line is curved. A curved line on
    a position vs. time graph signifies an
    accelerated motion 10 m/s2

18
  • A closer look at the position-time graph reveals
    that the object starts with a small velocity
    (slow) and finishes with a large velocity (fast).
  • The negative slope of the line indicates a
    negative (downward) velocity.

19
11. What does the position vs. time graph for
free fall from rest look like?
20
12. What does the negative slope on a position
vs. time graph for an object undergoing free fall
indicate?
  • The negative slope on a position vs. time graph
    for an object undergoing free fall indicates the
    object is undergoing a downward velocity.

21
Velocity vs. Time Graphs
  • The velocity vs. time graph for a free-falling
    object is shown below.
  • Observe that the line on the graph is a straight,
    diagonal line which signifies an accelerated
    motion.

22
  • A closer look at the velocity-time graph reveals
    that the object starts with a zero velocity and
    finishes with a large, negative velocity that
    is, the object is moving in the negative
    direction and speeding up.
  • Analysis of the slope is -10 m/s2 or more
    accurately -9.81 m/s2.

23
13. What does the velocity vs. time graph look
like for an object released from rest and
undergoes free fall?
24
What does the slope of a velocity vs. time
graph for free fall represent?
  • The slope of a velocity vs. time graph for free
    fall represents the acceleration of gravity
    (-9.81 m/s2).

25
How Fast? and How Far?
  • Free-falling objects are in a state of
    acceleration.
  • How Fast?
  • The speed is dependent upon
  • the length of time for which it
  • has fallen.
  • vf vi gt
  • Ex If t 5 s
  • vf 10 m/s2 (5 s) 50 m/s

26
15. What is the velocity of an object moving
after released from rest for 8 s?
  • vf vi at
  • 0 -10 m/s2 (8s)
  • -80 m/s

27
What is the velocity of an object undergoing free
fall from rest for 10 s?
  • vf vi at
  • Vf 0 -10 m/s2(10s)
  • Vf -100 m/s

28
How Far?
  • The distance a free-falling object falls
    depends upon the time of fall.
  • x vi (t) ½ a t2
  • Ex vi 0 m/s and t 1 s
  • x ½ (10 m/s2 ) (1s)2 5 m
  • The diagram shows the results
  • of several distance calculations
  • For a free-falling object dropped
  • from a position of rest.

29
17. How far does a stone fall in 3 s from rest?
  • x vit ½ at2
  • x 0(3s) ½ (-10 m/s2) (3s)2
  • x -45 m45 m

30
18. What is the displacement for an object that
falls freely for 8.0 s?
  • x vit ½ a t2
  • X 0 t ½ (-10. m/s2) (8.0s)2
  • -320 m

31
The Big Misconception
  • Doesnt a massive object accelerate at a greater
    rate than a less massive object?
  • Nearly everyone has observed the difference in
    rate of fall of a single piece of paper and a
    textbook.

32
  • The answer to the question Doesnt a massive
    object accelerate at a greater rate than a less
    massive object? is absolutely not!
  • That is, absolutely not, if you are considering
    the specific type of falling motion know as
    free-fall.
  • Free-falling object do not encounter air
    resistance.
  • Massive objects will only fall faster than less
    massive objects if there is an appreciable amount
    of air resistance present.

33
The Big Answer
  • The explanation of why all objects accelerate at
    the same rate involves the concepts of force and
    mass.
  • You will learn that the acceleration of an object
    is directly proportional to the force acting on
    it and inversely proportional to its mass.
  • All objects, regardless of their mass, free-fall
    at the same rate of acceleration.

34
19. Why does a hammer and feather hit the ground
at the same time on the moon?
  • A hammer and feather hit the ground at the same
    time on the moon because there is very little air
    resistance on the moon.

35
Does a massive object accelerate at a greater
rate than a less massive object when there is an
absence of air resistance?
  • A heavy object will accelerate at the same rate
    as a less massive object when there is an absence
    of air resistance.

36
Definition for Free Fall
  • Object falling only influence of gravity
  • Air Resistance is ignored.
  • Under such conditions, all objects will fall with
    the same rate of acceleration, regardless of
    their mass.

37
Falling with Air Resistance
  • Object falling through air usually encounter some
    degree of air resistance.
  • Air resistance results from collisions of the
    objects leading surface with air molecules
  • Actual amount of resistance depends on various
    factors--- speed of object and
  • cross-sectional area of the object.
  • Increased speeds result in increased amount
    of
  • air resistance.
  • Increased cross-sectional areas result in
  • increased amount of air resistance.

38
Terminal Velocity
  • Objects which encounters air resistance
    eventually reach a terminal velocity.
  • As an object falls, it picks up speed, which
    increases air resistance.
  • The force of air resistance becomes large enough
    to balance the force of gravity. The object has
    now reached terminal velocity where it no longer
    increases in speed.

39
  • When there is air resistance, more massive
    objects fall faster than less massive objects.
  • Consider the objects below of different masses
  • A falling object will continue to accelerate to
    higher speeds until they encounter an amount of
    air resistance equal to their weight.

40
  • Since the 150-kg skydiver weighs more
    (experiences a greater force of gravity), it will
    accelerate to higher speeds before reaching a
    terminal velocity.
  • More massive objects fall faster than less
    massive objects because they are acted upon by a
    larger force of gravity.
  • More massive objects accelerate to higher speeds
    until the air resistance force equals the gravity
    force.
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