course Phy 201
Class 090930Horizontal range of a pendulum let loose at equilibrium
Hold a washer pendulum stationary at its equilibrium point and let it drop to the floor. Mark or measure the
position at which it strikes the floor.
Now, holding the pendulum so its equilibrium point is the same as before, pull it back and release it so
that it swings back toward equilibrium. The instant it reaches its equilibrium point, let go of the string
and let it fall to the floor. Record the distance the pendulum was pulled back from its equilibrium
position, its length, its height above the floor, and the position at which it strikes the floor.
Repeat for a few trials.
Report your raw data below:
My first trial my pullback was 15cm and it landed at 47cm.
Second trial my pullback was 20cm and it landed at 60cm.
Third Trial my pullback was 10cm and it landed at 36cm.
****
&&&&
Starting with the event of letting go and ending with the event of first contact with the floor, we assume
that the washer is in free fall, the only force acting on it being the force of gravity (air resistance on
the washer and on the thread will actually be present, but will be insignificant compared to our
uncertainties in measurement). We will analyze the data to determine its velocity at equilibrium.
If you hold the pendulum string in a fixed point, you can move the washer around a circle whose radius is
equal to the length of the pendulum. So as long as you are holding the string in a fixed position the
pendulum will move along an arc of a circle.
As it swings back toward equilibrium, the direction of its motion is mostly horizontal but it also descends,
so its motion has a downward vertical component.
As it approaches equilibrium it moves faster and faster, but due to the shape of the circle it descends more
and more slowly.
After it passes equilibrium it continues for a time moving in the horizontal direction as it moves upward in
the vertical direction.
At equilibrium the washer is at its lowest point, neither rising nor falling, so at that instant it is
moving entirely in the horizontal direction.
If you let go of the string before the washer reaches equilibrium, then its fall will begin with a downward
vertical velocity.
If you let go after equilibrium, then the initial vertical of its fall will be upward.
If you let go exactly at the equilibrium point, then the initial velocity of its fall will be entirely
horizontal and its initial vertical velocity will be zero.
Of course you can't let go exactly at the instant the washer reaches the equilibrium position, and the
initial velocity of the fall won't in fact be entirely vertical. The initial position of the washer won't be
exactly at the equilibrium point, either.
Since in our analysis we will assume that the initial event occurs at the equilibrium point, with zero
vertical velocity, there are multiple sources of uncertainty in this experiment.
Using your raw data show how you find the following, for the interval between the event of letting go of the
string and the event of the washer's first contact with the floor.
The time required to fall your observed vertical distance, starting with initial vertical velocity zero and
accelerating downward at 980 cm/s^2.
The displacement of the washer in the horizontal direction.
The horizontal velocity of the washer.
For each of your trials, report the pendulum length, the pullback distance, and the horizontal velocity of
the falling washer. Use one line to report the results of each trial:
15,47
20,60
10,36
you don't appear to have calculated the horizontal velocities
****
&&&&
You need do this part for only one of your trials:
Suppose the pendulum was released a little early, so that the magnitude of its initial vertical velocity was
10% of the horizontal speed you just calculated. (If you didn't get that part you can assume a horizontal
speed of 60 cm/s)
How long would it then take to reach the floor? (you know the initial vertical velocity, vertical
displacement and vertical acceleration)
****
&&&&
Estimate the vertical 'drop' as the pendulum swings to equilibrium
You need do this part for only one of your trials:
Draw a circle on your paper. The diameter of your circle should be at least half the length of your paper.
Sketch the pendulum, hanging at equilibrium, as follows:
The center of the circle represents the point at which you held the pendulum.
The radius of the circle represents the length of your pendulum.
The 'lowest' point on the circle, vertically below the center, will represent the center of the washer.
Sketch the washer, centered at this 'lowest' point.
Sketch the string, which will extend from the center of the circle to the washer.
Now sketch the pendulum at its 'pullback' position (the 'held' end of the string will still be at the center
of the circle). Keep your sketch reasonably to scale.
Presumably you have observed the pullback and the length of the pendulum. What is the pullback of the
pendulum as a percent of its length? (e.g., if the length is 16 cm and the pullback 4 cm then pullback is
25% of the length).
****
Length of pendulum is 20cm the pullback is 5cm which is 25% of the length.
&&&&
Since the radius of the circle represents the length of the pendulum, the number you just gave is also the
pullback as a percent of the radius of the circle.
When the washer was pulled back in the horizontal, it was also raised in the vertical direction. Estimate
the distance it was raised as a percent of the distance it was pulled back.
****
I would assume it would raise it 25%
&&&&
What therefore is your estimate of the distance the washer was raised as a percent of the pendulum's length?
****
25%
&&&&
You measured the length. Based on your preceding estimate, how much was it raised?
****
25%
&&&&
If a coin was dropped from rest, and allowed to fall a distance equal to your previous result, how fast
would it be going at the end of its fall?
****
&&&&
"
You haven't really shown your work on these questions.
I'm always glad to answer questions.