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Lab 4: Free Fall Motion - College Physics I | PHYS 2011, Lab Reports of Physics

Tennessee State University (TSU)Physics
Prof. Lizhi Ouyang

Material Type: Lab; Professor: Ouyang; Class: College Physics I Lab; Subject: Physics; University: Tennessee State University; Term: Unknown 1989;

Typology: Lab Reports

Pre 2010

Uploaded on 08/18/2009

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Lab 4 Free Fall Motion
Purpose: To measure "g", the acceleration of gravity.
Apparatus: Picket Fence (plastic strip with uniformly spaced bands), Photogate, Scientificwork®
Interface, Software DataStudio® on Macintosh™.
Introduction: Neglecting the air resistance and flucturation in acceleration due to gravity, the free
fall of an object is a constant acceleration motion that follows the kinematical law:
d=d0+v0t+1/2gt2.
Suggested Procedure:
1. Turn on the macintosh computer
2. Turn on the scientificwork interface
3. Plug the output from the photogate into the #1 digital input channel on the scientificwork
interface.
4. Put the photogate at the edge of your table and make sure the Picket Fence is able to fall
through to the floor. Put a foam mattress under the photogate to catch and protect the
Picket Fence.
5. Open DataStudio® and select the free fall experiment. Add distant-time plot, velocity-
time plot, and acceleration-time plot into the graph window by dragging and dropping the
corresponding icon from the left panel.
6. Hold the Picket Fence straight right above the photogate. Press the “start” bottom to start
the data collection. At the same time release the Picket Fence.
7. Using the fitting function (linear fitting only) on the graph window to collect
experimental data for all three plots. Record the slope of velocity, maximum and
minimum value of acceleration.
Results and Error Analysis:
1. Examine the plot of Velocity versus time in the graph display. Determine the slope of the
best fit line for velocity-time plot. Select ‘Linear’ from the fit menu.
2. Apply Statistics to each column in the table display to determine the ‘mean’ value of
acceleration. Select ‘Mean’ from the ‘Statistics’ menu.
3. Record the value for the Mean of the acceleration, and the slope of the velocity-time in
the data table I.
4. Do a regression analysis of the Position-time data to find the acceleration due to gravity.
Record your results in the data table I.
Questions:
1. Can an object have an increasing velocity and a constant acceleration? Can the velocity of
an object be zero at the same instant its acceleration is non zero?
2. Find the sources for the deviations found in the experiments
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Lab 4 Free Fall Motion Purpose: To measure "g", the acceleration of gravity. Apparatus: Picket Fence (plastic strip with uniformly spaced bands), Photogate, Scientificwork® Interface, Software DataStudio® on Macintosh™. Introduction: Neglecting the air resistance and flucturation in acceleration due to gravity, the free fall of an object is a constant acceleration motion that follows the kinematical law: d=d 0 +v 0 t+1/2gt^2. Suggested Procedure:

  1. Turn on the macintosh computer
  2. Turn on the scientificwork interface
  3. Plug the output from the photogate into the #1 digital input channel on the scientificwork interface.
  4. Put the photogate at the edge of your table and make sure the Picket Fence is able to fall through to the floor. Put a foam mattress under the photogate to catch and protect the Picket Fence.
  5. Open DataStudio® and select the free fall experiment. Add distant-time plot, velocity- time plot, and acceleration-time plot into the graph window by dragging and dropping the corresponding icon from the left panel.
  6. Hold the Picket Fence straight right above the photogate. Press the “start” bottom to start the data collection. At the same time release the Picket Fence.
  7. Using the fitting function (linear fitting only) on the graph window to collect experimental data for all three plots. Record the slope of velocity, maximum and minimum value of acceleration. Results and Error Analysis:
  8. Examine the plot of Velocity versus time in the graph display. Determine the slope of the best fit line for velocity-time plot. Select ‘Linear’ from the fit menu.
  9. Apply Statistics to each column in the table display to determine the ‘mean’ value of acceleration. Select ‘Mean’ from the ‘Statistics’ menu.
  10. Record the value for the Mean of the acceleration, and the slope of the velocity-time in the data table I.
  11. Do a regression analysis of the Position-time data to find the acceleration due to gravity. Record your results in the data table I. Questions:
  12. Can an object have an increasing velocity and a constant acceleration? Can the velocity of an object be zero at the same instant its acceleration is non zero?
  13. Find the sources for the deviations found in the experiments

Table I. Measurements Item Value Slope of Velocity versus time Acceleration(mean) Acceleration (Regression) Acceleration (Helmert’s equation)* Percentage of error**

  • Widely used Helmert’s equation for acceleration of gravity: g=980.616 - 2.5928COS(2φ) + .0069(COS(2 φ))^2 - 3.086E-06*H (cm/s^2 ) where g is acceleration of gravity, φ is latitude in degress, and H is the elevation above sea level in centimeters. For TSU, φ = 36.16, H = 160m = 16000cm ** Percentage of error = | ( accepted value – experimental value ) / accepted value | * 100%