Name Class Date. Activity P37: Time of Flight versus Initial Speed (Photogate)

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Name Class Date Activity P37: Time of Flight versus Initial Speed (Photogate) Concept DataStudio ScienceWorkshop (Mac) ScienceWorkshop (Win) Projectile motion P37 Time of Flight.DS P08 Time of Flight P08_TOF.SWS Equipment Needed Qty Equipment Needed Qty Photogate (CI-6838 or ME-9204) 2 Photogate Mounting Bracket (ME-6821) 1 C-clamp 1 Projectile Launcher (ME-6800) 1 Extension Cable (PI-8117) 1 Time-of-Flight Accessory (ME-6810) 1 What Do You Think? Can you predict how long a ball will stay in the air? Does a change in its initial speed change the time of flight? If so, how? Take time to answer this question in the Lab Report section. Background The vertical motion of a freely falling ball launched horizontally off a table of height d is independent of any horizontal motion the ball may have. Thus the time for a ball to fall to the ground is independent of its horizontal speed. The distance d a ball falls from rest as a function of the time of fall t is given by: d 1 2 gt2 where g is the acceleration due to gravity in free fall. Thus the time for a ball to fall straight down a distance d from rest to the ground is given by: t 2 d g If a ball launched horizontally with a non-zero initial speed takes the same amount of time to reach the ground as a ball that drops from rest from the same height, this equation also gives the time of flight for any ball launched horizontally regardless of the initial speed of the ball. SAFETY REMINDERS Follow all directions for using the equipment. Procedure Use two Photogates measure the initial speed of a ball that is fired from a Projectile Launcher. Use the Time-of-Flight pad to measure the time of flight for the ball. Use ScienceWorkshop or DataStudio to record and display the time-of-flight and the initial speed. P37 1999 PASCO scientific p. 7

Physics Labs with Computers, Vol. 2 Student Workbook P37: Time-of-Flight vs. Initial Speed of a Projectile 012-07001A Compare the time-of-flight for different values of initial speed when the launcher is aimed horizontally to the time-of-flight for different values of initial speed when the launcher is aimed at an angle above horizontal. p. 8 1999 PASCO scientific P37

Name Class Date PART I: Computer Setup 1. Connect the ScienceWorkshop interface to the computer, turn on the interface, and turn on the computer. 2. Connect the stereo phone plug of one Photogate into Digital Channel 1 on the interface. Connect the stereo phone plug of the second Photogate into Digital Channel 2 on the interface. Connect the Extension Cable s stereo phone plug into Digital Channel 3 on the interface. 3. Open the file titled as shown: DataStudio ScienceWorkshop (Mac) ScienceWorkshop (Win) P37 Time of Flight.DS P08 Time of Flight P08_TOF.SWS The DataStudio file has a Table display of Time of Flight vs. Initial Speed and a Workbook display. Read the instructions in the Workbook. The ScienceWorkshop document has a Table display of tflight (s), or Time of Flight, and vinitial (m/s), or Initial Velocity. PART II: Sensor Calibration and Equipment Setup You do not need to calibrate the Photogates or the Time-of-Flight pad 1. Clamp the base of the projectile launcher to the edge of a sturdy table. Aim the launcher away from the table toward the center of an open area at least 3 meters away. 2. Adjust the angle of the launcher to zero degrees so the plastic ball will be launched horizontally. 3. Slide the photogate mounting bracket into the T-slot on the bottom side of the projectile launcher. Mount the Photogate that is connected to Digital Channel 1 on the bracket in the position closest to the end of the launcher. Mount the Photogate that is connected to Digital Channel 2 on the bracket in the position farthest from the end of the launcher. 4. Connect the Time-of-Flight pad s stereo phone plug into the end of the extension cable. P37 1999 PASCO scientific p. 9

Physics Labs with Computers, Vol. 2 Student Workbook P37: Time-of-Flight vs. Initial Speed of a Projectile 012-07001A PART IIIA: Data Recording Horizontal Launch Angle 1. Put the plastic ball into the projectile launcher. Cock the launcher to the short-range position. 2. Test fire the ball to determine where to place the timing pad on the floor. Put the timing pad on the floor where the ball hits. 3. Reload the ball into the projectile launcher, and cock the launcher to the short range position. 4. Start recording data. (In DataStudio, click Start. In ScienceWorkshop, click REC.) 5. Shoot the ball on the short-range position. After the ball hits the Time-of-Flight pad, do the following: In DataStudio, click Stop. Result: Run #1 appears in the Summary list. In ScienceWorkshop, click PAUSE to momentarily pause data recording. Result: The PAUSE button allows you to reload the launcher without accidentally recording data when the Photogates are blocked during reloading. 6. Reload the ball into the launcher, but cock the launcher to the middle range position. Testfire the ball to determine the new location to put the Time-of-Flight pad. Move the pad. 7. Reload the ball into the launcher and put the launcher in the middle range position. 8. When you are ready, resume recording data. 9. Shoot the ball with the launcher in the middle range position. After the ball hits the Timeof-Flight pad, click Stop (in DataStudio) or click PAUSE (in ScienceWorkshop). 10. Reload the ball into the launcher, but cock the launcher to the long-range position. Test-fire the ball to determine the new location to put the Time-of-Flight pad. Move the pad. p. 10 1999 PASCO scientific P37

Name Class Date 11. Repeat the data recording process as you did for the short and middle ranges. 12. After completing the data recording for the long-range position, end data recording. In DataStudio, the Summary list shows three runs of data. In ScienceWorkshop, the Data list shows Run #1. PART IIIB: Data Recording Non-horizontal Launch Angle 1. Adjust the angle of the projectile launcher to 30 degrees above horizontal. 2. Test-fire the ball on the short-range position. Move the timing pad. 3. When you are ready, begin data recording. Shoot the ball on the short-range position at 30 degrees above horizontal. 4. After the ball hits the timing pad, click Stop in DataStudio or click PAUSE in ScienceWorkshop. 5. Repeat the process for the middle range position. 6. Repeat the process for the long-range position. 7. End data recording. In DataStudio, the Summary list shows six runs of data. In ScienceWorkshop, the Data list shows Run #1 and Run #2. P37 1999 PASCO scientific p. 11

Physics Labs with Computers, Vol. 2 Student Workbook P37: Time-of-Flight vs. Initial Speed of a Projectile 012-07001A Analyzing the Data DataStudio 1. Use the Data menu in the Table display toolbar to select Run #1 for the Initial Speed and for the Time-of-Flight. Record the values for speed and time-of-flight for the first projectile launcher range in the Launch Angle Horizontal Data Table in the Lab Report section. 2. Repeat the process to select Run #2 and then Run #3. Record the values. 3. Use the Data menu in the Table display toolbar to select Run #4 for the Initial Speed and for the Time-of-Flight. Record the values for speed and time-of-flight for the first projectile launcher range in the Launch Angle 30 above Horizontal Data Table in the Lab Report section. 4. Repeat the process to select Run #5 and Run #6. Record the values. Analyzing the Data - ScienceWorkshop 1. Open the Table display for Run #1 and record the initial speeds and time-of-flight values for each of the projectile launcher ranges in the Launch Angle Horizontal Data Table in the Lab Report section. 2. Open the Table display for Run #2 and record the initial speeds and time-of-flight values for each of the projectile launcher ranges in the Launch Angle 30 above Horizontal Data Table in the Lab Report section. Use your results to answer the questions in the Lab Report section. p. 12 1999 PASCO scientific P37

Name Class Date Activity P37: Time of Flight versus Initial Speed What Do You Think? Can you predict how long a ball will stay in the air? Does a change in its initial speed change the time of flight? If so, how? Data Table Launch Angle Horizontal Launch Angle 30 above Horizontal Questions Range Initial Speed (m/sec) Time of Flight (sec) Short Middle Long Range Initial Speed (m/sec) Time of Flight (sec) Short Middle Long 1. How do the values for the time of flight for the short, middle, and long range distances compare when the ball was launched horizontally? 2. How do the values for the time of flight for the short, middle, and long range distances compare when the ball was launched at 30 degrees above the horizon? 3. Why would time of flight depend on the angle of the launch? P37 1999 PASCO scientific p. 13

Physics Labs with Computers, Vol. 2 Student Workbook P37: Time-of-Flight vs. Initial Speed of a Projectile 012-07001A p. 14 1999 PASCO scientific P37

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