Lab 1: Motion in One Dimension Part 1 1
Physics 2305
Lab 1: Motion in One Dimension Part 1
Objectives
• To introduce the student to the Pasco 850 interface and Capstone software • To learn about the functionality of the ultrasonic motion detector • To explore the graphical representation of different types of motion • To examine the relevance of kinematics equations in actual motion • To experiment with free-fall and to understand the assumptions made in
expressing the physical quantity of height in terms of acceleration due to gravity
Recommended Background Reading
• Knight, Chapters 1 and 2 • CAPSTONE APPENDIX: www.phys.vt.edu/~labs/CAPSTONE (this website is case
sensitive).
Name ___________________________
Date _____________________________
GTA Name _______________________
Lab Partner _______________________
Quad & Seat ______________________
CRN ____________________________
Abdulla AL Nahdi
7/13/2020
http://www.phys.vt.edu/%7Elabs/CAPSTONE
Lab 1: Motion in One Dimension Part 1 2
READING NOTES
• In the Capstone file, there will be a video of the experiment with displays that show the sensor reading at those times.
• At the bottom of the Capstone window, there are controls for the video of the experiment:
• Jumps the experiment to the beginning (left arrow) or to the end (right arrow) • Moves the experiment backward (left arrows) or forward (right arrows) one frame at a time. • Plays the experiment at the chosen playback speed. It also pauses the experiment. • Causes the experiment to repeat when it finishes. • Allows you to control the playback speed of the experiment in a pop-up menu.
• This Experiment Selector drop-down menu allows you to switch between experiments if multiple experiments are stored under a single tab.
Lab 1: Motion in One Dimension Part 1 3
Physics 2305 Lab 1, Motion in One Dimension:
Pre-lab Assignment (To be completed and turned in at the start of your lab session)
1. Explain the difference between average and instantaneous velocity.
2. An object initially at rest accelerates through a distance of 1.5 m at which point the instantaneous velocity of the object is 3.5 m/s. Using relevant expressions from the reading, determine:
(a) The average acceleration of the object: initial speed u= 0, final speed v= 3.5, distance d = 1.5m average acceleration a=? v^2-u^2=2*a*d =2*1.5*a=3.5^2=12.25/3 = 4.083 m/s^2
(b) The time it took the object to travel 1.5 meters. v= u+at = 0+at t=v/a = 3.5/4.08 =0.86s
(c) The average velocity of the object during this period of motion. distance /total time = 1.5/0.86= 1.74m/s
3. On the axes below draw a solid line that represents someone walking forward at a speed of 0.5 m/s for 2 seconds, resting for one second, then walking backward at a speed of 1.0 m/s for 2 seconds.
Name ____________________________
CRN ____________________________
Date ____________________________
GTA Name ______________________
V el
oc ity
(m /s
)
Time (s)
+1
-1
0
1 3 5
Abdulla AL Nahdi 7/13/2020
The average velocity is the average rate of change of position of the position( or in other words displacement) with respect to time. And the instantaneous velocity is the specific rate of change of position (displacement) with respect to time at a single point.
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Lab 1: Motion in One Dimension Part 1 4
4. On the axes below draw a solid line that represents someone starting at the origin and walking forward with a constant speed of 0.5 m/s for 2 seconds, standing still for one second, and then moving backward with a constant speed of 1.0 m/s for 2 seconds.
5. A small washer is taped to a ball and the ball is hung from an electromagnet. When a trigger is activated the electromagnet will shut off and the ball will fall through a height of 75 cm to land on a time of flight pad. Determine the amount of time it will take for the ball to impact the time of flight pad once the trigger is activated. (Show your calculations and ignore air resistance)
Po si
tio n
(m )
Time (s)
+2
-2
0
1 3 5
height h = 0.75m initial speed u = 0 using equation of motion: h= v*t+1/2*a*t^2 0.75= 0+1/2*9.81*t^2 t= 0.39s
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Lab 1: Motion in One Dimension Part 1 5
Equipment
You will use the following equipment provided at your station:
• Pasco 850 Lab Interface o Motion Detector (Yellow lead – Digital 1; Black lead – Digital 2) o Time of Flight pad (Digital 3) o Trigger [Photogate] (Digital 4) o Control Box o Drop Box
• Dell Computer workstation • Capstone Software • 2 meter stick • 1 meter stick • Medium sized bin • Yellow acrylic ball with washer attached
Lab 1 Setup Notes
• Check the 850 interface to ensure that the motion detector is plugged into the interface. The yellow lead should be plugged into the Digital 1 port and the black lead into the Digital 2 port.
• From the desktop of the computer, open the class notes folder and access the Lab 1.cap file.
• Read any instructions and confirm the initial setup from the introduction tab. • Clean up your workstation and untangle any cords so that the motion sensor can be
freely moved around the perimeter of your lab table. The motion sensor will break if it falls from the table and lands on the floor.
• General note about printing in this lab: The printers in the lab room annotate printed pages with the quadrant and table number from which they were printed at the bottom of the page. The annotation has the following format:
NB103-Q(quadrant letter)(table number) (time)
For example, the annotation “NB103-QA3 16:30:49” means that the printed page came from Table 3 in Quadrant A at 16:30 hours. When you are at the printers to retrieve your printouts, check the annotations for your quadrant and table number on all of the printouts. If you cannot find your printouts or your work has not printed after 2 minutes, talk to your TA before printing another printout.
Lab 1: Motion in One Dimension Part 1 6
Investigation 1 – Moving in the x-y plane.
The universe is separated into 3 spatial dimensions. Motion in any of these dimensions is independent and the net motion becomes a vector sum of the motions in each. In other words, walking around in the lab room consists of moving in the x-y plane where any straight line path may have components in the �̂�𝒊 and 𝒋𝒋̂ directions depending on the coordinate system you choose. In the following activities we will establish a coordinate system in the lab room and analyze motion in a single dimension.
Activity 1: Determining the Origin
Navigate to the tab named Origin to display a position- time graph and video. In the video you will see a cart on a track. The cart's motion is restricted to moving in one dimension by the track. For convenience we’ll refer to this as the x-axis. Vectors that you record that are parallel to this axis will be denoted with the unit vector .
Now that you have your axis lets learn about the device being used to track the motion in our labs. In this video it is the black device sitting on the right end of the track. Appropriately, it is called a motion sensor (or detector). This sensor has has a range of roughly 15 cm through 3 m. This means that anything that gets closer than 15 cm to the sensor will be recorded as being 15 cm away and anything greater than 3 meters away will be recorded as being 3 meters away. This range is cause by limits in the way the sensor works.
The motion sensor sends out ultrasonic pulses which collide with any object in the viewable range. Some amount of the pulse is reflected back along its path and perturbs the membrane of the motion sensor. This information (i.e. the relative time between sending and receiving a signal) is transferred via a calibration file into information about the relative position of the object. If the object is moving – changing its position during the data taking process – the sensor measures the average velocity between position measurements. As the time period between these measurements decreases, the value of the measured velocity approaches the instantaneous velocity of the object. If the object is accelerating, the sensor measures two instantaneous velocities and reports the average acceleration of the object. In essence, the motion sensor takes position measurements with a certain frequency (adjustable in Capstone) and then performs the following calculations after each measurement:
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 1.cap
7
𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝 𝑎𝑎𝑝𝑝 𝑝𝑝𝑝𝑝𝑡𝑡𝑡𝑡 𝑝𝑝0: 𝑥𝑥(𝑝𝑝0) = 𝑥𝑥0 𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝𝑝 𝑎𝑎𝑝𝑝 𝑝𝑝𝑝𝑝𝑡𝑡𝑡𝑡 𝑝𝑝1: 𝑥𝑥(𝑝𝑝1) = 𝑥𝑥1 𝑣𝑣𝑡𝑡𝑣𝑣𝑝𝑝𝑣𝑣𝑝𝑝𝑝𝑝𝑣𝑣 𝑎𝑎𝑝𝑝 𝑝𝑝𝑝𝑝𝑡𝑡𝑡𝑡 𝑝𝑝0:𝑢𝑢𝑝𝑝𝑢𝑢𝑝𝑝𝑝𝑝𝑢𝑢𝑝𝑝
𝑣𝑣𝑡𝑡𝑣𝑣𝑝𝑝𝑣𝑣𝑝𝑝𝑝𝑝𝑣𝑣 𝑎𝑎𝑝𝑝 𝑝𝑝𝑝𝑝𝑡𝑡𝑡𝑡 𝑝𝑝1: 𝑣𝑣(𝑝𝑝) = 𝑥𝑥1 − 𝑥𝑥0 𝑝𝑝1 − 𝑝𝑝0
= ∆𝑥𝑥 ∆𝑝𝑝
So it is apparent that in a time period Δt, if there are N position measurements taken by the sensor then there will be N-1 velocity measurements. It is important to note that any data appearing on your screen, although connected via a line, still represents a discrete sampling of the system’s behavior. True instantaneous velocity is only achieved in the limit that Δt 0. With velocity measurements in mind, think about average acceleration:
𝑎𝑎(𝑝𝑝) = Δ𝑣𝑣 Δ𝑝𝑝
= 𝑣𝑣(𝑝𝑝′) − 𝑣𝑣(𝑝𝑝)
𝑝𝑝′ − 𝑝𝑝
Question 1-1: Suppose that the data collection frequency of the motion sensor is set to 25 Hz. How many position, velocity, and acceleration measurements are made per second by the motion sensor?
Now that we have a rudimentary understanding of how the sensor collects data we need to find the zero – point of the sensor. This will be the origin of our coordinate system.
Prediction 1-1: Based on how the motion sensor takes data, where do you expect the origin of your coordinate system to be without any adjustment to the motion sensor? Will it be possible for the cart to sit at the origin of this coordinate system?
Now we will test your understanding. In the experiment we are about to do, the cart will:
• Start as close to the origin as possible. • Move roughly 2 meters away from the detector for 10s. • Reverse at the same speed until it is 1 meter from the detector • Pause for 5s • Rapidly return to its starting position in 3s.
Stay on Capstone File - Experiments and Data - Lab 01 - 2305 Part 1.cap
Now use the Prediction tool to trace what you think the position-time graph of this motion will look like. You can choose to either draw it free-hand with the mouse, or create a point by point prediction, whichever you prefer. Once you are happy with your prediction, take a screen shot of it by clicking the snapshot button . You can view snapshots by clicking the journal button and double clicking the image in question. Save it using any means (if you need help with this, be sure to ask your TA during the live session) and include it in your report when you turn it in. Click play in the video control panel to see how well you did. Lab 1: Motion in One Dimension Part 1
Lab 1: Motion in One Dimension Part 1 8
You can view different portions of the data run by shifting the bottom axis. First you should auto-scale your graph from the graph menu and practice using the mouse wheel and dragging each of the axes to scale your data. Once you and your partner are comfortable scaling the data answer the following question:
Observation 1: When the cart moved away from the detector did its position register as positive or negative?
Now navigate to the tab named "Motion on Another Axis". Press play to view the experiment
Observation 2: What happened to the data when the cart was moved perpendicular to the x axis (pulled in front of the track)? Provide an explanation about the limits of the motion sensor range.
Observation 3: In the region of motion where there was did the motion sensor data become choppy or erratic? If so, provide an explanation.
Question 1-2: Based on your observations label the origin, and the positive x and y directions on the following axes. Use the familiar unit vectors and to denote these directions.
The y-axis is perpendicular to the x-axis and the direction of 𝒋𝒋̂ is determined by the following:
motion sensor
Stay on Capstone File - Experiments and Data - Lab 01 - 2305 Part 1.cap
Lab 1: Motion in One Dimension Part 1 9
• Place the fingers of your right hand parallel to the x direction with your palm facing the floor. Curl your fingers into a fist and stick out your thumb. 𝒋𝒋̂ points in the direction of your thumb.
Congratulations, you now have a coordinate system and an understanding of what types of motion will give nice data for the far setting on the motion sensor.
Activity 2: Exploring Position versus Time graphs.
Navigate to the tab named "x vs. t" in the Capstone software. A video and a position versus time graph will be shown as well as a digital readout of the cart's instantaneous velocity. In this activity and the next you will explore position versus time graphs for several types of motion.
Part 1: Motion at constant velocity Once again use the prediction tool to predict what you think the data will look
like for the following motion: • The Cart remains still for 5s. • It steadily moves away from the origin for 5s. • It moves more quickly away from the origin for 5s.
Once you are satisfied with your prediction, click the drop down menu from the data triangle and choose "select all". Press play to see how your prediction compares to the actual motion. Include a screen shot of the graph with both your prediction and the data in your lab report.
Question 1-3: How do the slopes of each type of motion compare with one another? Using the linear fit tool from the graph menu determine the ratio of the slopes of the quick steady walking to that of the slow steady walking and record it here, showing your calculations.
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 2.cap
Lab 1: Motion in One Dimension Part 1 10
Part 2: Motion with changing velocity Navigate to the tab Named "Motion with Changing Velocity". Once again
you will predict the motion of the cart, saving the prediction and data for your report. There are two motions you will examine:
1. Ensure the experiment selector has "Part 2: Away" selected. Starting from rest as close to the origin as possible while still able to record good data, the cart will slowly increase speed over time from very slow to moderately fast away from the sensor. This motion will only last 5 s.
2. Change the experiment to "Part 2: Towards". Starting from rest at the 2 meter mark, the cart will slowly increase its speed over time from very slow to moderately fast moving toward the sensor. This motion will only last 5 s.
Repeat these experiments until you are satisfied with the plots of both types of motion. Display your best run of each of these types of motion and use the annotate tool to label the graphs for this activity. Take a screenshot of your data using the Journal tool in Capstone. Print it and collect the printout that is annotated with your proper quadrant and table number. Include it after this page. You should delete this graph from the journal after you print it
Question 1-5: Provide a mathematical reason for the shape of the position-time graphs generated. What type of motion have you plotted? You are welcome to apply different fits to your data from the graph menu but you should already be familiar with the expression that denotes this type of motion.
Question 1-6: Write down the expression (and any assumptions you made when answering the previous question) that represents this type of motion.
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 3.cap
Lab 1: Motion in One Dimension Part 1 11
Activity 3: Exploring Velocity versus Time graphs
We will use the same data from Part 2 to compare position and velocity graphs. You can review this data in the tab "x vs. t" Navigate to the tab named "v vs. t". Capstone is now taking the position-time graph and extrapolating from this data a velocity-time plot.
Question 1-7: Does the velocity-time graph contain information about the cart's starting or ending positions? Explain.
Question 1-8: From the data displayed, determine the net displacement and the average velocity for a region of good data using the appropriate functions (refer to the online appendix for hints on the graph menu tools). State the mathematical operations performed by Capstone in determining each of these values.
Display the run from Part 2 of Activity 2 and answer the following questions.
Question 1-9: What physical quantity does the slope of a velocity-time graph represent?
Question 1-10: Write down an expression which best describes the carts velocity as a function of time when moving away from the detector with a steadily increasing speed.
Activity 4: Velocity Matching
Navigate to the tab "velocity match". You will attempt to predict the velocity time graph that will be produced by the following steps:
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 4.cap
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 5.cap
Lab 1: Motion in One Dimension Part 1 12
Once you are happy with your prediction, press play to see how you did. Take a screenshot of both and turn them in with your report. Note: Real world data will have variation in it that your "theoretical" prediction will not. When performing experiments It is important to be able to tell what data is caused by experimental error and what conflicts with your theory.
• 0 – 2 seconds: The cart is at rest
• 2 – 5 seconds: The cart travels away from the motion sensor at a constant 0.5 m/s.
• 5 – 7 seconds: The cart is at rest.
• 7 – 10 seconds: The cart travels 0.9 m back towards the sensor at a constant velocity.
Investigation 2 – Motion perpendicular to the x-y plane
So far we have analyzed motion in the x-y plane by setting up our coordinate system relative to the motion sensor and defining motion recorded by the sensor as along the x axis. You have by now discovered that this was an arbitrary choice motivated by nothing more than convenience. Keeping our current definitions of the x and y axis we can use similar tactics to determine the z direction and the direction that 𝒌𝒌� will point. To do so we will adopt a convention that is common in physics and mathematics. It should be apparent that defining the plane of the page to be x and y as shown leaves only two possible choices for the direction of 𝒌𝒌�, viz. into and out of the page. Label the direction of 𝒌𝒌� on the axes that follow by taking these steps:
1. Place your hand at the origin so that your fingers point along �̂�𝒊 and such that 𝒋𝒋̂ has its source at your palm. Consult your GTA if you are having difficulty.
2. Curl your fingers into a fist with your thumb extended. Your thumb will point in the direction of 𝒌𝒌�.
3. In the circle at the origin denote ⊙ if the unit vector 𝒌𝒌� points out of the page or ⊗ if the k vector points into the page.
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 5.cap
Open Capstone File - Experiments and Data - Lab 01 - 2305 Part 6.cap
Lab 1: Motion in One Dimension Part 1 13
This investigation will give insight to motion in the 𝒌𝒌� direction. This is the special direction through which gravity always acts, and so we will analyze the motion of objects subject to accelerations due to gravity. Close to the surface of the earth acceleration due to gravity is constant and, ignoring any slight changes due to elevation, has a magnitude of 9.81 m/s2.
Question 2-1: Using the coordinate system above write down the vector acceleration due to gravity.
Before taking we will explain the experimental setup. The drop box at the top houses an electromagnet and is attached to a horizontal rod which in turn is clamped to a vertical rod. The vertical rod is clamped to the shelf above the table and its height is adjustable. A time of flight pad is positioned inside a catch bin directly below the drop box. Place the bin on the table directly below the drop box. . There is a long length of RJ11 cord that connects the drop box with a control box and a separate cord with a ¼” plug which connects the control box to a trigger. This allows us to start a timer at the same time that the ball is dropped and stop the timer as soon as the ball hits the time of flight pad.
Activity 1: Dropping an object from several heights We will start with the bottom of the ball at a height of 1 meter.
𝚥𝚥 ̂
𝚤𝚤̂ 𝑢𝑢�
Stay on Capstone File - Experiments and Data - Lab 01 - 2305 Part 6.cap
Lab 1: Motion in One Dimension Part 1 14
Question 2-2: By making the appropriate substitutions, derive a general expression for the time of flight of an object falling through a known height. Solve this expression to determine the theoretical time of flight for the yellow acrylic ball.
In this file you will see Five tabs named "Time of Flight ___ m". Play the experiment in each tab and record the time it takes the ball to fall for each height. Type these values in right side column in the table on the "Time of Flight Graph" tab.
The graph will display your data as you type it. Recall from the expression you derived in question 2-2 that free fall time is a function of height. You will now set up a user-defined best fit line to check the validity of your expression. From the fit tool select user-defined. You should see a curve that has the form A*x^(1/2). If this is not the case you can edit the curve from the menu on the left hand side of the screen.
Stay on Capstone File - Experiments and Data - Lab 01 - 2305 Part 6.cap
Lab 1: Motion in One Dimension Part 1 15
1. Click on the “Apply selected curve fits to active data” button in the top menu and select “User-defined” in the drop down menu.
2. Click on the “Curve Fit Editor” button in the bottom of the left-side menu. 3. On the graph, click on the box by the fitted curve labeled “User Defined”. 4. In the “Curve Fit Editor”, type in A*x^(1/2).
Take a screenshot of your data and turn it in with your report.
Question 2-3: Determine the constant A from the one you derived in Question 2 – 2 and compare it to the value reported by Capstone.
Question 2-4: Does your best fit line reflect the functional dependence of time on initial height? If not, explain possible sources of error in your experiment.
Question 2-5: From your understanding of motion with constant acceleration and air resistance, is your data less accurate when the yellow acrylic ball is dropped through larger or smaller heights?
Question 2-6: Write down expressions for the yellow acrylic ball’s position as a function of time and velocity as a function of time taking a point on the surface of the time of flight pad directly beneath the electromagnet to be the origin.
WHEN THERE ARE 10 MINUTES REMAINING IN THE LAB SESSION STOP WHAT YOU ARE DOING AND ANSWER THE POST-LAB QUESTIONS THAT FOLLOW.
If you need to edit the user-defined best fit line,
Stay on Capstone File - Experiments and Data - Lab 01 - 2305 Part 6.cap
Lab 1: Motion in One Dimension Part 1 16
Lab 1 Post-Lab Questions: 1. Determine the total distance traveled by an object whose motion is described by the velocity-time graph below. Show your calculations with units.
2. An object is dropped from rest through a height of 2.5 meters. Determine the time of flight of the object and the object’s speed just before it hits the ground. Show your calculations. 3. On the axes below sketch a graph of an object that accelerates uniformly from rest to a position of 2.0 meters in 3 seconds.
V el
oc ity
(m /s
)
Time (s)
+1
-1
0
1 3 5
Po si
tio n
(m )
Time (s)
+2
-2
0
1 3 5
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