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Modeling Gravity and Friction: A STEM Activity Using Trigonometry

Modeling Gravity and Friction: A STEM Activity Using Trigonometry. By: John Lamb, Ph.D. The University of Texas at Tyler http://math.uttyler.edu/ut3mc/stem. How this started.

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Modeling Gravity and Friction: A STEM Activity Using Trigonometry

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  1. Modeling Gravity and Friction: A STEM Activity Using Trigonometry By: John Lamb, Ph.D. The University of Texas at Tyler http://math.uttyler.edu/ut3mc/stem

  2. How this started • Discovery Science Place had a “Golf Ball Room” with spiraling ramps, rollercoaster simulations, and a station that illustrated gravity and friction for young children. • As a secondary mathematics enthusiast, I wanted to know if the behavior of the ball on the gravity ramp could be modeled?

  3. This led to some research • Galileo • Tautochrone • Pendulum

  4. Galileo

  5. Tautochrone(curve of equal decent)Cycloid

  6. Pendulum

  7. Guiding Question • What function would model the effect gravity and friction has on a ball as it travels on a curved ramp?

  8. Field Trip To Discovery Science Place • I had three independent study pre-service mathematics education students and we went to the discovery Science Place with calculators, CBRs, and laptops. • I had an conceptual idea of how to collect the data and answer the guiding question, but I tried to guide the students toward discovering what they needed to do to collect accurate data that would model the behavior of the golf ball on the ramp. • We were mildly successful, only because of limited time.

  9. Here is what we came up with Cleaned Data Raw Data Modeling Function

  10. Middle and High School Math and Science Teachers • At the end of that semester, I presented the idea to some middle and high school math and science teachers from the East Texas area. • I couldn’t take them all to the Discovery Science Place, so I had to bring the ramp to them. • I wanted to do something that I believe a math and science teacher operating on a small (literally microscopic) budget could do. • I therefore spent about $5 and build a ramp using mostly supplies a school would already have.

  11. Materials • Decaying Ball Materials • 2 CBRs • 2 TI-84s • Ball • 8’ corner molding (cove) piece • 2 Ring Stands • Velcro Straps • Duct Tape • Measuring Tape • Computer • TI-Connect Software • Excel

  12. Some Examples • Show Excel documents

  13. Then I wrote to present here • I was accepted…Yay • But I now had the problem of getting my ramp not just across town, but across the country. • So I turned to the internet and found these stringless pendulums you have at the table

  14. Show iPad Video

  15. Now, Let’s Experiment • Phase I: • Make sure your CBRs on the left and right are the same distance away from the center of the ramp. • What is the distance from your CBR to the ball resting at the center of the ramp?

  16. Engage and ExploreMake Sure you get smooth graphs! • Using correct timing, collect distance over time data using both CBRs for 15 seconds for the ball bearing and 10 seconds for the golf ball. You want to collect 300 data points. • List the minimum points (ordered pairs) found from each side of the ramp from either the golf ball or ball bearing.

  17. Example Ordered Pairs

  18. More Exploration • What observations can you make about the period and amplitude of the graphs you found? (hint: you may need to use the distance and points found earlier)

  19. Let me Wave My Hands at Phases II • Transfer your data from your calculator to your computer. • Using the data from the CBR where the ball started on the ramp, you need to transform the data so it is reflected and translated to the first quadrant representing the upper half of the sinusoidal function. This is done by subtracting the initial CBR distance then multiplying by negative one. Then remove all the negative distance points. • Using the data from the other CBR, you need to translate the points down by the initial CBR distance to the fourth quadrant representing the lower half of the sinusoidal function. Then remove all the positive distance points. • Now combine both data sets, order them by time, and remove any points that share the same time value. Then graph the cleaned data to see the damping trig function. • Transfer the data from the computer to the calculator.

  20. The real Mathematics • Using the calculators and L3 and L4 • Plot the points on the calculator and then try and determine the damping trig function that best fits your data. The damping function will be in the form f(x)=a*cos(b*x+c)+d • (hint: f(x)=a*e^(-b*x)*cos(2*pi/period*x+c)+d where a, b, c, and d are unknowns) • What is your damping function that models the movement of the ball?

  21. Visit Website or email • If you have questions or want the powerpoint and any handouts we have used, please visit our STEM website • http://math.uttyler.edu/ut3mc/stem • My email is jlamb@uttyler.edu

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