Unit 7

1. Unit 7 The Track & Field Championship

2. Essential Questions • What is the relationship between speed, distance, and time, and how are they calculated? • How can we use trends from track and field competitions to make predictions for future competition results? • Are average speed and speed the same at all points in a race? • How can we use a graph to analyze a runner’s speed in a race? • How does our stride length relate to wavelength, and how can we use this data to calculate the frequency of a runner? • What is the difference between motion and landing position of objects dropped straight down to those with projectile motion? • How does the concept of energy conservation relate to the pole vault?

3. Chapter Challenge (pp. 140-141) • TASOK is going to send a track and field team to the Penn Relays • You need to write a physics manual to train the TASOK team and help them improve their performance for 3 different track & field events (must include 1 field and 1 track event) which includes the following: • Include a description of the physics principles related to the events • Provide specific techniques to improve performance (diagrams recommended) • Help students compare themselves with their competitors (i.e. are there different techniques for your events?) • Due Date: April 12

4. Day 1: Running the Race • Learning Objectives: • Measure distance in meters along a straight line • Use a stopwatch to measure the amount of time for a person to travel a measured distance • Use measurements of distance and time to calculate the average speed of a running person • Compare the average speeds of a running person during segments of a run • Compare the average speeds of different persons running along the same path • Infer factors which affect the average speed of a running person

5. Starter

6. Starter (cont’d) • Very few people can run the 100m in under 10s (Usain Bolt ran it in 9.63s at this past summer’s Olympic Games) • How can you measure a runner’s speed? • Does running twice as far take twice as much time? Explain. • What time do you think Usain Bolt ran (& won) the 200m finals in at this past Olympics? • Time: 15 minutes

7. Activity 1 • You will be put into groups of 5 people • Choose 1 person in the group who will run 20m • The other 4 people will be timers • Mark out a 20m “track” with markers every 5m (ie. At 0m, 5m, 10m, 15m, and 20m) • The timers will stand at all the positions (except 0m) and record the time it takes for the runner to start to get to their position • How will you calculate the time taken to run the 5m interval you need to time? • The person at the 5m mark will be the starter • Run 3 trials, giving the runner a couple of minutes in between to rest. This is when you can record your data • Time: 30 minutes

8. Data Table

9. Activity 2 • Calculate the speed at the different intervals and complete your table • How do you calculate the different times? You will need to work together and have everyone’s data to calculate these. • What was the runner’s average speed for the 4 intervals? • Does running twice as far take twice as much time? • What is the runner’s average speed for the entire 20m? How does this compare to the 4 intervals? • Which interval did the runner have the greatest speed? How does this compare to other group’s data? • Time: 15 minutes

10. Activity 3 • Graph the data you collected, using the average time for each of the four intervals • What type of graph will you use? • What information goes on the x-axis? The y-axis? • Give your graph an appropriate title • Time: 10 minutes

11. Closing & Homework • Create a distance, speed, time triangle that can be used to calculate for an unknown. • Read “For You to Read”pg. 145 • Physics to Go, pg. 146 #1a, 2, 4, 6 • Reminder: All corrections and outstanding work due this Friday!

12. Day 2: Analysis of Trends • Learning Objectives: • Sketch a best fit curve or trend line on a graph on which points have been plotted • Extrapolate graphs to predict trends beyond available data • Create graphs of data presented in tabular form • Calculate the average speed of a runner given distance and time • Calculate the time required for a runner to travel a specified distance given the runner’s average speed • Interpret information presented in graphical form

13. Starter • Current trends indicate that women will start outrunning men in 65 years • Watch the following videos. One is from 1928, the other is from 2012. • Is it useful to compare track records over many years of time? • Can future track records be predicted based on past performances? • What are some differences that you notice between the races from the two time periods? • Time: 20 minutes

16. Activity 1 • Look at the graph “Speed vs. Year: Men’s Olympic 400m Dash” • What is this graph showing? • Sketch a curved line or straight line through the data points • What is the trend that you observe happening in the speed for the 400m over the past 100 years? • Guess what the line would look like until 2020. According to your extrapolation, what will the speed of the winner of the 2020 Olympics be? • In 1980, the speed of the winner is ~9.0m/s. How fast did the winner do the 400m run in (assume 9.0m/s)? • Time: 20 minutes

17. Activity 2 • Look at the graph “Speed vs. Distance: Men and Women, Penn Relays” • What does this graph show? • Sketch the shapes of the two graphs that are shown • What do you notice about the trends of the average speed for men and women as the distance of the races get longer? • Extrapolate to predict the record speed for the 10,000m for men and women • Time: 20 minutes

18. Activity 3 • Your plan to help your school’s track team at the Penn Relays will only be as good as your knowledge of current performances in T&F. • Research the top times/distances for under 18 boys and girls(high school students) in the following events (use meters for the field events). Some Canadian sites to help you include OTFA and OFSAA. • High Jump • 100m • 400m hurdles • 1500m • Triple Jump • Time: 20 minutes

19. Closing & Homework • Does knowing past performances help determine future performances? Why or why not? • Physics to Go, pg. 150 #2, 3, 4,5

20. Day 3: Who Wins the Race? • Learning Objectives: • Measure short time intervals in arbitrary units • Measure distances to the nearest mm • Use a record of an object’s position vs. time to calculate the object’s average speed during designated position and time intervals • Measure and describe changes in an object’s speed • Relate changes in the speed of an object traveling on a complex sloped track to the shape of the track

21. Starter • The average jogging pace for a human is 9-12 km/h. The average running pace for a human is (top athlete) 36 km/h. • How fast does an average car travel? • How do you determine who wins a race? • The runner with the highest finishing speed? • The runner with the highest average speed? • The runner with the greatest top speed? • Time: 15 minutes

22. Starter

23. Activity 1 • Move to your lab groups • Design an experiment that determines a cart’s average speed • You will test the cart’s speed on a flat surface and three inclines • Sections to include are: • Aim/Objective • Hypothesis • Materials • Procedure • Data • Analysis (after experiment is complete) • Time: 20 minutes

24. Activity 2 • Carry out your investigation after you have your plan okayed by me • Type up your plan and results • Due: Friday, March 22 • Time: 30 minutes

25. Closing & Homework • How do you determine the average speed of an object? • On which track produced the top speed for your cart? • Physics to go, pg. 155 #3, 4, 5, 6

26. Day 4: Understanding the Sprint (60 min) • Learning Objectives: • Calculate the average speed of a runner given distance and time • Produce a histogram showing the average speeds of a runner during segments of a race; analyze changes in a runner’s speed • Produce a graph of distance vs. time from split time data for a runner • Estimate the slope of a distance vs. time graph at specified times • Recognize that the slope of a distance vs. time graph at a particular time represents the speed at that time

27. Starter

28. Starter

29. Starter • After watching the videos for the 100m (Carl Lewis, 1991) and the long jump (Mike Powell, 1991) discuss the following questions: • How long does it take to get up to maximum speed? • Does it differ depending on the event you are competing in? Why? • When does a sprinter want to be at their maximum speed? How about a long jumper? • Time: 15 minutes

30. Activity 1 • Work through steps 1-5 on pp. 156-158 • Graph paper is available for you to use • When you finish, you can do research for your chapter challenge • Time: 45 minutes

31. Homework • Physics to go, pg. 159 #2, 3, 5

32. Day 5: Acceleration • Learning Objectives: • Understand the definition of acceleration • Understand meters per second per second as the unit of acceleration • Distinguish between acceleration and deceleration

33. Starter • Accelerating out of the starting block is important if a runner is going to win a race • If all runners in a race have equal top speeds and none “fade” at the end of the race, what determines who wins? • How is response time a factor in determining who wins the race? • What do you think blocks do, and what do you think the correct technique is for starting in them? • Time: 15 minutes

34. Starter

36. Activity 1 • In your lab groups, construct an accelerometer like the picture below

37. Activity 2 • Work through the “For you to do” • Choose someone who doesn’t normally record to be the recorder • Choose 2 people to walk forwards and backwards to compare results and make sure that your results are accurate • Time: 45 minutes

38. Closing & Homework • You can use this time to research your events for the chapter challenge • I am going to come around and ask your groups and what events you are doing • Read “Physics Talk”, pg. 162 and “For you to Read”, pg. 163 • Physics to Go, pg. 165 #1, 2, 3, 6, Choose 3 from 8, 9, 10, 12, 13, 14, 15, or 16

39. Day 6: Measurement • Learning Objectives: • Calibrate the length of a stride • Measure a length by pacing and with a meter stick • Identify sources of error in measurement • Evaluate estimates of measurements as reasonable or unreasonable • Measure various objects and calculate the error in each measurement

40. Starter

41. Starter • In about 200 BC, Eratosthenes calculated the circumference of Earth. He used shadows cast by the sun in two cities and a measurement of the distance between the two cities. The distance between the cities was found by pacing. • Two people measure the length of the same object. One reports a length of 3m, the other reports a length of 10m. Has one of them goofed? Why do you think? • What if the measurements were 3m and 3.1m? • How does this play a factor in measuring the distances jumped or thrown in track and field events? • Is there room for error in these events? How so? • Time: 15 minutes

42. Activity 1 • Move to your new lab groups • Work through steps 1-8 on pp.167-169 • Choose 1 person to record, one person to walk, and one (or two) person (people) to measure • Hand in your answers/observations when complete • Time: 40 minutes

43. Activity 2 • You may use this time to work on your chapter challenge • This is your last chance before break to ask me questions about form, technique, etc.

44. Closing & Homework • For you to read, pg. 169 • Physics to go, pg. 170 #1, 3, 4, 7

45. Day 7: Increasing Top Speed • Learning Objectives • Calculate the average speed of a runner given distance and time • Measure the frequency of strides of a running person • Measure the length of strides of a running person • Recognize that either the equation (speed = distance/time) or the equation (speed = stride frequency x stride length) may be used to calculate a runner’s speed with equivalent results • Infer ways in which stride length and stride frequency can be adjusted by a runner to increase speed

46. Starter • A cheetah can reach a top speed of 100km/h (30m/s) • What is the top speed a runner can reach? • Watch the video of the cheetah running • What are some differences between a human’s stride and a cheetah’s stride? • What can a runner do in order to increase their top speed? • Time: 15 minutes

47. Activity 1 • Watch the video of the runner • Calculate their speed (note it is yards/sec – where are they running? Why is it in yards/sec?) • You will need a stopwatch to record their time • Compare the speed you calculated to the speed the people at your desk got • Why are there discrepancies? (Think back to last lesson) • Time: 10 minutes

48. Activity 2 • Now count the number of strides taken by the runner during the entire run • Use the number of strides and the total time to calculate the runners stride frequency in strides/sec • Stride frequency = number of strides time (sec) • Time: 5 min

49. Activity 3 • Calculate the average length of one stride of the runner • How will you do this? • Calculate the runner’s speed using the “new” equation for speed: speed = stride frequency x stride length • Compare the results of your two speeds • Do the equations agree on the speed of the runner? • How good is the agreement? • Explain any differences in results that you obtained • Time: 15 min

50. Activity 4 • Work through steps 4-8 on pg. 172 with your lab group • You may use the field or the covered court (whichever is not being used by the PE class) • Choose different people from Tuesday to be the recorder, runner, and measurer • Hand in your observations when you are completed • Time: 30 minutes