Transverse waves on an elastic spring

1. Transverse waves on an elastic spring

2. What happens when a a short pulse is “flicked”down a long, taut spring? • It keeps its shape but gets smaller the farther it goes. • It keeps its shape and stays the same size. • It changes shape, but stays about the same size. • It changes shape, and gets smaller. • I have no clue. NEXUS/Physics Clicker Questions

3. What happens? NEXUS/Physics Clicker Questions

4. y x Pulse moving to the right If this is the space-graph (photo at an instant of time) what does the time-graph look like for the bead marked with a red arrow? • Choice One • Choice Two • Choice Three • Choice Four NEXUS/Physics Clicker Questions • Choice Five • Choice Six • Choice Seven • Choice Eight

5. y x Describing the motion of the beads Pulse moving to the right • Sketch vertical arrows showing how each bead is moving as the pulse moves from the first position to the second. NEXUS/Physics Clicker Questions vy x

6. A pulse is started on the string moving to the right. At a time t0 a photograph of the string would look like figure 1 below. A point on the string to the right of the pulse is marked by a spot of paint. (x is horizontal and right, y is vertical and up) Which graph would look most like a graph of the y displacement of the spot as a function of time? NEXUS/Physics Clicker Questions 7 None of these

7. A pulse is started on the string moving to the right. At a time t0 a photograph of the string would look like figure 1 below. A point on the string to the right of the pulse is marked by a spot of paint. (x is horizontal and right, y is vertical and up) Which graph would look most like a graph of the x velocity of the spot as a function of time? NEXUS/Physics Clicker Questions 7 None of these

8. A pulse is started on the string moving to the right. At a time t0 a photograph of the string would look like figure 1 below. A point on the string to the right of the pulse is marked by a spot of paint. (x is horizontal and right, y is vertical and up) Which graph would look most like a graph of the y velocity of the spot as a function of time? NEXUS/Physics Clicker Questions 7 None of these

9. A pulse is started on the string moving to the right. At a time t0 a photograph of the string would look like figure 1 below. A point on the string to the right of the pulse is marked by a spot of paint. (x is horizontal and right, y is vertical and up) Which graph would look most like a graph of the y force on the spot as a function of time? NEXUS/Physics Clicker Questions 7 None of these

10. What Controls the Speed of the Pulse on a Spring? To make the pulse go to the wall faster • Move your hand up and down more quickly (but by the same amount). • Move your hand up and down more slowly (but by the same amount). • Move your hand up and down a larger distance in the same time. • Move your hand up and down a smaller distance in the same time. • Use a heavier string of the same length under the same tension. • Use a string of the same density but decrease the tension. • Use a string of the same density but increase the tension. • Put more force into the wave, • Put less force into the wave. NEXUS/Physics Clicker Questions

11. Below is a snapshot of a piece of an elastic spring on which a pulse is traveling.   Each square of the grid represents 1 cm.   In a video of the motion of the pulse, the pulse is observed to move a distance of 2 cm in 0.04 seconds. Three pieces of tape are attached to the spring.   They are marked by small circles in the figure and are labeled A , B , and C . Graph the velocity of each of the 3 pieces of tape as the pulse moves past them. (Take this instant as t = 0) NEXUS/Physics Clicker Questions

12. Which goes with which? Graph I Graph II NEXUS/Physics Clicker Questions Graph III

13. How do waves combine? We know how one pulse moves. What happens when we get two pulses on top of each other? NEXUS/Physics Clicker Questions ?

14. What happens if they overlap perfectly? ? NEXUS/Physics Clicker Questions

15. What happens when they would have passed each other if the other hadn’t been there? 1. (Bounce off) ? NEXUS/Physics Clicker Questions (Pass through) 2. (Cancel) 3. 4. Other

16. 1. NEXUS/Physics Clicker Questions 2. ? 3. Other

17. How about on the same side? ? NEXUS/Physics Clicker Questions

18. NEXUS/Physics Clicker Questions

19. An elastic string (modeled as a series of beads) driven by a wheel driving one of the beads up and down sinusoidally. . The driving wheel has generated a traveling wave of amplitude 10 cm moving to the right. (The string continues on for a long way to the right as indicated by its going “out the window.”) The figure shows t= 0, when the green bead marked “II” is passing through its equilibrium point. Which of the graphs could serve as the graph of thevertical displacement of bead II as a function of time? NEXUS/Physics Clicker Questions

20. An elastic string (modeled as a series of beads) driven by a wheel driving one of the beads up and down sinusoidally. . The driving wheel has generated a traveling wave of amplitude 10 cm moving to the right. (The string continues on for a long way to the right as indicated by its going “out the window.”) The figure shows t= 0, when the green bead marked “II” is passing through its equilibrium point. Which of the graphs could serve as a graph of the vertical displacement of bead IIIas a function of time? NEXUS/Physics Clicker Questions

21. An elastic string (modeled as a series of beads) driven by a wheel driving one of the beads up and down sinusoidally. . The driving wheel has generated a traveling wave of amplitude 10 cm moving to the right. (The string continues on for a long way to the right as indicated by its going “out the window.”) The figure shows t= 0, when the green bead marked “II” is passing through its equilibrium point. Which of the graphs could serve as a graph of the vertical displacement of the elastic string at the time t = 0 as a function of position? NEXUS/Physics Clicker Questions

22. Graph A is a graph of the string's shape and graph B is a graph of the string's velocity. Is the wave on the string: • a right going traveling wave  • a left going traveling wave  • a part of a standing wave growing in amplitude at time t1 • a part of a standing wave shrinking in amplitude at time t1 • none of the above • you can’t tell from the info given. NEXUS/Physics Clicker Questions

23. Graph A is a graph of both the string's shape and the string's velocity. Is the wave on the string: • a right going traveling wave  • a left going traveling wave  • a part of a standing wave growing in amplitude at time t1 • a part of a standing wave shrinking in amplitude at time t1 • none of the above • you can’t tell from the info given. NEXUS/Physics Clicker Questions

24. Graph B is a graph of the string's shape and graph A is a graph of the string's velocity. Is the wave on the string: • a right going traveling wave  • a left going traveling wave  • a part of a standing wave growing in amplitude at time t1 • a part of a standing wave shrinking in amplitude at time t1 • none of the above • you can’t tell from the info given. NEXUS/Physics Clicker Questions

25. This is the state of the PhET wave-on-a-string simulation when the string is very long so reflection can be ignored. What is the speed of the wave (assuming that the frequency is given in cycles/min? NEXUS/Physics Clicker Questions

26. For what frequencies will we generate a large (resonant) standing wave if we drive it with a small amplitude? NEXUS/Physics Clicker Questions

27. If we start our beaded string off in a sinusoidal shape y(x) = A sin(πx/L) it will oscillate with a frequency f0.If we start it out with a shape y(x) = A sin(2πx/L)with what frequency will it oscillate? • f0 • 2f0 • f0/2 • Something else NEXUS/Physics Clicker Questions

28. If we start our beaded string off in a sinusoidal shape y(x) = A sin(πx/L) it will oscillate with a frequency f0.If we start it out with a complex shape (shown) will it ever repeat itself? If yes, with what frequency? • No • f0 • 2f0 • f0/2 • Something else NEXUS/Physics Clicker Questions

29. In the figure below is shown a picture of a string at a time t1. The pieces of the string are each moving with velocities indicated by arrows. (Vertical displacements are small and don't show up in the picture.) if the shape of the string at time t1 is that shown below (displacement magnified by X100) then the motion of the string is • Left traveling wave • Right traveling wave • A standing wave increasing in amplitude • A standing wave decreasing in amplitude • None of these. NEXUS/Physics Clicker Questions

30. In the figure below is shown a picture of a string at a time t1. The pieces of the string are each moving with velocities indicated by arrows. (Vertical displacements are small and don't show up in the picture.) if the shape of the string at time t1 is that shown below (displacement magnified by X100) then the motion of the string is • Left traveling wave • Right traveling wave • A standing wave increasing in amplitude • A standing wave decreasing in amplitude • None of these. NEXUS/Physics Clicker Questions

31. In the figure below is shown a picture of a string at a time t1. The pieces of the string are each moving with velocities indicated by arrows. (Vertical displacements are small and don't show up in the picture.) if the shape of the string at time t1 is that shown below (displacement magnified by X100) then the motion of the string is • Left traveling wave • Right traveling wave • A standing wave increasing in amplitude • A standing wave decreasing in amplitude • None of these. NEXUS/Physics Clicker Questions