Tutorials in Introductory Physics
1st Edition
ISBN: 9780130970695
Author: Peter S. Shaffer, Lillian C. McDermott
Publisher: Addison Wesley
expand_more
expand_more
format_list_bulleted
Concept explainers
Question
Chapter 11.6, Problem 1T
To determine
The complete sketch to show the shape of the spring a short time after the trailing edge of the pulse has reached the boundary.
Expert Solution & Answer
Want to see the full answer?
Check out a sample textbook solutionStudents have asked these similar questions
Suppose that y1(x,t) and y2(x,t) are two independent wave functions, which describe the displacements vertical (in meters) of a string, as a function of position x (in meters) and time t (in seconds):
(See image)
For what values of the phase constant ϕ1 does destructive interference occur?
Compliment:
According to an article I've read on the internet, destructive interference occurs when ϕ1-ϕ2=180°
What I did was :
ϕ1+(π/3)=π
Is it wrong?
Consider the standing wave pattern shown below. A wave generated at the left end of the medium undergoes reflection at the fixed end on the right side of the medium. The number of antinodes in the diagram is _____.
Lake Erie is prone to remarkable seiches—standing waves that slosh water back and forth in the lake basin from the west end at Toledo to the east end at Buffalo. as shown smoothed data for the displacement from normal water levels along the lake at the high point of one particular seiche. 3 hours later the water was at normal levels throughout the basin; 6 hours later the water was high in Toledo and low in Buffalo.a. What is the wavelength of this standing wave?b. What is the frequency?c. What is the wave speed?
Chapter 11 Solutions
Tutorials in Introductory Physics
Ch. 11.1 - Prob. 1TCh. 11.1 - Prob. 2aTCh. 11.1 - Prob. 2bTCh. 11.1 - Prob. 2cTCh. 11.1 - The representation that we have been using...Ch. 11.1 - Prob. 2eTCh. 11.1 - Prob. 2gTCh. 11.1 - Each of the photographs at right shows a part of a...Ch. 11.1 - Obtain a piece of paper and a transparency with...Ch. 11.2 - Obtain a pan of water and form a barrier in it...
Ch. 11.2 - Prob. 2aTCh. 11.2 - Obtain an enlargement of the diagram at right that...Ch. 11.2 - Suppose that the width of one of the slits were...Ch. 11.2 - Red light from a distant point source is incident...Ch. 11.2 - Compare the situation in part II (in which a...Ch. 11.2 - For each of the lettered points, determine D (in...Ch. 11.2 - Suppose that one of the slits were covered. At...Ch. 11.2 - The pattern produced by red light passing through...Ch. 11.2 - Consider point B, the first maximum to the left of...Ch. 11.3 - Red light from a distant point source is incident...Ch. 11.3 - In a previous homework, you found an expression...Ch. 11.3 - Suppose that the screen were semicircular, as...Ch. 11.3 - Consider a point M on the distant screen where...Ch. 11.3 - Consider a point N on the screen where there is a...Ch. 11.3 - Obtain a set of transparencies of sinusoidal...Ch. 11.3 - Suppose that coherent red light were incident on a...Ch. 11.3 - Generalize your results from the 2-slit, 3-slit,...Ch. 11.3 - Coherent red light is incident on a mask with two...Ch. 11.3 - Prob. 3dTCh. 11.4 - Red light from a distant point source is incident...Ch. 11.4 - Suppose that point X marks the location of the...Ch. 11.4 - Suppose that only slit 1 is uncovered, and all...Ch. 11.4 - Show how you could group all ten slits into five...Ch. 11.4 - Suppose that the number of slits is doubled and...Ch. 11.4 - If we continued to add slits in this way (i.e.,...Ch. 11.4 - How is this pattern different from what you would...Ch. 11.4 - Consider the following dialogue: Student 1: "l...Ch. 11.4 - The photograph at right shows the diffraction...Ch. 11.4 - The photograph at right shows the diffraction...Ch. 11.4 - Describe what you would see on the screen if the...Ch. 11.4 - If a diffraction pattern has several minima (like...Ch. 11.4 - In part A, you drew a diagram that showed how find...Ch. 11.4 - Use the model that we have developed to write an...Ch. 11.5 - The minima that occur in the case of a single slit...Ch. 11.5 - Consider the following dispute between two physics...Ch. 11.5 - A second slit, identical in size to the first, is...Ch. 11.5 - Both slits are now uncovered. For what angles will...Ch. 11.5 - Suppose that the width of both slit, a, were...Ch. 11.5 - Suppose instead that the distance between the...Ch. 11.5 - The four graphs from part C that show relative...Ch. 11.5 - Consider the relative intensity graph shown at...Ch. 11.5 - Consider the following comment made by a student:...Ch. 11.5 - You may have already noticed that the maxima are...Ch. 11.6 - Prob. 1TCh. 11.6 - Prob. 2aTCh. 11.6 - When comparing two materials of different indices...Ch. 11.6 - Consider light incident on a thin soap film, as...Ch. 11.6 - Light of frequency f=7.51014Hz is incident on the...Ch. 11.6 - Suppose that an observer were located on the left...Ch. 11.6 - Observer A is looking at the part of the film that...Ch. 11.6 - Observer B is looking at the part of the film that...Ch. 11.6 - Observer C is looking at the thinnest part of the...Ch. 11.6 - Describe the appearance of the film as a whole.Ch. 11.6 - What are the three smallest film thickness for...Ch. 11.6 - The thickness of the film is 1650 nm at the bottom...Ch. 11.7 - Look at the room lights through one of the...Ch. 11.7 - Hold a second polarizing filter in front of the...Ch. 11.7 - Do the room lights produce polarized light?...Ch. 11.7 - Suppose that you had two marked polarizers (i.e.,...Ch. 11.7 - Suppose that you had a polarizer with its...Ch. 11.7 - Prob. 2dTCh. 11.7 - An observer is looking at a light source through...Ch. 11.7 - Consider a beam of unpolarized light that is...
Knowledge Booster
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.Similar questions
- Sketch the resultant wave when the two traveling wave pulses in the figure interact, specifically when point A on the left wave is at the same position as point B on the right wave. Identify areas as constructive or destructive interference.arrow_forwardTwo point sources are vibrating together (in phase) at the same frequency to produce a two-point source interference pattern. The diagram at the right depicts the two-point source interference pattern. The crests are represented by thick lines and the troughs by thin lines. Several points on the pattern are marked by a dot and labeled with a letter. Use the diagram to answer the following questions. a. Which of the labeled points are located on the second antinodal line? b. Which of the labeled points are located on the third antinodal line? c. Which of the labeled points are located on the first nodal line (using the notation that the first nodal line is the nodal line directly to the left or the right of the central antinodal line)? d. Which of the labeled points are located on the second nodal line (using the notation that the second nodal line is the second nodal line directly to the left or the right of the central antinodal line)? e. Which of the labeled points are located on the…arrow_forwardA bass guitar string is 1.5 m long. If the fundamental frequency is 220 Hz, calculate the following for the first 3 harmonics? a) Wavelengths b) Frequencies c) Wave speed Remember to include the following when answering these questions: What did you get? (your answer with the correct units and supporting work) How did you get that? (the equation you chose to use to get your answer) Why did you use that? (the concept that supports the use of the equation that you chose to use)arrow_forward
- Anna Litical ties a rope to a tree, stands 7.2 m away, and vibrates the rope up and down with 28 complete cycles in 5.0 seconds. The resulting standing wave pattern is shown in the diagram at the right. Use this information and the diagram to determine the amplitude, wavelength, frequency and speed.arrow_forwardHaving some trouble understanding this question: a and b Please see attached image Caroline, a piano tuner, suspects that a piano's D4 key is out of tune. Normally, she would play the key along with her D4 tuning fork and tune the piano to match, but her D4 tuning fork is missing. Instead, she plays the errant key along with her C4 tuning fork (which has a frequency of 261.6 Hz), displays the resulting waveform on a handheld oscilloscope, and measures a beat frequency of 50.3 Hz. Then, she plays the errant key along with her E4 tuning fork (which has a frequency of 329.6 Hz) and measures a beat frequency of 17.7 Hz. a. What frequency is being played by the out‑of‑tune key? 211.3 Hz 311.9 Hz 18.2 Hz 347.3 Hz 279.3 Hz b. If the D4 key is supposed to produce a frequency of 293.7 Hz, is the frequency of the key lower than it should be ("flat") or higher than it should be ("sharp")? flat sharparrow_forward4 QUESTON 5 SHOW ALL WORK 5) Marcelo is facilitating the class with his normal voice. Student A, siting at 6 meters from Marcelo hears his voice with an intensity of 70dB A) How much is the Power of the sound Marcelo produces? B) Student B is sitting at 10 meters from Marcelo, but the students wants also to hear the class will an intensity of 70db, therefore the student decide to bring an Amplifier. What will be the gain of the amplifier to ensure that Student B, siting at 10 meters from Marcelo will hear also the class with an intensity of 70db? C) Student C is sitting in the front row at 1 meter from Marcelo. Student C wants also to hear the class with an intensity of 70dB, and therefore Student C decide to use earplugs. How much will be the intensity of the sound the earplug need to attenuate Marcelo’s sound to allow Student C to hear the class with and intensity of 70 dB?arrow_forward
- A snapshot of two beaters oscillating in a ripple tank at the same frequency with wave amplitudes of 0.5 cm are shown in the diagram. The circles represent wave crests. Is point a,b,c constructive or destructive interference?arrow_forwardDetermine the sound density and complete a,b,c,d. Show all work (Precalculus 1)arrow_forwardAnswer the questions using the simulation above Set the frequency of wave 1 to 428 Hz and the frequency of wave 2 to 436 Hz. (a) Waves 1 and 2 are precisely in phase with one another at t = 0. If you look at the sum of the two waves, you can see that the amplitude of their sum drops to zero at one particular time between 50 and 100 ms (there are lots of places where the sum is zero, but only one place where the envelope enclosing the fast oscillations is zero, and that's the point we're interested in). Precisely when is the time, between 50 and 100 ms, when the amplitude of the sum is zero?(b) How many periods does this time correspond to for wave 1? You can get a pretty accurate idea of this by counting peaks on the wave 1 graph, but you should calculate it accurately.(c) How many periods does this time correspond to for wave 2? Note the difference between your answers for parts (b) and (c). It should be exactly half a period, which is why the waves experience completely destructive…arrow_forward
- Figure 1 shows a snapshot of a wave on a string. This wave has a frequency of 200 Hz. Approximately how long does it take the wave crest located at point A in this snapshot to move to point B?arrow_forwardTwo sound waves, which are initially in phase, travel two different distances, x1and x2toan observer/listener. Write a sentence or two about how the difference in distance, Δx,relates to the wavelength of the sound if the listenerhears maximum constructiveinterference at this location.arrow_forwardA 1.0-m-tall vertical tube is filled with 20 ∘C water. A tuning fork vibrating at 579 Hz is held just over the top of the tube as the water is slowly drained from the bottom At what water heights, measured from the bottom of the tube, will there be a standing wave in the tube above the water? Express your answer numerically. If there is more than one answer, enter your answers in descending order separated by commas.arrow_forward
arrow_back_ios
SEE MORE QUESTIONS
arrow_forward_ios
Recommended textbooks for you
- Glencoe Physics: Principles and Problems, Student...PhysicsISBN:9780078807213Author:Paul W. ZitzewitzPublisher:Glencoe/McGraw-Hill
Glencoe Physics: Principles and Problems, Student...
Physics
ISBN:9780078807213
Author:Paul W. Zitzewitz
Publisher:Glencoe/McGraw-Hill