4. Travelling Waves and Their Characteristics A sinusoidal rope wave travels along the positive x -...
question 4-7 4. Travelling Waves and Their Characteristics A rope wave travels in the positive x -direction. You are also told that the speed of the wave is 1000 cm/s, its frequency is 200 Hz, and that the wave is subject to the following initial conditions: at x 0 and t = 0: y =-1 cm, and, at x = 0 and t : ar = +20 cm/s (this is the velocity of the point on the rope at horizontal...
1. Travelling Waves A transverse wave travels along the length of a rope. The vertical displacement of any mass element of the rope is given by the function y(x.t) - 2sin(x+t+) in units of centimeters. Answer the following: () What is the velocity of the wave itself (indicate direction of motion as well)? (ii) Find the maximum transverse acceleration of the rope.
A sinusoidal transverse wave of wavelength 19.0 cm travels along a string in the positive direction of an x axis. The displacement y of the string particle at x = 0 is given in the figure as a function of time t. The scale of the vertical axis is set by ys = 4 cm. The wave equation is to be in the form of y = ym sin(kx - ωt + φ). (a) At t = 0, is a...
2. A sinusoidal wave is traveling along a rope. The oscillator that generates the wave completes 39.0 vibrations in 29.0 s. A given crest of the wave travels 410 cm along the rope in 14.0 s. What is the wavelength of the wave? 3. When a particular wire is vibrating with a frequency of 5.00 Hz, a transverse wave of wavelength 64.0 cm is produced. Determine the speed of waves along the wire.
A sinusoidal transverse wave is travelling along a string in the negative direction of an x axis. The figure shows a plot of the displacement as a function of position at time t = 0; the y intercept is 4.0 cm. The string tension is 3.3 N, and its linear density is 44 g/m. Find the (a) amplitude, (b) wavelength, (c) wave speed, and (d) period of the wave, (e) Find the maximum transverse speed of a particle in the...
A transverse sinusoidal wave is moving along a string in the positive direction of an x axis with a speed of 87 m/s. At t=0, the string particle at x = has a transverse displacement of 4.2 cm from its equilibrium position and is not moving. The maximum transverse speed of the string particle at x = is 17 m/s. (a) What is the frequency of the wave? (b) What is the wavelength of the wave? If the wave equation...
A sinusoidal transverse wave travels along a long, stretched string. The amplitude of this wave is 0.0863 m, its frequency is 2.89 Hz, and its wavelength is 1.13 m. What is the shortest transverse distance d between a maximum and a minimum of the wave? d = m How much time At is required for 75.7 cycles of the wave to pass a stationary observer? At = S Viewing the whole wave at any instant, how many cycles N are...
t = 0 ms (a) (4 marks) A sinusoidal wave moving along a string is shown twice in the figure at time t = 0 (top) and time t = 4t (bottom). After At = 4.0 ms, the crest travels d=6.0 cm in the positive x direction. The equation for the wave is in the form 8 mm H HHHx y(x, t) =Ym sin(kx = wt). t = 4 ms What are (i) ym, (ii)k, (iii) w, and (iv) the...
A sinusoidal transverse wave travels along a long, stretched string. The amplitude of this wave is 0.0923 m, its frequency is 2.69 Hz, and its wavelength is 1.75 m. (a) What is the shortest transverse distance between a maximum and a minimum of the wave? shortest transverse distance: (b) How much time is required for 51.5 cycles of the wave to pass a stationary observer? time to pass a stationary observer: (c) Viewing the whole wave at any instant, how...
A sinusoidal transverse wave travels along a long, stretched string. The amplitude of this wave is 0.0921 m, its frequency is 3.95 Hz, and its wavelength is 1.31 m. (a) What is the shortest transverse distance between a maximum and a minimum of the wave? shortest transverse distance: (b) How much time is required for 58.5 cycles of the wave to pass a stationary observer? time to pass a stationary observer: (c) Viewing the whole wave at any instant, how...