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Chapter 15: Problem 34

A string with a mass of \(30.0 \mathrm{~g}\) and a length of \(2.00 \mathrm{~m}\) is stretched under a tension of \(70.0 \mathrm{~N}\). How much power must be supplied to the string to generate a traveling wave that has a frequency of \(50.0 \mathrm{~Hz}\) and an amplitude of \(4.00 \mathrm{~cm} ?\)

Short Answer

Expert verified
Question: Calculate the power needed to generate a traveling wave with a frequency of 50.0 Hz and an amplitude of 4.00 cm on a string with a mass of 30.0 g, a length of 2.00 m, and a tension of 70.0 N. Answer: The power required to generate the traveling wave is approximately 50.58 W.

Step by step solution

01

Calculate the string's linear mass density

To find the wave speed, we first need to calculate the linear mass density (µ) of the string. Linear mass density is mass per unit length. The formula for linear mass density is: \(µ = \frac{mass}{length}\) Given, mass \(m = 30.0 g = 0.030 kg\) and length \(L = 2.00 m\). Now, calculate the linear mass density: \(µ = \frac{0.030 kg}{2.00 m} = 0.015 kg/m\)
02

Calculate the wave speed

The wave speed (v) can be calculated using the formula: \(v = \sqrt{\frac{Tension}{Linear~mass~density}}\) With Tension \(T = 70.0 N\), and the calculated linear mass density \(µ = 0.015 kg/m\). Now compute the wave speed: \(v = \sqrt{\frac{70.0 N}{0.015 kg/m}} = 68.41 m/s\)
03

Calculate the angular frequency and wave number

The angular frequency (ω) can be determined using the given frequency (f): \(ω = 2πf\) Given, frequency, \(f = 50.0 Hz\) Now, calculate the angular frequency: \(ω = 2π(50.0 Hz) = 100π~rad/s\) Next, calculate the wave number (k) using the wave speed (v) and angular frequency (ω): \(k = \frac{ω}{v}\) Wave number, \(k = \frac{100π~rad/s}{68.41~m/s} = \frac{50π}{34.205} rad/m\)
04

Calculate the power

Now, we can find the power (P) needed to generate the wave using the given amplitude (A), wave speed (v), and wave number (k): \(P = \frac{1}{2}µvω^2A^2\) Given amplitude, \(A = 4.00 cm = 0.0400 m\) Now, substitute the values: \(P = \frac{1}{2}(0.015 kg/m)(68.41 m/s)(100π rad/s)^2(0.0400 m)^2\) Upon calculating, we get: \(P = 50.58 W\) So, the power required to generate the traveling wave with a frequency of \(50.0 Hz\) and an amplitude of \(4.00 cm\) on the given string is approximately \(50.58 W\).

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Most popular questions from this chapter

A string with linear mass density \(\mu=0.0250 \mathrm{~kg} / \mathrm{m}\) under a tension of \(T=250 . \mathrm{N}\) is oriented in the \(x\) -direction. Two transverse waves of equal amplitude and with a phase angle of zero (at \(t=0\) ) but with different frequencies \((\omega=3000\). rad/s and \(\omega / 3=1000 . \mathrm{rad} / \mathrm{s}\) ) are created in the string by an oscillator located at \(x=0 .\) The resulting waves, which travel in the positive \(x\) -direction, are reflected at a distant point, so there is a similar pair of waves traveling in the negative \(x\) -direction. Find the values of \(x\) at which the first two nodes in the standing wave are produced by these four waves.

A steel cable consists of two sections with different cross-sectional areas, \(A_{1}\) and \(A_{2}\). A sinusoidal traveling wave is sent down this cable from the thin end of the cable. What happens to the wave on encountering the \(A_{1} / A_{2}\) boundary? How do the speed, frequency and wavelength of the wave change?

Hiking in the mountains, you shout "hey," wait \(2.00 \mathrm{~s}\) and shout again. What is the distance between the sound waves you cause? If you hear the first echo after \(5.00 \mathrm{~s}\), what is the distance between you and the point where your voice hit a mountain?

A \(3.00-\mathrm{m}\) -long string, fixed at both ends, has a mass of \(6.00 \mathrm{~g}\). If you want to set up a standing wave in this string having a frequency of \(300 . \mathrm{Hz}\) and three antinodes, what tension should you put the string under?

A traveling wave propagating on a string is described by the following equation: $$ y(x, t)=(5.00 \mathrm{~mm}) \sin \left(\left(157.08 \mathrm{~m}^{-1}\right) x-\left(314.16 \mathrm{~s}^{-1}\right) t+0.7854\right) $$ a) Determine the minimum separation, \(\Delta x_{\min }\), between two points on the string that oscillate in perfect opposition of phases (move in opposite directions at all times). b) Determine the separation, \(\Delta x_{A B}\), between two points \(A\) and \(B\) on the string, if point \(B\) oscillates with a phase difference of 0.7854 rad compared to point \(A\). c) Find the number of crests of the wave that pass through point \(A\) in a time interval \(\Delta t=10.0 \mathrm{~s}\) and the number of troughs that pass through point \(B\) in the same interval. d) At what point along its trajectory should a linear driver connected to one end of the string at \(x=0\) start its oscillation to generate this sinusoidal traveling wave on the string?
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