18. Waves & Sound

Average Power of Waves on Strings

18. Waves & Sound

Average Power of Waves on Strings: Videos & Practice Problems

Topic summary

Waves on strings carry energy, not matter, as they propagate through space. To continuously produce waves, average power must be calculated using the equation: ${\frac{1}{2}}^{P} = ω^{2} A^{2} v μ$ . Here, ω is angular frequency, A is amplitude, v is wave speed, and μ is mass density. Understanding these concepts is crucial for solving wave-related problems effectively.

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Energy & Power of Waves on Strings

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Energy & Power of Waves on Strings Video Summary

In the study of waves on strings, understanding the concept of average power is crucial. Average power refers to the energy supplied over time to maintain wave motion on a string. It's important to note that waves carry energy through space, not matter; the particles of the string oscillate up and down while the wave pattern travels horizontally. To continuously produce a wave, energy must be supplied, which is quantified as power.

The formula for calculating the average power ($P_{\text{avg}}$) of waves on strings is given by:

$P_{\text{avg}} = \frac{1}{2} \omega^2 A^2 v \mu$

In this equation, $\omega$ represents the angular frequency, $A$ is the amplitude of the wave, $v$ is the wave speed, and $\mu$ is the mass density of the string. A helpful mnemonic to remember this equation is that it resembles the word "wave," with $\mu$ replacing the letter "e" and the first two variables being squared.

To find the average power, you first need to determine the angular frequency ($\omega$) and the wave speed ($v$). The angular frequency can be calculated using the formula:

$\omega = 2 \pi f$

where $f$ is the frequency of the wave. For example, if the frequency is 60 Hz, then:

$\omega = 2 \pi \times 60 \approx 377 \, \text{rad/s}$

Next, the wave speed can be calculated using the formula specific to strings:

$v = \sqrt{\frac{T}{\mu}}$

where $T$ is the tension in the string. For instance, if the tension is 100 N and the mass density is 0.05 kg/m, the wave speed would be:

$v = \sqrt{\frac{100}{0.05}} \approx 44.7 \, \text{m/s}$

Once you have $\omega$, $A$, $v$, and $\mu$, you can substitute these values into the average power equation. For example, if the amplitude is 0.06 m, the average power can be calculated as:

$P_{\text{avg}} = \frac{1}{2} (377)^2 (0.06)^2 (44.7)(0.05)$

After performing the calculations, you would find that the average power required to maintain the wave is approximately 572 watts. This value indicates the energy needed to continuously produce waves with the specified characteristics.

Problem

A horizontal string is stretched with a tension of 90 N, and the speed of transverse waves for the wire is 400 m/s. What must the amplitude of a 70.0 Hz traveling wave be for the average power carried by the wave to be 0.365 W?

2.9 mm

4.1 mm

0.2 mm

0.017 mm

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What is the equation for calculating the average power of waves on strings?

The equation for calculating the average power of waves on strings is:

$\frac{1}{2} π ω^{2} A^{2} v μ$

Here, $ω$ is the angular frequency, $A$ is the amplitude, $v$ is the wave speed, and $μ$ is the mass density of the string.

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How do you calculate the angular frequency for waves on a string?

The angular frequency $ω$ for waves on a string can be calculated using the equation:

$ω = 2 π f$

where $f$ is the frequency of the wave. This equation is derived from the relationship between the period and frequency of a wave.

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What is the significance of mass density in the average power equation for waves on strings?

Mass density $μ$ is a crucial factor in the average power equation for waves on strings. It represents the mass per unit length of the string. Higher mass density means the string is heavier, which affects the wave speed and the amount of power needed to sustain the wave. The average power equation is:

$\frac{1}{2} π ω^{2} A^{2} v μ$

where $μ$ directly influences the power required to produce the wave.

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How do you determine the wave speed on a string?

The wave speed $v$ on a string can be determined using the equation:

$v = \sqrt{\frac{T}{μ}}$

where $T$ is the tension in the string and $μ$ is the mass density of the string. This equation shows that the wave speed increases with higher tension and decreases with higher mass density.

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What is the role of amplitude in the average power of waves on strings?

The amplitude $A$ plays a significant role in the average power of waves on strings. It represents the maximum displacement of the string from its equilibrium position. In the average power equation:

$\frac{1}{2} π ω^{2} A^{2} v μ$

the amplitude is squared, indicating that even small increases in amplitude result in significant increases in the average power required to sustain the wave.

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