The concept needed to solve this problem is average power dissipated by a wave on a string. This expression ca be defined as
[tex]P = \frac{1}{2} \mu \omega^2 A^2 v[/tex]
Here,
[tex]\mu[/tex] = Linear mass density of the string
[tex]\omega =[/tex] Angular frequency of the wave on the string
A = Amplitude of the wave
v = Speed of the wave
At the same time each of this terms have its own definition, i.e,
[tex]v = \sqrt{\frac{T}{\mu}} \rightarrow[/tex] Here T is the Period
For the linear mass density we have that
[tex]\mu = \frac{m}{l}[/tex]
And the angular frequency can be written as
[tex]\omega = 2\pi f[/tex]
Replacing this terms and the first equation we have that
[tex]P = \frac{1}{2} (\frac{m}{l})(2\pi f)^2 A^2(\sqrt{\frac{T}{\mu}})[/tex]
[tex]P = \frac{1}{2} (\frac{m}{l})(2\pi f)^2 A^2 (\sqrt{\frac{T}{m/l}})[/tex]
[tex]P = 2\pi^2 f^2A^2(\sqrt{T(m/l)})[/tex]
PART A ) Replacing our values here we have that
[tex]P = 2\pi^2 (105)^2(1.8*10^{-3})^2(\sqrt{(29.0)(2.95*10^{-3}/0.79)})[/tex]
[tex]P = 0.2320W[/tex]
PART B) The new amplitude A' that is half ot the wavelength of the wave is
[tex]A' = \frac{1.8*10^{-3}}{2}[/tex]
[tex]A' = 0.9*10^{-3}[/tex]
Replacing at the equation of power we have that
[tex]P = 2\pi^2 (105)^2(0.9*10^{-3})^2(\sqrt{(29.0)(2.95*10^{-3}/0.79)})[/tex]
[tex]P = 0.058W[/tex]
