a) 277.5 Hz
b) 61.6 Hz
Explanation:
a)
Stationary waves are the waves produced on a string: these are waves that do not propagate through space, since they travel only back and forth along the string.
These waves can have different frequencies, depending in how many segments of the string they vibrate.
The frequency of the fundamental mode of vibration (the one having only two nodes at the ends of the string) is called fundamental frequency, and it is given by:
[tex]f_1=\frac{1}{2L}\sqrt{\frac{T}{m/L}}[/tex]
where
L is the length of the spring
T is the tension
m is the mass of the string
For the steel piano wire in this problem:
T = 2030 N
L = 1.3 m
m = 0.003 kg
Therefore, the fundamental frequency is
[tex]f_1=\frac{1}{2(1.3)}\sqrt{\frac{2030}{(0.003)/(1.3)}}=277.5 Hz[/tex]
b)
An organ pipe is a closed-air tube, which is open at one end and close at the other end.
For a closed-open air tube, the wavelength of the fundamental mode of vibration is equal to 4 times the length of the tube:
[tex]\lambda_1 = 4 L[/tex]
In this case, the length of the tube is
L = 1.38 m
So the fundamental wavelength is
[tex]\lambda_1 = 4(1.38)=5.52 m[/tex]
The relationship between frequency and wavelength for a sound wave is
[tex]f_1=\frac{v}{\lambda_1}[/tex]
where in this case:
v = 340 m/s is the speed of sound
[tex]\lambda_1 = 5.52 m[/tex] is the fundamental wavelength
Solving for f1, we find the fundamental frequency:
[tex]f_1=\frac{340}{5.52}=61.6 Hz[/tex]
