A 2.00 m-long rope, having a mass of 80 g, is fixed at one end and is tied to a light string at the other end. The tension in the string is 256 N. (a) Find the frequencies of the fundamental and the first two overtones. (b) Find the wavelength in the fundamental and the first two overtones.

A 1 m long rope, having a mass of 40 g , is fixed at one end and is tied to a light string at the other end. The tension in the string in 400 N . Find the wavelength in second overtone (in cm ).

A 1 m long rope, having a mass of 40 g , is fixed at one end and is tied to a light string at the other end. The tension in the string in 400 N . Find the wavelength in second overtone (in cm ).

A 160 g rope 4 m long is fixed at one end and tied to a light string of the same length at the other end. Its tension is 400 N. (a) What are the wavelength of the fundamental and the first two overtones? (b) What are the frequencies of these standing waves? [Hint : In this case, fixed end is a node and the end tied with the light string is antinode.]

If the frequency of the fundamental tone emitted from a pipe closed at one end is 200 Hz, then the frequencies of the first three overtones will be

A steel wire of mass 4.0 g and length 80 cm is fixed at the two ends. The tension in the wire is 50 N. Find the frequency and wavelength of the fourth harmonic of the fundamental.

A steel wire of mass 4.0 g and length 80 cm is fixed at the two ends. The tension in the wire is 50 N. Find the frequency and wavelength of the fourth harmonic of the fundamental.

A steel wire of mass 4.0 g and length 80 cm is fixed at the two ends. The tension in the wire is 50 N. Find the frequency and wavelength of the fourth harmonic of the fundamental.

A string of length L fixed at both ends vibrates in its first overtone. Then the wavelength will be