A tube of diameter d and of length l is open a both ends. Its fundamental frequnecy of resonance is found to be `f_(1)`. One end of the tube is now closed. The lowrst frequency of resonance of this closed tube is now `f_(2)`. Taking into consideration the end correction ,`(f2)/(f_(1)` is

A tube of diameter d and of length l unit is open at both ends. Its fundamental frequency of resonance is found to be v_(1) . The velocity of sound in air is 330 m//sec . One end of tube is now closed. The lowest frequency of resonance of tube is now v_(2) . Taking into consideration the end correction, (v_(2))/(v_(1)) is

A tube of a certain diameter and of length 48cm is open at both ends. Its fundamental frequency is found to be 320 Hz . The velocity of sound in air is 320 m//sec . Estimate the diameter of the tube.

A tube of certain diameter and length 48 cm is open at both ends. Its fundamental frequency of resonance is found to be 320 Hz. The velocity of sound in air is 320 m/s. Estimate the diameter of the tube. One end of the tube is now closed. Calculate the fundamental resonance for the tube.

A tube of a certain diameter and of length 48cm is open at both ends. Its fundamental frequency is found to be 320 Hz . The velocity of sound in air is 320 m//sec . Estimate the diameter of the tube. One end of the tube is now closed. Calculate the lowest frequency of resonance for the tube.

A tube of a certain diameter and of length 48cm is open at both ends. Its fundamental frequency is found to be 320 Hz . The velocity of sound in air is 320 m//sec . Estimate the diameter of the tube. One end of the tube is now closed. Calculate the lowest frequrncy of resonance for the tube.

A tube open at both ends has fundamental frequency 'n'. If one end of the tube is dipped in water to half of its length , what would be the fundamental frequency ?

Prove that a pipe open at both end of length of 2L , has same fundamental frequency as another pipe of closed at one end of length L.

A cylindrical tube, open at both ends has a fundamental frequency f in air. This tube is dipped vertically in water so that half of it is in water. The fundamental frequency of the air column is now