A closed organ pipe is vibrating in fundamental frequency. There are two points A and B in the organ pipe as shown, at a distance AB = L/n. Ratio of maximum pressure variation at point A to point B is `2//sqrt3` find value of n

An open organ pipe of length L vibrates in its fundamental mode. The pressure variation is maximum

A closed organ pipe and an open organ pipe are tuned to the same fundamental frequency. The ratio of their lengths is

A closed organ pipe and an open organ pipe are tuned to the same fundamental frequency. The ratio of their lengths is

A closed organ pipe of length L is vibrating in its first overtone there is a point Q inside the pipe at a distance 7L//9 form the open end the ratio of pressure amplitude at Q to the maximum pressure amplitude in the pipe is

An organ pipe A closed at one end vibrating in its fundamental frequency and another pipe B open at both ends is vibrating in its second overtone are in resonance with a given tuning fork . The ratiio of length of pipe A to that of B is

A closed organ pipe can vibrate at a minimum frequency of 500 Hz. Find the length of the tube. Speed of sound in air = 340 m s^-1 .

Two open organ pipes of fundamental frequencies n_(1) and n_(2) are joined in series. The fundamental frequency of the new pipes so obtained will be

A closed organ pipe of length 1.2 m vibrates in its first overtone mode . The pressue variation is maximum at

An organ pipe is closed at one end has fundamental frequency of 1500 Hz. The maximum number of overtones generated by this pipe which a normal person can hear is

If the fundamental frequency of a closed of pipe is equal to the first overtone of an open organ pipe then the ratio of lengths of closed organ pipe to open organ pipe is