For an open metal pipe of length L the wavelength of the first overtone is given by

For an closed metal pipe of length L the wavelength of the first overtone is given by

If the frequency of the first overtone of a closed organ pipe of length 33 cm is equal to the frequency of the first overtone of an open organ pipe, then the length of the open organ pipe will be

The third overtone of an open organ pipe of length l_(0) has the same frequency as the third overtone of a closed pipe of length l_(c) . The ratio l_(0)//l_(c) is equal to

The second overtone of an open organ pipe has the same frequency as the first overtone of a closed pipe L metre long. The length of the open pipe will be

The frequency of the third overtone of a closed pipe of length Lc is the same as the frequency of the sixth overtone of an open pipe of the length L_o. Then:

If v is the p.d. across the potentiometer of length l then potential drop per unit length of wire is given by

The fundamental frequency of a closed organ pipe of length 20 cm is equal to the second overtone of an organ pipe open at both the ends. The length of organ pipe open at both the ends is

A pipe open at both the ends has a fundamental frequency of 600 Hz . The first overtone of a pipe closed at one end has the same frequency as the first overtone of the open pipe. How long are the two pipes ?

A closed organ pipe of length L and an open organ pipe contain gass of densities rho_(1) and rho_(2) , respectively. The compressibility of gass are equal in both the pipes. Both the pipes are vibrating in their first overtone with same frequency . The length of the open orange pipe is