A cylinder full of water is placed just below a container. Water drops come out of the bottom of container at a regular interval of time and strike water surface in tank with velocity `v_(0)`. If `f_(0)` is the frequency of sound produced, then frequency of sound received by the oberver at rest, is

A tank containing water has an orifice in one vertical side. If the centre of orifice is 4.9 m below the surface level in the tank, the velocity of discharge is:

A source of sound with natural frequency f_0=1800Hz moves uniformly along a straight line separated from a stationary observer by a distance l=250m . The velocity of the source is equal to eta=0.80 fraction of the velocity of the sound. Q. Find the frequency of osund received by the observer at the moment when the source gets closest to him.

A source of sound with natural frequency f_0=1800Hz moves uniformly along a straight line separated from a stationary observer by a distance l=250m . The velocity of the source is equal to eta=0.80 fraction of the velocity of the sound. Q. Find the frequency of osund received by the observer at the moment when the source gets closest to him.

A small bulb (assumed to be a point source) is placed at the bottom of a tank containing water to a depth of 80 cm . Find out the area of the surface of water through which light from the bulb can emerge. Take the value of refractive index of water to be 4//3 .

A small bulb (assumed to be a point source) is placed at the bottom of a tank containing water to a depth of 80 cm . Find out the area of the surface of water through which light from the bulb can emerge. Take the value of refractive index of water to be 4//3 .

A source of sound of frequency 1.8kHz moves uniformly along a straight line at a distance 250m from observer. The velocity of source is 0.8C where C is the velocity of sound. Find out the frequency of sound received by observer (in kHz) at the moment when the source gets closest to him.

A sound source S and observers O_1 O_2 are placed as shown. S is always at rest and O_1,O_2 start moving with velocity V_0 at t=0 . At t=5 sec, f_1 and f_2 represent apparent frequencies of sound received by O_1 and O_2 respectively . The ratio of f_1 and f_2 is

A source of sound and detector are arranged as shown in Fig. The detector is moving along a circle with constant angular speed omega . It start from the shown location in anticlockwise direction at t=0 (Take velocity of sound in air as v) What is the frequency as received by detector, when it rotates by an angle (pi)/(2) ?

A container contains water up to a height of 20 cm and there is a point source at the centre of the bottom of the container. A rubber ring of radius r floats centrally on the water. The ceiling of the room is 2.0 m above the water surface. (a) Find the radius of the shadow of the ring formed on the ceiling if r = 15 cm. (b) Find the maximum value of r for which the shadow of the ring is formed on the ceiling. Refractive index of water =4/3.

An ultrasonic wave is sent from a ship towards the bottom of the sea. It is found that the time interval between the sending and the receiving of the wave is 1.5 s. Calculate the depth of the sea, , if the velocity of sound in sea water is 1400 ms^(-1) .