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

If 'O' is at equilibrium then the values of the tension T_(1) and T_2 respectively.

A small source of sound moves on a circle as shown in the figure and an observer is standing on O. Let n_1 , n_2 and n_3 be the frequencies heard when the source is at A, B and C respectively. Then

A source is approaching towoed a wall as shown in figure .We have three observes O_(1),O_(2) and O_(3). observer O_(2) is over the source itself . Let f_(1),f_(2)and f_(3) be the beat frequencires heard by O_(1),O_(2) and O_(3) between direct sound from the source and reflected sound from the wall . then

An observer moves towards a stationary source of sound with a speed 1/5 th of the speed of sound. The wavelength and frequency of the source emited are lamda and f, respectively. The apparent frequency and wavelength recorded by the observer are, respectively- (a) f,1.2 lambda (b) 0.8f,0.8lambda (c) 1.2f,1.2lambda (d) 1.2f,lambda

A small source of sound moves on a circle as shown in figure and an observer is sitting at O. Let v_1,v_2,v_3 be the frequencies heard when the source is at A,B and C respectively. .

A source of sound and a detector are placed at the same place on ground At t=0 , the source S is projected towards reflector with velocity v_0 in vertical upward directon and reflector starts moving down with constant velocity v_0 At t=0 , the vertical separation between the reflector and source is H((gtv_0^2)/(2g)) . The speed of sound in air is v(gtgtv_0) , Take f_0 as the frequency of sound waves emitted by source. Based on above information answer the following questions. Q. Frequency of sound received by detector after being reflected by reflector at t=(v_0)/(2g) is

A source of sound and a detector are placed at the same place on ground At t=0 , the source S is projected towards reflector with velocity v_0 in vertical upward directon and reflector starts moving down with constant velocity v_0 At t-0 , the vertical separation between the reflector and source is H((gtv_0^2)/(2g)) . The speed of sound in air is v(gtgtv_0) , Take f_0 as the frequency of sound waves emitted by source. Based on above information answer the following questions. Q. Wavelength of sound waves as received by detector before reflection at t=(v_0)/(2g) is

A source of sound and a detector are placed at the same place on ground At t=0 , the source S is projected towards reflector with velocity v_0 in vertical upward directon and reflector starts moving down with constant velocity v_0 At t-0 , the vertical separation between the reflector and source is H((gtv_0^2)/(2g)) . The speed of sound in air is v(gtgtv_0) , Take f_0 as the frequency of sound waves emitted by source. Based on above information answer the following questions. Q. Wavelength of sound waves as received by detector before reflection at t=(v_0)/(2g) is

A source of sound and a detector are placed at the same place on ground At t=0 , the source S is projected towards reflector with velocity v_0 in vertical upward directon and reflector starts moving down with constant velocity v_0 At t-0 , the vertical separation between the reflector and source is H((gtv_0^2)/(2g)) . The speed of sound in air is v(gtgtv_0) , Take f_0 as the frequency of sound waves emitted by source. Based on above information answer the following questions. Q. Frequency of sound waves emitted by source at t=(v_0)/(2g) is

In the figure shown, an observer O_1 floats (static) on water surface with ears in air while another observer O_2 is moving upwards with constant velocity V_1=(V)/(5) in water. The source moves down with constant velocity V_S=(V)/(5) and emits sound of freqeuncy f . The velocity of sound in air is V and that in water is 4V . For the situation shown in figure.