A source of sound and a detector are pla...

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

`(2f_0(v+v_0))/(2v-v_0)`

`(2f_0v)/(v-v_0)`

`2f_0[(v+v_0)/(2v-v_0)]xx[(v)/(v-v_0)]`

`2f_0xx(v+v_0)/(v-v_0)`

Text Solution

Verified by Experts

The correct Answer is:

As we known velocity at `t=(v_0)/(2g)` is `(v_0)/(2)`.
Number of waves reaching the reflector per second.
`f_1=(v+v_0)/(v-(v_0)/(2))f_0`
Now the wall acts as the source with above frequency and the detector is at rest. So, frequency heard by the detetor is
`f=(v)/(v-v_0)f_1=(v)/(v-v_0)xx(v+v_0)/(v-(v_0)/(2))f_0`
`=(v)/(v-v_0)xx(v+v_0)/(2v-v_0)2f_0`

Topper's Solved these Questions

SOUND WAVES AND DOPPLER EFFECT
CENGAGE PHYSICS|Exercise Integer|16 Videos
SOUND WAVES AND DOPPLER EFFECT
CENGAGE PHYSICS|Exercise Assertion-Reasoning|24 Videos
RIGID BODY DYNAMICS 2
CENGAGE PHYSICS|Exercise Interger|2 Videos
SUPERPOSITION AND STANDING WAVES
CENGAGE PHYSICS|Exercise Comprehension Type|5 Videos

Similar Questions

Explore conceptually related problems

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

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

At t = 0 source starts falling under gravity and a detector is projected upwards with a velocity 10m/s. For the vertical upward motion of detector

A wall is moving with constant velocity u towards a fixed source of sound of frequency f . The velocity of sound is v . The wavelength of the sound reflected by the wall is

A source of sound and detector are moving as shown in Fig. at t=0 . Take velocity of sound wave to be v . For this situation mark out the correct statement(s).

Speed of sound wave is v. If a reflector moves towards a stationary source emitting waves of frequency f with speed u, the wavelength of reflected waves will be

A detector is released from rest over a source of sound of frequency f_(0) = 10^(3) Hz . The frequency observed by the detector at time t is plotted in the graph. The speed of sound in air is (g = 10 m // s^(2) )

Two coherent sound sources A and B produce a sound of wavelength lambda. If at t=0 a detector starts moving with constant velocity v_(0) from point O along y - direction, then the minimum time, after which it detects the sound of maximum intensity, is (D gt gt lambda)

CENGAGE PHYSICS-SOUND WAVES AND DOPPLER EFFECT-Comprehension

In the figure shown below, a source of sound having power 12xx10^-6W i...
Text Solution
|
In the figure shown below, a source of sound having power 12xx10^-6W i...
Text Solution
|
In the figure shown below, a source of sound having power 12xx10^-6W i...
Text Solution
|
When a sound wave enters the ear, it sets the eardrum into oscillation...
Text Solution
|
When a sound wave enters the ear, it sets the eardrum into oscillation...
Text Solution
|
When a sound wave enters the ear, it sets the eardrum into oscillation...
Text Solution
|
When a sound wave enters the ear, it sets the eardrum into oscillation...
Text Solution
|
When a sound wave enters the ear, it sets the eardrum into oscillation...
Text Solution
|
A source of sound and detector are arranged as shown in Fig. The detec...
Text Solution
|
A source of sound and detector are arranged as shown in Fig. The detec...
Text Solution
|
A source of sound and detector are arranged as shown in Fig. The detec...
Text Solution
|
As shown if Fig. a vibrating tuning fork of frequency 512 Hz is moving...
Text Solution
|
As shown if Fig. a vibrating tuning fork of frequency 512 Hz is moving...
Text Solution
|
As shown if Fig. a vibrating tuning fork of frequency 512 Hz is moving...
Text Solution
|
As shown if Fig. a vibrating tuning fork of frequency 512 Hz is moving...
Text Solution
|
A source of sound with natural frequency f0=1800Hz moves uniformly alo...
Text Solution
|
A source of sound with natural frequency f0=1800Hz moves uniformly alo...
Text Solution
|
A source of sound and a detector are placed at the same place on groun...
Text Solution
|
A source of sound and a detector are placed at the same place on groun...
Text Solution
|
A source of sound and a detector are placed at the same place on groun...
Text Solution
|