The isothermal elasticity of a medium is and the adiabatic elasticity in . The velocity of sound in the medium is proportional to
1.
2.
3.
4.
A source of sound moves away with the velocity of sound from a stationary observer. The frequency of the sound heard by the observer:
1. remains the same
2. is doubled
3. is halved
4. becomes infinity
The equation of a wave pulse travelling along x-axis is given by , x and y are in meters and t is in seconds. The amplitude of the wave pulse is
1. 5 m
2. 20 m
3. 15 m
4. 30 m
1. | \(100~\text{times}\) | 2. | \(50~\text{times}\) |
3. | \(200~\text{times}\) | 4. | \(400~\text{times}\) |
1. | \(100~\text{and}~50\) | 2. | \(44~\text{and}~22\) |
3. | \(80~\text{and}~40\) | 4. | \(72~\text{and}~30\) |
The sound intensity level at a point 10 m away from a point source is 20dB, then the sound level at a distance 1m from the same source would be
1. 40 dB
2. 30 dB
3. 200 dB
4. 100 dB
In the phenomenon of interference of sound by two coherent sources if difference of intensity at maxima to intensity at minima is 20dB, then the ratio of intensities of the two sources is
1.
2.
3.
4.
1. | \(10~\text{Hz}\) | 2. | \(20~\text{Hz}\) |
3. | \(30~\text{Hz}\) | 4. | \(40~\text{Hz}\) |
Two cars moving in opposite directions approach each other with speed of 22m/s and 16.5 m/s respectively. The driver of the first car blows a horn having a frequency 400 Hz. The frequency heard by the driver of the second car is [velocity of sound 340m/s]
1. 350Hz
2. 361Hz
3. 411Hz
4. 448Hz
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
1. L
2. 2L
3. L/2
4. 4L
A siren emitting a sound of frequency 800 Hz moves away from an observer towards a cliff at a speed of . The frequency of sound that the observer hears in the echo reflected from the cliff will be:
(Take, velocity of sound in air= )
1. 800 Hz
2. 838 Hz
3. 885 HZ
4. 765 Hz
A uniform rope of length L and mass m1 hangs vertically from a rigid support. A block of mass m2 is attached to the free end of the ropes. A transverse pulse of wavelength λ1 is produced at the lower end of the rope. The wavelength of the pulse when it reaches the top of the rope is λ2. The ratio λ2/λ1 is-
1.
2.
3.
4.
1. | \(4\) | 2. | \(5\) |
3. | \(7\) | 4. | \(6\) |
When a string is divided into three segments of lengths the fundamental frequencies of these three segments are respectively. The original fundamental frequency (v) of the string is
(1)
(2)
(3)
(4)
Two waves are represented by the equations and , where x is in metre and t in second. The phase difference between them is?
(1) 1.25 rad
(2) 1.57 rad
(3) 0.57 rad
(4) 1.0 rad