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. | \(72~\text{and}~30\) |
1. | \(275~\text{Hz}\) | 2. | \(175~\text{Hz}\) |
3. | \(525~\text{Hz}\) | 4. | \(575~\text{Hz}\) |
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.
When a sound wave travels from one medium to another, the quantity that remains unchanged is :
1. speed
2. amplitude
3. frequency
4. wavelength
If a sound source of frequency n approaches an observer with velocity v/4 and the observer approaches the source with velocity v/5, then the apparent frequency heard will be-
1. (5/8)n
2. (8/5)n
3. (7/5)n
4. (5/7)n
The equation of plane progressive wave motion is y=a sin 2(vt-x). Velocity of particle is
(1)
(2)
(3)
(4)
1. | \(\frac{3}{2}\) | 2. | \(\frac{5}{3}\) |
3. | \(\frac{7}{4}\) | 4. | \(\frac{7}{6}\) |