Sound waves of frequency `600 H_(Z)` fall normally on perfectly reflecting wall. The distance from the wall at which the air particles have the maximum amplitude of vibration is (speed of sound in air = `330 m//s`)

Sound waves of frequency 660 Hz fall normally on a perfectly reflecting wall. The shortest distance from the wall at which the air particle has maximum amplitude of vibration is (velocity of sound in air is 330m/s)

Sound waves of frequency 660 Hz fal normally on a perfectly reflecting wall. The shortest distance from the wall at which the pair particles have maximum amplitude of vibration is ……………… meters.

Sound waves of v=60 Hz fall normally on a perfectly reflecting wall. The shortest distance from the wall at which all particles will have maximum amplitude of vibration will be (Given, speed of sound =300 ms^(-1) )

A sound wave of frequency 660 Hz incidents normally on a perfectly reflecting surface. If the speed of sound in air is 330 m s^(-1) , what is the time taken by a particle in the medium to complete one vibration? Determine the wave length of the wave.

A sound wave of frequency 660 Hz incidents normally on a perfectly reflecting object. If the speed of sound in air is 330 ms^(-1) , what is the shortest distance from the wall at which the wave particles have (a) the maximum and (b) the minimum displacement gt

A driver in a stationary car horns which produces monochromatic sound waves of frequency n=1000Hz , normally towards a reflecting wall. If the wall approaches the car will a velocity u=3.3(m)/(s) , calculate the frequency of sound reflected from wall and heard by the driver. What is the percentage change of sound frequency of reflection from the wall?

Distance travelled by the sound produced by a tuning fork of frequency 50 Hz completing 200 vibrations is, (the velocity of sound in air is 330 m/s)