A ball of radius `R=100cm` is located in the way of propagation of a plane sound wave. The sonic wavelength is `lambda=2cm`, the frequency is `v=100pi Hz`, the pressure oscillation amplitude in air is `(Deltap)_(m)=4Pa`. Find the mean energy flow rate (in watt), averaged over an oscillation period, reaching the surface of the ball. Take density of air `1 kg//m^(3)`.

For a person with normal hearing, the faintest sound that can be at a frequency of 400 Hz has pressure amplitude of about 6.0 xx 10^(-5) Pa . Calculate the corresponding intensity in W//m^(2) . Take speed of sound in air as 344 m//s and density of air 1.2 kg//m^(3) .

(a) what is the displacemant amplitude for a sound wave having a frequency of 100 Hz and a pressure amplitude of 10 pa? (b) The displacement amplitude of a sound wave of frequency 300 Hz is 10^(-7) m. what is the pressure amplitude of this wave ? speed of sound in airb is 340 ml s and density of a ir is 1.29kg// m^(3) .

A 3 m long organ pipe open at both ends is driven to third harmonic standing wave. If the ampulitude of pressure oscillations is 1 per cent of mean atmospheric pressure (p_(o) = 10^(5) Nm^(2)) . Find the ampulited of particle displacement and density oscillations. Speed of sound upsilon = 332 m//s and density of air rho = 1.03 kg//m^(3) .

Plane harmonic waves of frequency 500Hz are produced in air with displacement amplitude 10^(-3)cm . Deduce (i) the pressure amplitude (ii) the energy density and (iii) intensity of the wave. Speed of sound in air =300m/s. Density of air =1.29"kg/m"^3 .

A point sound is located in the perpendicular to the plane of a ring drawn through the centre O of the ring. The distance between the point O and the source is l = 1.00 m , the radius of the ring is R = 0.50 m . If the mean energy flow rate across the area encloseed by the ring is (in muW ). Find (x_(0))/(5) . Given, at point O the energy intensity of sound is equal to I_(0) = 30 muW//m^(2) and assuming the damping of the waves is negligible.

The amplitude of the sound wave emitted by a source is 10^(-3)m. If the frequency of sound is 600 Hz, what is (i) the energy per unit volume and (ii) the intensity of sound ? Speed of sound = 340 m/s, Density of air ="1.29 kg/m"^3 .

An organ pipe of (3.9 pi) m long, open at both ends is driver to third harmonic standing wave. If the amplitude of pressure oscillation is 1% of mean atmospheric pressure [p_(o) = 10^(5) N//m^(2)] . The maximum displacement of particle from mean position will be [Given, velocity of sound = 200 m//s and density of air = 1.3 kg//m^(3)]

An air bubble of radius 1 mm is located at a depth of 20 cm below water level. The excess pressure inside the bubble above the atmospheric pressure is [Given, the surface tension of water is "0.075 Nm"^(-1) and density is "1000 kg m"^(-3) ]

Plane harmonic waves of frequency 500 Hz are produced in air with displacement amplitude of 10mum . Given that density of air is 1.29(kg)/(m^3) and speed of sound in air is 340(m)/(s) . Then

A point A is located at a distance r = 1.5 m from a point source of sound of frequency 600 H_(Z) . The power of the source is 0.8 W . Speed of sound in air is 340 m//s and density of air is 1.29 kg//m^(3) . Find at the point A , (a) the pressure oscillation amplitude (Deltap)_(m) (b) the displacement oscillation amplitude A .