Two sound waves of frequencies `100Hz` and `102Hz` and having same amplitude `'A'` are interfering. At a stationary detector, which can detect resultant amplitude greater than or equal to `A`. So, in a given time interval of 12 seconds, finds the total duration in which detector is active.

Two sound waves travelling in the same direction are superposed. Their frequencies are 300 and 302 Hz and their amplitudes are 0.2 and 0.3 mm , respectively a. What is the number of beats per second ? b. What are the maximum and minimum values of resultant amplitude during the formation of beats ? c. Calculate the ratio of maximum and minimum intensities of the resultant sound.

The planes sources of sound of frequency n_(1)=400Hz,n_(2)=401Hz of equal amplitude of a each, are sounded together. A detector receives waves from the two sources simultaneously. It can detect signals of amplitude with magnitude ge a only,

A source emitting sound of frequency 180 Hz is placed in front of a wall at a distance of 2 m from it. A detector is also placed in front of the wall at the same distance from it. Find the minimum distance between the source and the detector for which the detector detects a maximum of sound. Speed of sound in air =360ms^-1 .

A whistle of frequency f_0 = 1300 Hz is dropped from a height H = 505 m above the ground. At the same time, a detector is projected upwards with velocity v = 50 ms^( -1) along the same line. If the velocity of sound is c = 300ms^(-1) find the frequency detected by the detector after t = 5s.

Two small loudspeakers A , B ( 1m apart) are connected to the same oscillator so that both emit sound waves of frequency 1700 Hz in phase . A sensitive detector , detects a maximum wave at P on the perpendicular bisector MP of AB and another maximum wave when it first reaches a point Q directly opposite to B . Calculate the speed c of the sound waves in air .

Two waves, each having a frequency of 100 Hz and a wavelength of 2.0 cm, are travelling in the same direction on a string. What is the phase difference between the waves if the second wave was produced 0.015 s later than the first one at the same place,

A source of sound is moving along a circular orbit of radius 3 meter with an angular velocity of 10 rad//s . A sound detector located far away from the source is executing linear simple harmonic motion along the line BD with an amplitude BC = CD = 6 meters . The frequency of oscillation of the detector is (5)/(pi) per second. The source is at the point A when the detector is at the point B . If the source emits a continuous sound wave of frequency 340 Hz , Find the maximum and the minimum frequencies recorded by the detector.

A diode detector is used to detect and amplitude modulated wave of 60% modulation by using a condenser of capacity 250 pF in parallel with a load resistance 100 kOmega . Find the maximum modulated frequency which could be detected by it

Two waves, each having a frequency of 100 Hz and a wavelength of 2.0 cm, are travelling in the same direction on a string. What is the phase difference between the waves (a) if the second wave was produced 0.015 s later than the first one at the same place, (b) if the two waves were produced at the same instant but the first one was produced a distance 4.0 cm behind the second one ? (c) If each of the waves has an amplitude of 2.0 mm, what would be the amplitudes of the resultant waves in part (a) and (b) ?

A sound source S, emitting a sound of frequency 400 Hz and a receiver R of mass m are at the same point. R is performing SHM with the help of a spring of force constant K. At a time t = 0, R is at the mean position and moving towards the right, as shown. At the same time, the source starts moving away from R with some acceleration a. The frequency registered by the receiver at a time t = 10 s is 250 Hz. What is the time (in seconds) at which the corresponding registered frequency of 250 Hz was emitted by the source? [Given that (m)/(K)=(25)/(pi^(2)) and amplitude of oscillation = (100)/(pi) m, V_("sound") = 320 m s^(-1)]