A detector at `x=0` receives waves from three sources each of amplitude `A` and frequencies `f + 2,f` and `f-2`.
If `I_(0) prop A^(2)`, then the value of maximum intensity,is

A detector at x=0 receives waves from three sources each of amplitude A and frequencies f + 2,f and f-2 . The time at which intensity is maximum, is

A detector at x=0 receives waves from three sources each of amplitude A and frequencies f + 2,f and f-2 . The equation of waves are : y_(1)=A sin[2 pi(f+2),y_(2)=A sin 2 pift and y_(3)=A sin[2pi (f-2)t] . The time at which intensity is minimum is

f(x)= x^(2)-3x + 4 If f(x)= f(2x+1) find the value of x .

f(x)= 2x^(n) + a . If f(2)= 26 and f(4)= 138 then the value of f(3) is……..

Two radio stations broadcast their programmes at the same amplitude A and at slightly different frequencies omega_(1) and omega_(2) respectively, where omega_(1) - omega_(2) = 10^(3) Hz . A detector receives the signals from the two stations simultaneously, it can only detect signals of intensity ge 2A^(2) . (i) Find the time interval between successive maxima of the intensity of the signal received by the detector. (ii) Find the time for which the detector remains idle in each cycle of the intensity of the signal.

Verify mean value theorem for each of the functions: f(x)= sin x- sin (2x), "in " x in [0, pi]

A detector is released from rest over height h a source of sound of frequency f_(0) = 10^(3) Hz . The frequency observed by the detector at time t is plotted in the graph. The speed of sound in air is (g = 10 m//s^(2))

Verify mean value theorem for each of the functions: f(x)= x^(3)-2x^(2)-x + 3, x in [0, 1]

Let f(x) be a differentiable function in the interval (0, 2) then the value of int_(0)^(2)f(x)dx

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.