Sounds from two identical sources `S_(1)` and `S_(2)` reach a point `P`. When the sounds reach directly, and in the same phase, the intensity at `P` is `I_(0)`. The power of `S_(1)` is now reduced by `64%` and the phase difference between `S_(1)` and `S_(2)` is varied continuously. The maximum and minimum intensities recorded at `P` are now `I_("max")` and `I_("min")`

The sum of the maximum and minimum values of the function f(x)=1/(1+(2cosx-4sinx)^2)i s

The phase difference between two SHM y_(1) = 10 sin (10 pi t + (pi)/(3)) and y_(2) = 12 sin (8 pi t + (pi)/(4)) to t = 0.5s is

Figure shows two coherent sources S_(1) and S_(2) which emit sound of wavelength lambda in phase. The separation between the sources is lambda. A circular wire of large radius is placed in such a way that S_(1)S_(2) lies in its plane and the middle point of S_(1)S_(2) is at the centre of the wire. Find the angular positions theta, on the wire for which constructive interference takes place.

When two progressive waves of intensity I_(1) and I_(2) but slightly different frequencies superpose, the resultant intensity fluctuates between :-

While conduction the Young's double slit experiment, a student replaced the two slits with a large opaque plate in the x-y plane containing two small holes that act as two coherent point sources (S_(1),S_(2)) emitting light of wavelength 600nm. The student mistakenly placed the screen parallel to the x-z plane (for zgt0) at a distance D=3 m from the mid-point of S_(1) , S_(2) , as shown schematically in the figure. The distance between the sources d=0.6003 mm . The origin O is at the intersection of the screen and the line joining S_(1)S_(2) . Which of the following is (are) true of the intensity pattern of the screen?

In the figure , the intensity of waves arriving at D from two coherent soucrces s_(1) and s_(2) is I_(0) . The wavelength of the wave is lambda = 4 m . Resultant intensity at D will be

In an interference arrangement similar to young's double slit experiment the slits S_(1) and S_(2) are illuminated with coherent microwave sources each of frequency 10^(6)Hz the sources are synchronized to have zero phase difference. the slits are separated by a distance d=150.0m. The intensity I(theta) is measured as a funtion of theta , where theta is defined as shown. if I_(0) is the maximum intensity then I(theta) for 0lethetale90^(@) is given by:

Figure shows two coherent microwave source S_(1) and S_(2) emitting waves of wavelength lamda and separated by a distance 3lamda for lamdalt lt D and yne0 . The minimum value of y for point P to be an intensity maximum is (sqrt(m)D)/(n) determine the value of m+n, if m and n are coprime numbers.

Two particle P and Q describe S.H.M. of same amplitude a same frequency f along the same straight line .The maximum distance between the two particles is asqrt(2) The phase difference between the two particle is

In figure S is a monochromatic point source emitting light of wavelength lambda=500 nm . A thin lens of circular shape and focal length 0.10 m is cut into two identical halves L_(1) and L_(2) by a plane passing through a diameter. The two halves are placed symmetrically about the central axis SO with a gap of 0.5 mm . The distance along the axis from S to L_(1) and L_(2) is 0.15 m , while that from L_(1) and L_(2) to O is 1.30 m . The screen at O is normal to SO . (a) If the 3^(rd) intensity maximum occurs at point P on screen, find distance OP . (b) If the gap between L_(1) and L_(2) is reduced from its original value of 0.5 mm , will the distance OP increases, decreases or remain the same?