The accleration of a particle as seen from two frames `S_(1)` and `S_(2)` have equal magnitudes 4 `m//s^(2)`

The body moves along the x- axis . At time t=0 the velocity of particle is +0.5m//s . The acceleration of particle in different time interval is given as : a={{:(-1 m//s^(2)," ",0slt=tlt=3s),(-2 m//s^(2)," ",3s lt tlt6s),(+4m//s^(2)," ",6s lt=tlt=10s):}

At two points P and Q on a screen in Young's double slit experiment, waves from slits S_(1) and S_(2) have a path difference of O and (lambda)/(4) respectively. The ratio of intensities at P and Q will be ......

At two point P and Q on screen in Young's double slit experiment, waves from slits S_(1) and S_(2) have a path difference of 2lamda and (lamda)/(4) respectively. The ratio of intensities at P and Q will be:

Assertion :- A particle on earth found to be at rest when seen from a frame U_(1) and moving with a constant velocity when seen from another frame U_(2) . Then both frames may be non - inertial. Reason :- A reference frame attached to the earth must be an inertial frame.

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 Young's double slit experiment the slits, S_(1) & S_(2) are illuminated by a parallel beam of light of wavelength 4000 Å from the medium of refractive index n_(1)=1.2 A thin film of thickness 1.2 mum and refractive index n=1.5 is placed infrom of S_(1) perpedicular to path of light. the refractive index of medium between plane of slits & screen is n_(2)=1.4 if the light coming from the film and S_(1)&S_(2) have equal intensities I then intensity at geometrical centre of the screen O is

Consider the situation in figure. The bottom of the pot is reflecting plane mirror , S is small fish is a human eye . Refractive index of water is mu . Fish can see two images of human eye , first due to refractive only and other due to refraction and than reflection . Distance of these images from fish are S_(1) "and" S_(2) respectively . Human eye can also see the two images of fish, first due to refraction only and other due to reflection and then refraction . Distance of these images from human eye are S_(3) "and" S_(4) respectively . Match the quantities of column-I (with their value in column-(II) {:("Column I","Column II"),((A) S_(1),(p)H[1 + (1)/(2mu)]),((B)S_(2),(q) H[mu + (1)/(2)]),((C)S_(3) , (r) H[1 + (3)/(2mu)]) , ((D) S_(4) , (s) H[mu + (3)/(2)]):}

If y=5(mm) sin pi t is equation of oscillation of source S_(1) and y_(2) = 5 (mm) sin pi//6) be that of S_(2) and it takes 1 sec and ^(1//_(2 sec) for the transverse waves to reach point A from source S_(1) and S_(2) respectively then the resulting amplitude at point A , is .

When a mass m is connected individually to two springs S_(1)" and "S_(2) the oscillation frequencies are v_(1)" and "v_(2) . If the same mass is attached to the two springs as shown in figure, the oscillation frequency would be