In the figure shown, `mu_(1) gt mu_(2) gt mu_(3)`. What are the limits of angle i so that it is neither get total internal reflection at AB nor at CD ?

In the figure shown, find ._(1)mu_2.

In the figure shown, mu_1gtmu_2. Find minimum value of i so that TIR never takes place at P.

The refractive index of the core of an optical fibre is mu_(2) and that of the cladding is mu_(1) . The angle of incidence on the face of the core of that the light ray just under goes total internal reflection at the cladding is

A transparent cube of side d, made of a material of refractive index mu_(2) , is immersed in a liquid of refractive index mu_(1)(mu_(1)ltmu_(2)) . . A ray is incident on the face AV at an angle theta (shown in the figure). Total internal refraction takes place at point E on the face BC. Then must satisfy:

A transparent cube of side d, made of a material of refractive index mu_(2) , is immersed in a liquid of refractive index mu_(1)(mu_(1)ltmu_(2)) . . A ray is incident on the face AV at an angle theta (shown in the figure). Total internal refraction takes place at point E on the face BC. Then must satisfy:

There are three optical media 1,2 and 3 with the refractive indices mu_(1) gt mu_(2) gt mu_(3) . (TIR rarr total internal reflection)

There are three optical media 1,2 and 3 with their refractive index mu_(1) , mu_(2) and mu_(3) such that mu_(1)gtmu_(2)gtmu_(3) choose the correct options (TIR means total internal reflection)

Monochramatic light is incident on the pLane interface AB between two media of refractive indices mu_1 and mu_2(mu_2gtmu_1) at an angle of incidence theta as shown in figure. The angle theta is infinitesimally greater thannte critical angle for the two media so thast total internal reflection takes place. Now, if a transparent slab DEFG of uniform thickness and of refractive inde mu_2 is introduced on theinterface (as shown in figure ) , show that for any value of mu_2 all light will ultimately be reflected back into medium II.

A small block of mass m is projected on a larger block of mass 10 m and length l with a velocity v as shown in the figure. The coefficient of friction between the two block is mu_(2) while that between the lower block and the ground is mu_(1) . Given that mu_(2) gt 11 mu_(1) . (a) Find the minimum value of v , such that the mass m falls off the block of mass 10 m . (b) If v has minimum value, find the time taken by block m to do so.

A light ray from air is incident (as shown in figure ) at one end of a glass fiber ( refractive index mu=1.5) making an incidence angle of 60^(@) on the lateral surface, so that it undergoes a total internal reflection. How much time would it take to traverse the straight fiber of length 1 km ?