A spider and a fly are on the surface of a glass sphere. As the fly moves on the surface, find the maximum area on the glass sphere for the spider to be able to see it? Assume that the radius of the sphere (R) is much larger than the sizes of the spider and the fly. take the refractive index of glass `mu_(g)` to be equal to `sqrt(2)`.

A point object is placed at the centre of a glass sphere of radius 6cm and refractive index 1.5. The distance of virtual image from the surface is

A ray is incident on a glass sphere as shown.The opposite surface of the sphere is partially silvered .If the net deviation of the ray transmitted at the partially silvered surface is 1//3^(rd) of the net deviation suffered by the ray reflected at the partially silvered surface(after emerging out of the sphere).Find the refractive index of the sphere.

An L shaped glass tube is kept inside a bus that is moving with constant acceleration during the motion the level of the liquid in the left arm is at 12 cm whereas in the right arm it is at 8 cm when the orientation of the tube is as shown assuming that the diameter of the tube is much smaller than levels of the liquid and neglecting effect of surface tension, acceleration of the bus find the (g=10m//s^(2)) .

There is a spherical glass ball of refractive index mu_(1) and another glass ball of refractive index mu_(2) inside as shown in figure . The radius of the outer ball is R_(1) and that of inner ball is R_(2) . A ray is incident on outer surface of the ball at an angle i_(1) , Find the value of r_(2)

A hollow sphere of glass of R.I .n has small mark M on its interior surface which is observed by an observer O from a point outside the sphere, .C is centre of the sphere. The inner cavity (air) is concentric with the external surface and thickness of the glass is every where equal to the radius of the inner surface. Find the distance by which the mark will appear nearer than it really is in terms of n and R assuming paraxial rays.

There is a spherical glass ball of refractive index mu_(1) and another glass ball of refractive index mu_(2) inside as shown in figure . The radius of the outer ball is R_(1) and that of inner ball is R_(2) . A ray is incident on outer surface of the ball at an angle i_(1) , Find the value of r_(1)

There is a spherical glass ball of refractive index mu_(1) and another glass ball of refractive index mu_(2) inside as shown in figure . The radius of the outer ball is R_(1) and that of inner ball is R_(2) . A ray is incident on outer surface of the ball at an angle i_(1) , Find the value of i_(2)

A ray R_(1) is incident on the plane surface of the glass slab (kept in air) of refractive index sqrt(2) at angle of incident equal to the critical angle for this air glass system. The refracted ray R_(2) undergoes partial reflection & refraction at the other surface. The angle between the reflected ray R_(3) and the refracted ray R_(4) at that surface is :

A circle is the locus of a point in a plane such that its distance from a fixed point in the plane is constant. Anologously, a sphere is the locus of a point in space such that its distance from a fixed point in space in constant. The fixed point is called the centre and the constant distance is called the radius of the circle/sphere. In anology with the equation of the circle |z-c|=a , the equation of a sphere of radius is |r-c|=a , where c is the position vector of the centre and r is the position vector of any point on the surface of the sphere. In Cartesian system, the equation of the sphere, with centre at (-g, -f, -h) is x^2+y^2+z^2+2gx+2fy+2hz+c=0 and its radius is sqrt(f^2+g^2+h^2-c) . Q. Radius of the sphere, with (2, -3, 4) and (-5, 6, -7) as xtremities of a diameter, is