As shown in the figure, region BCDEF and ABFG are of refractive index `2.0 and 1.5` respectively. A particle O is kept at the mid of DH. Image of the object as seen by the eye is at a distance

The focal lengths of the objective and the eyepiece of a compound microscope are 1.0 cm and 5.0 cm respectively. An object, placed at a distance of 1.1 cm from the objective, has its final image formed at a distance of 25 cm from the eye. Find the magnifying power of the microscope.

A plane mirror is fixed at the bottom of a vessel as shown in the figure. Water of refractive index mu is filled up to a height h in the vessel. There is a fish at a height h//2 from bottom of vessel and there is a bird at a height h above the surface of water in the vessel. (a) Calculate apparent distance of bird as seen by the fish. (b) Calculate apparent distance of image of bird in mirror as seen by the fish. (c) Calculate apparent distance of fish as seen by the bird. (d) Calculate apparent distance of image of fish in the mirror as seen by the bird.

Figure shows figure three transparent medi of refractive indices mu_1, mu_2 and mu_3 . A point object O is placed in the medium mu_2 . If the entire medium on the right of the spherical surface has refractive index mu_1 , the image forms at O. If this entire medium has refractive index mu_2 the image form at O''. In the situation shown

The focal lengths of the objective and eye piece of a microscope are 2 cm and 5 cm respectively, and the distance between them is 20 cm . Find the distance of the object from the objective when the final image seen by the eye is 25 cm from the eye piece. What is the magnifying power ?

A compound microscope has an eyepiece of focal length 5 cm and the distance between its objective and the eye piece is 20 cm. What is the distance of the real intermediate image from the objective, if the final iamge seen by the eye is formed at the distance of distinct vision ?

A biconvex lens separates two media of refractive indices 1.3 and 1.7. the refractive index of the lens is 1.5 and the radii of curvature of the two sides of the lens are r_(1)=10cm and r_(2)=60cm . The medium of refractive index 1.3 extends to 78 cm from the lens and that of refractive index 1.7 extends of 34 cm from the lens. A luminous object O is at a distance of 144 cm from the lens. Find the position of the final image from the lens.

A glass hemisphere of radius R and of material having refractive index 1.5 is silvered on its flat face as shown in figure., A small object of height h is located at a distance 2R from the surface of hemisphere as shown in the figure. The final image will form.

Consider a concave mirror and a convex lens (refractive index 1.5) of focal length 10 cm each separated by a distance of 50 cm in air (refractive index = 1) as shown in the Fig. An object is placed at a distance of 15 cm from the mirror. Its erect image formed by this combination has magnification M_1 . When this set up is kept in a medium of refractive index 7//6 , the magnification becomes M_2 . The magnitude ((M_2)/(M_1)) is : .

There is a spherical glass shell of refractive index 1.5, inner radius 10 cm and outer radius 20 cm. Inside th espherical cavity, there is air. A point object is placed at a point O at a distance of 30cm from the outer spherical surface. Find the final position of th eimage as seen eye.