In image formatiion from spherical mirrors, only paraxial rays are considered because they

Statement-1 The formula connecting u,v and f for a spherical mirror is valid only for mirrors whose sizes are very small compared to their radii of curvature. Statement-2 Laws of reflection are strictly valid for plane surfaces, but nor for large spherical surfaces.

Assertion:- The formula ((1)/(v)+(1)/(u)=(1)/(f)) connecting u and v for a spherical mirror is valid only for mirros whose sizes are very small compared to their radii of curvatures. Reason:- Laws of reflection are strictly valid for smaller size of of optical system.

Assertion:- Images formed by TIR (Total internal reflection) are much brighter than formed by mirrors or lenses. Reason:- IN TIR, there is no loss of intensity while in case of reflection from mirrors or refraction from plane surfaces or lenses there is some loss of intensity as all light can never be reflected or refracted.

The distance of an object from a spherical mirror is equal to the focal length of the mirror. Then the image:

Radius of curvature of each mirror is R. 'O' is object. Consider first reflection from concave mirror. Consider only first three reflection. The distance of final image from convex mirror is

If f is focal length and v is image distance for spherical mirror, then beteral magnification m = …....

If real image obtained from concave mirror of focal length f is n times of object, then find object distance.

If image obtained from concave mirror of focal length f is (1/n)^(th) times of object, then find object distance.

3% of energy of 100 W bulb is converted into visible light. Find the average intensity on a spherical surface 1 m away from the bulb consider the bulb is point source and medium is isotropic.

How is it convenient to obtain image by reflection from spherical mirror ?