If the behavior of light rays through a convex lens is as shown in the adjoining figure, then

A thin bi-convex lens made out of a material of refractive index mu_(1) is place in a medium of refractive index mu_(2) . A paraxial beam of light, parallel to the principal axis of the lens, is shown in the figure. Based on the ray diagram, we can conclude that

In the network of resistors shown in the adjoining figure, the equivalent resistance between A and B is

The total capacity of the system of capacitors shown in the adjoining figure between the points A and B is

The velocity-time diagram of a harmonic oscillator is shown in the adjoining figure. The frequency of oscillation is

The relation between n_1 and n_2 if the behaviour of light ray is as shown in the figure

A light ray hits the pole of a thin biconvex lens as shown in fig. The angle made by the emergent ray with the optic axis will be approximately

A ray of light, travelling parallel to diameter of a sphere enters the sphere through a hole at point A as shown in the figure. The inner surface of the sphere is made perfectly reflecting. Find the number of reflections suffered by the ray before coming out of the sphere.

A convex lens of focal length 1 meter and a concave lens fo focal length 0.25 meter and kept 0.75 meter apart. A parallel beam of light first passes through the ocnvex lens, then through the concave lens and comes to a focus 0.5m away from the concave lens.

A parallel beam of light falls successively on a thin convex lens of focal length 40 cm and then ono a thin convex lens of focal length 10cm as shown in figure. In figure, the second lens is an equi-concave lens of focal length 10cm and made of a material of refractive index 1.5. In both the cases, the second lens has an aperture equal to 1cm. Q. Compare the area illuminated by the beam of light on the screen, which passes through the second lens in the two cases. The ratio (A_(2)//A_(1)) will be

In refraction of light through a prism the light ray: