A small fish 0.4 m below the surface of a lake is viewed through a simple converging lens of focal length 3 m.the lens is kep at 0.2 m above the water surface such that the fish lies on the optical axis of the lens. Find the image of the fish seen by the observed. `(mu_(water)=(4)/(3))`

A small fish, 0.4m below the surface of a lake, is viewed through a simple converging lens of focal length 3m. The lens in kept at 0.2m above the water surface such that the fish lies on the optical axis of the lens. Find the image of the fish seen by the observer. The refractive index of water is 4//3 .

A small fish 0.4m below the surface of a lake, is viewed through a simple converging lens of focal length 3m . The lens is kept at 0.2m above the water surface such that the fish lies on the optical axis of the lens. Find the distance of the image of the fish from the lens as seen by the observer. The refractive index of water is 4//3 .

The focal length of a lens is -0.4m. The lens is

A convex lens of focal legnth 0.2 m and made of glass (mu = 1.50) is immersed in water (mu = 1.33) . Find the change in the focal length of the lens.

An object is placed at 0.06 m from a convex lens of focal length 0.1 m. Calculate the position of the image?

An object is kept at 0.2m from a convex lens of focal length 0.15 m. Find the position of the image produced.

A convex lens of focal length 30 cm and a concave lens of focal length 0.6m are placed in contact. Find the power of the combination.

A fish in a lake (refractive index 4//3 for water ) is viewed through a convex lens. From water surface, the lens is placed in air at half of the distance of the fish from the water surface, so that the image is formed at the fish itself. The focal length of the lens is how many times the depth of fish in water?

A stationary observer O looking at a fish F in water (mu_(w)=4//3) through a converging lens of focal length 90.0cm . The lens is allowed to fall frelly from a height 62.0cm with its axis vertical. The fish and the observer are on the principal axis of the lens. The fish moves up with constant velocity 100cm//s . Initially it was at depth of 44.0cm . Find the velocity (in cm//s) with which the fish appears to move with respect to lens to the observer at t=0.2 s . (take g=10m//s^(2))

A convergent beam of light passes through a diverging lens of focal length 0.2 m and comes to focus at a distance of 0.3 m behind the lens. Find the position of the point at which the beam would converge in the absence of the lens.