The muiscles of a normal eye are least strained when the eye is focussed on an object

The focal length of a normal eye lens is about

The focal length of a normal eye lens is about

Eye lens is

Eye lens is

For a normal eye, the least distance of distinct vision is

For a normal eye, distance of near point from the eye is.

What happens to the image distance in the normal human eye when we decrease the distance of an object, say 10 m to 1 m? Justify your answer.

The figure shows a simple arrangement which works as an astronomical telescope. The arrangement consists of two convex lenses placed coaxially. The lens which faces a distant object is called the objective. It has a large aperture and a large focal length also. The second lens is closed to the observers eyes. It is called the eyepiece. It has a smaller aperture as compared to the objective. Its focal length is also small in comparison to objective. The objective forms a real image of a distant object. This image acts as the object for the eyepiece. The eye-piece may form its image at a large distance (oo) or at least distance of distinct vision (D = 25 cm). The magnifying power of the telescope is the ratio (-beta)/(alpha) . Maximum angular magnification is produced when the final image is at the least distance of distinct vision. A telescope has an objective of focal length 50 cm and an eye-piece of focal length 5 cm. The least distance of distinct vision is 25 cm. The telescope is adjusted for distinct vision and it is focussed on an object 200 cm away. The length of the telescope is

A simple telescope, consisting of an objective of focal length 60 cm and a single eye lens of focal length 5 cm is focussed on a distant object in such a way that parallel rays comes out from the eye lens. If the object subtends an angle 2^(@) at the objective, the angular width of the image

A simple telescope consisting of an objective of focal length 60 cm and a single eye lens of focal length 5 cm is focused on a distant object in such a way that parallel rays emerge from eye lens. If the object subtends an angle of 2^(@) at the objective, the angular width of the image is (Let tan theta=theta assuming theta small).