. O PTICAL I NSTRUMENTS A number of optical devices and instruments have been designed utilising reflecting and refracting properties of mirrors, lenses and prisms. Periscope, kaleidoscope, binoculars, telescopes, microscopes are some FIGURE . Sunlight travels through a longer distance in the atmosphere at sunset and sunrise.
examples of optical devices and instruments that are in common use. Our eye is, of course, one of the most important optical device the nature has endowed us with. Starting with the eye, we then go on to describe the principles of working of the microscope and the telescope. .
. The eye Figure . (a) shows the eye. Light enters the eye through a curved front surface, the cornea.
It passes through the pupil which is the central hole in the iris. The size of the pupil can change under control of muscles. The light is further focussed by the eye lens on the retina. The retina is a film of nerve fibres covering the curved back surface of the eye.
The retina contains rods and cones which sense light intensity and colour, respectively, and transmit electrical signals via the optic nerve to the brain which finally processes this information. The shape (curvature) and therefore the focal length of the lens can be modified somewhat by the ciliary muscles. For example, when the muscle is relaxed, the focal length is about . cm and objects at infinity are in sharp focus on the retina.
When the object is brought closer to the eye, in order to maintain the same image-lens distance ( . cm), the focal length of the eye lens becomes shorter by the action of the ciliary muscles. This property of the eye is called accommodation . If the object is too close to the eye, the lens cannot curve enough to focus the image on to the retina, and the image is blurred.
The closest distance for which the lens can focus light on the retina is called the least distance of distinct vision , or the near point . The standard value for normal vision is taken