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Image formation by spherecal mirrors

Image formation by spherecal mirrors. Image Formation by Spherical Mirrors. We have studied about the image formation by plane mirrors . We also know the nature, position and relative size of the images formed by them . How about the images formed by spherical mirrors?

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Image formation by spherecal mirrors

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  1. Image formation by spherecal mirrors

  2. Image Formation by Spherical Mirrors

  3. We have studied about the image formation by plane mirrors. We also know the nature, position and relative size of the images formed by them. How about the images formed by spherical mirrors? How can we locate the image formed by a concave mirror for different positions of the object? Are the images real or virtual? Are they enlarged, diminished or have the same size? We shall explore this with an Activity.

  4. Activity We have already learnt a way of determining the focal length of a concave mirror. We have seen that the sharp bright spot of light you got on the paper is, in fact, the image of the Sun. It was a tiny, real, inverted image.We got the approximate focal length of the concave mirror by measuring the distance of the image from the mirror . „ Take a concave mirror. Find out its approximate focal length. Note down the value of focal length.„ Mark a line on a Table with a chalk. Place the concave mirror on a stand. Place the stand over the line such that its pole lies over the line. „ Draw with a chalk two more lines parallel to the previous line such that the distance between any two successive lines is equal to the focal length of the mirror. These lines will now correspond to the positions of the points P, F and C, respectively. Remember – For a spherical mirror of small aperture, the principal focus F lies mid-way between the pole P and the centre of curvature C. „

  5. Keep a bright object, say a burning candle, at a position far beyond C. Place a paper screen and move it in front of the mirror till you obtain a sharp bright image of the candle flame on it. „ Observe the image carefully. Note down its nature, position and relative size with respect to the object size. „ Repeat the activity by placing the candle – (a) just beyond C, (b) at C, (c) between F and C, (d) at F, and (e) between P and F. „ In one of the cases, you may not get the image on the screen. Identify the position of the object in such a case. Then, look for its virtual image in the mirror itself. „ Note down and tabulate your observations

  6. We will see in the above Activity that the nature, position and size of the image formed by a concave mirror depends on the position of the object in relation to points P, F and C. The image formed is real for some positions of the object. It is found to be a virtual image for a certain other position. The image is either magnified, reduced or has the same size, depending on the position of the object

  7. Representation of Images Formed by Spherical Mirrors Using Ray Diagrams

  8. To construct the ray diagrams, in order to locate the image of an object, an arbitrarily large number of rays emanating from a point could be considered. However, it is more convenient to consider only two rays, for the sake of clarity of the ray diagram. These rays are so chosen that it is easy to know their directions after reflection from the mirror. The intersection of at least two reflected rays give the position of image of the point object.

  9. i) A ray parallel to the principal axis, after reflection, will pass through the principal focus in case of a concave mirror or appear to diverge from the focus in case of a convex mirror.

  10. (ii) A ray passing through the principal focus of a concave mirror or a ray which is directed towards the principal focus of a convex mirror, after reflection, will emerge parallel to the principal axis.

  11. (iii) A ray passing through the centreof curvature of a concave mirror or directed in the direction of the centre of curvature of a convex mirror, after reflection, is reflected back along the same path.

  12. (iv) A ray incident obliquely to the principal axis, towards a point P (pole of the mirror), on the concave mirror or a convex mirror is reflected obliquely. The incident and reflected rays follow the laws of reflection at the point of incidence (point P), making equal angles with the principal axis

  13. At infinity • Real, inverted and highly diminished image is formed at focus

  14. Beyond C Real , and inverted and diminished image between focus and C

  15. At CReal, inverted, same sized image at C

  16. Between C and F Real and inverted ,Large image at beyond C

  17. At focusReal, inverted ,highly enlarged image at infinity

  18. Between P and FVirtual and erect , large image behind the mirror

  19. Uses of concave mirrors • Concave mirrors are commonly used in torches, search-lights and vehicles headlights to get powerful parallel beams of light. • They are often used as shaving mirrors to see a larger • image of the face. • The dentists use concave mirrors to see large images of the teeth of patients. • Large concave mirrors are used to concentrate sunlight to produce heat in solar furnaces.

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