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Mirrors

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If the object is between one and two focal lengths from the lens, the real image ... Laser surgery to change the 'pull' of the muscles that control the shape of the ... – PowerPoint PPT presentation

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Title: Mirrors


1
Mirrors Lenses
  • Jayne Robinson

2
20-1 The Optics of Mirrors
  • Plane Mirrors mirrors with a flat surface a
    piece of glass coated with a reflective coating
    on the front or back.
  • Virtual image an image in which no light rays
    pass through the image it appears behind the
    mirror, is upright, and appears as far behind the
    mirror as the object is in front of the mirror.

3
20-1 The Optics of Mirrors
  • Concave Mirrors curved inward like a spoon. The
    image formed by concave mirrors depends on how
    far the object is located from the mirror.
  • Optical axis - straight line through the center
    of the mirror
  • Focal point the point on the optical axis
    through which all reflected light rays pass.
  • Focal length distance from the center of the
    mirror to the focal point.

4
20-1 The Optics of Mirrors
  • Concave Mirror Images
  • Real image an image formed where the light rays
    meet and it can be projected onto a screen forms
    when the object is located farther than the focal
    point from a concave mirror it is also enlarged
    and inverted (upside down).
  • An object placed at the focal point reflects no
    image b/c the light rays do not converge (meet)
    exgt car headlights, flashlights, and spotlights
    use these mirrors.

5
20-1 The Optics of Mirrors
  • Concave Mirror Images
  • Virtual image appears behind the mirror, is
    upright and enlarged formed when the object is
    between the focal point and the mirror. Make-up
    mirrors use this type of mirror.

6
20-1 The Optics of Mirrors
  • Convex Mirrors curve outward
  • The reflected rays never meet so the image is
    always virtual, upright, and smaller than the
    actual object.
  • Used in stores and factories to see large areas,
    and used for rear-view or side-view mirrors on
    autos to see a wide view of traffic. However,
    objects are always closer than they appear.

7
20-2 The Optics of Lenses
  • Convex Lenses thicker in the middle than at the
    edges.
  • Light rays are refracted toward the center of the
    lens and converge at the focal point they are
    capable of forming real images that can be
    projected on a screen.
  • The amount of refraction depends on the change in
    the speed of light as it passes through the
    material and the shape of the object.
  • Thick lenses with very curved surfaces bend light
    more than ones with less curved surfaces.
  • The focal length of thick lenses is shorter than
    those of thin lenses.

8
20-2 The Optics of Lenses
  • Cameras and the human eye lens view objects that
    are more than two focal lengths away so the real
    image is smaller and inverted. (The brain
    converts the image to upright.)
  • If the object is between one and two focal
    lengths from the lens, the real image is inverted
    and larger than the object. This is the method
    used by movie projectors and overhead projectors.

9
20-2 The Optics of Lenses
  • Concave Lenses thinner in the middle than at
    the edges.
  • Light rays diverge and never form a real image.
    The image is virtual, upright, and smaller than
    the object.
  • Concave lenses are usually used in combination
    with other lenses.
  • They are used with convex lenses in telescopes
    and cameras to spread out incoming light and
    extend the focal length to see far-away
    objects.
  • The are also used to correct nearsighted vision.

10
20-3 Lenses Vision
  • Light enters your eye through the cornea
    (transparent covering), then passes through the
    pupil (opening). The iris (colored part) adjusts
    the pupil size to control how much light reaches
    the lens. The light converges to form an
    inverted image on the retina.

11
20-3 Lenses Vision
  • The lens in the eye is soft, and flexible muscles
    in the eye can change its shape.
  • When you look at a distant object, you need a
    longer focal length, so your eye muscles adjust
    the lens to a less convex shape.
  • When you focus on a near object, the eye muscles
    increase the curvature of the lens to shorten the
    focal length.

12
20-3 Lenses Vision
  • Nearsighted has difficulty seeing distant
    objects b/c the eyeball is too long or the
    corneas are too flat to allow the rays to
    converge on the retina. Concave lenses correct
    this problem by diverging the light rays before
    they enter the eye. (Fig 20-10 p. 520)

13
20-3 Lenses Vision
  • Farsighted - cant focus clearly on nearby
    objects b/c the eyeball is too short or corneas
    are too flat to allow the rays to converge on the
    retina. The image is focused behind the retina.
    Convex lenses converge the image at the retina.

14
20-3 Lenses Vision
  • Astigmatism causes blurry vision b/c the
    surface of the cornea is curved unevenly. These
    corrective lenses have an uneven curvature so as
    to smooth out the curves.

15
20-3 Lenses Vision
  • Methods to correct vision currently include
  • Eye glasses
  • Contact lenses worn on the cornea.
  • Laser surgery to change the pull of the muscles
    that control the shape of the eyeball itself,
    making it less elongated or more elongated.

16
20- 4 Optical Instruments
  • Telescopes devices designed to magnify objects
    far away.
  • Early telescopes were made of mirrors and lenses.
  • Around 1600, lensmakers in Holland constructed a
    telescope.
  • In 1609, Galileo built and used his own telescope
    to discover the moons of Jupiter, the phases of
    Venus, and some details of the Milky Way.

17
20- 4 Optical Instruments
  • Refracting telescopes use two convex lenses to
    gather and focus light from distant objects.
  • The objective lens is the larger lens that allows
    light to enter and form a real image of the
    object.
  • The eyepiece is a smaller lens that forms an
    enlarged, virtual image of the real image, but
    the image is inverted.
  • Refracting telescopes must have a very large,
    very heavy lens to see faraway stars planets.

18
20- 4 Optical Instruments
  • Reflecting telescopes use a concave mirror, a
    plane mirror and a convex lens to magnify distant
    objects.
  • Light enter the telescopes and is reflected by
    the concave mirror to a plane mirror.
  • The plane mirror reflects the rays to form an
    inverted real image in the telescope.
  • The convex lens (eyepiece) magnifies the image.
    This lens can be replaced by a camera to
    photograph the image.

19
20- 4 Optical Instruments
  • Binoculars and terrestrial telescopes (used for
    bird-watching) use a third lens or reflecting
    prism to invert the upside down image so it
    appears upright.
  • Microscopes use two convex lenses with short
    focal lengths to magnify very small, close
    objects.
  • Light enters through the objective lens and forms
    a real, enlarged image.
  • This image is magnified again to create a
    virtual, enlarged image.
  • The image is upside down and backwards.
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