1 / 31

Lenses

Lenses. Type of lenses: Convex lens Convave lens. Refraction Rules for a Converging Lens. Any incident ray traveling parallel to the principal axis of a converging lens will refract through the lens and travel through the focus on the opposite side of the lens.

talmai
Télécharger la présentation

Lenses

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Lenses • Type of lenses: • Convex lens • Convave lens

  2. Refraction Rules for a Converging Lens • Any incident ray traveling parallel to the principal axis of a converging lens will refract through the lens and travel through the focus on the opposite side of the lens. • Any incident ray traveling through the focus on the way to the lens will refract through the lens and travel parallel to the principal axis. • An incident ray which passes through the optical centre of the lens will in effect continue in the same direction that it had when it entered the lens. http://micro.magnet.fsu.edu/primer/java/lenses/converginglenses/index.html

  3. Ray Diagrams

  4. Refraction Rules for a Diverging Lens • Any incident ray traveling parallel to the principal axis of a diverging lens will refract through the lens and travel in line with the focus (i.e., in a direction such that its extension will pass through the focus). • Any incident ray traveling towards the focus on the way to the lens will refract through the lens and travel parallel to the principal axis. • An incident ray which passes through the optical centre of the lens will in effect continue in the same direction that it had when it entered the lens. http://micro.magnet.fsu.edu/primer/java/lenses/diverginglenses/index.html

  5. Image Formation of Lenses http://www.tutorvista.com/content/physics/physics-ii/light-refraction/convex-lens-formation.php

  6. 2 1 Visual Angle http://www.microscopy.fsu.edu/primer/java/humanvision/accommodation/index.html • How large an object appears, and how much detail we can see on it, depends on the size of the image it makes on the retina. • This, in turns, depends on the angle subtended by the object at the eye.

  7. Magnifying Glass (Simple Microscope) http://www.microscopy.fsu.edu/primer/java/scienceopticsu/microscopy/simplemagnification/index.html • A magnifying glass allows us to place the object closer to our eye so that it subtends a greater angle. • The object is placed within the focus of the lens so as to produce a virtual image, which must be at least 25 cm (least distance of distinctvision or near point) from the eye.

  8. Magnifying Power of a simple microscope(Angular Magnification) • Where  is the angle subtended by the object at the near point of the eye and •  is the angle subtended by the image to the lens. • M is the ratio of the apparent sizes of the image and the object.  D

  9. Compound microscope • A microscope is used to produce an image on the retina larger than that obtainable by placing a small accessible object at the near point. • The overall magnification of a microscope is the product of the magnifications produced by the two lenses.

  10. Eyepiece Objective  D (25 cm) Compound Microscope in Normal Adjustment http://webphysics.davidson.edu/alumni/MiLee/java/Final_Optics/optics.htm • In normal adjustment an enlarged virtual image is formed at the near point, 25 cm from the normal eye.

  11. Magnifying Power of a compound Microscope • In normal adjustment, the angular magnification equals the linear magnification • Where  is the angle subtended by the object at the near point of the eye and •  is the angle subtended by the final image at the eye.

  12. Resolution of Lens • The ability of a lens to produce distinct images of two point objects very close together is called the resolution of the lens. • The closer the two images can be and still be seen as distinct, the higher the resolution. Image of pollen grain with good resolution (left) and poor resolution (right)

  13. Resolving Power of a Microscope • The resolving power of a microscope is its ability to enable detail in the image to be made out. • The resolving power depends on • The aperture of the objective • (The larger the aperture, the better the resolution.) • The wavelength of the light • (The shorter the wavelength, the better the resolution.)

  14. The Eye Ring for a Microscope • The eye ring is the optimum position for the observer’s eye to gather most light that passing through the objective. • The image is then brightest and the field of view greatest. • The eye ring is also the image of the objective formed by the eyepiece. • An observer should ideally have a pupil diameter equal to the eye ring.

  15. Optical Aberrations http://micro.magnet.fsu.edu/primer/lightandcolor/opticalaberrations.html • Chromatic Aberration • Spherical Aberration • Coma • Astigmatism • Curvature of Field • Distortion http://amazing-space.stsci.edu/resources/explorations/groundup/lesson/basics/g13/

  16. Modern Microscope Component Configuration

  17. Refracting Telescope • A telescope is used to produce an enlarged retinal image of a distant inaccessible object. • The job of a telescope • Light gathering power • Magnifying power • Resolving power

  18. Magnifying Power of a Refracting Telescope • Where  is the angle subtended at the eye by the object without the telescope, •  is the angle subtended by the final image at the eye.

  19. Refracting Telescope in Normal Adjustment • In normal adjustment the final image seen through the eyepiece is adjusted to line at infinity so that the eye is the most relaxed. • In normal adjustment, • The length of a telescope in normal adjustment = fo+fe

  20. Resolving Power of a Telescope (1) • Resolving power of a telescope is the ability to separate two closely positioned stars. • Diffraction by the objective is a factor that limits the resolving power of a telescope.

  21. Resolving Power of a Telescope (2) • The resolving power of a telescope • depends on the quality of the optical surfaces, • depends on the wavelength observed, • increases as the diameter of the objective increases. • Large lenses are difficult to make and they tend to sag under their own weight.

  22. The Eye Ring for a Telescope • In normal adjustment, it can be shown that

  23. Reflecting Astronomical Telescope • Advantages of reflecting telescope: • No chromatic aberration • A mirror can have a much larger diameter than a lens • No spherical aberration if paraboloidal mirror is used

  24. Hubble Space Telescope Eskimo nebula Eagle nebula HST’s primary mirror

  25. Terrestrial Telescope • An erecting lens is inserted between the objective and the eye piece to erect the inverted image formed by the objective. • This system has the disadvantage of increasing the length of the telescope. • An advantage is that it makes it possible to vary the magnification of the telescope.

  26. Galilean Telescope • Advantages: • The final image is erect so it is useful for terrestrial purposes. • It is shorter than the terrestrial telescope • Disadvantages: • Small field of view

  27. Spectrometer • The spectrometer is an instrument used for • Producing, viewing and taking measurements on a pure spectrum using either a prism or a diffraction grating. • Measuring accurately the refractive index of a material in the form of a prism.

  28. Construction of a spectrometer • The essential parts are • The collimator which is fixed to the base of the instrument, consisting of a slit of variable width, and an achromatic lens. • The turntable, which can be rotated, and to which a prism or grating can be attached. The circular edge of the table has a scale graduated in degrees. • The telescope, which can also be rotated. A vernier scale is fitted to the telescope where it adjoins the table, enabling their relative orientation to be measured to 0.1o, or less.

  29. Turntable Diffraction grating Collimator C θ Light source Telescope T Eyepiece Achromatic lenses Cross-wire Eye Functions of the collimator and the telescope (1) • Spectrometer used to measure wavelength of light

  30. Functions of the collimator and the telescope (2) • The collimator is set to produce a parallel beam of light from the light source near the slit. • The telescope is set to receive parallel beam of light and hence measures the angle of deviation of light through the diffraction grating or the prism.

  31. Adjustments of the spectrometer • The eyepiece is focussed on the crosswires. • The objective lens of the telescope is focussed so that the crosswires are in its focal plane. • Using a slit of width appropriate to the source brightness, the collimator lens is moved so that the slit is in its focal plane. • Using the table levelling screws, the axis of the table is made perpendicular to the plane containing the principal axes of the collimator and telescope lenses.

More Related