1 / 27

OPTICS

OPTICS. 1. LIGHT REFLECTION. Light reflection law light comes ( i ), normal line and reflected ray (r) lays in one flat incidence angle equal to angle of reflection ( i = r). M irror flat mirror S hadow character: illusion, upright of equal size. Shadow total Notes: n = shadow total

duke
Télécharger la présentation

OPTICS

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. OPTICS

  2. 1. LIGHT REFLECTION • Light reflection law • light comes (i), normal line and reflected ray (r) lays in one flat • incidence angle equal to angle of reflection (i = r)

  3. Mirror • flat mirror • Shadow character: illusion, upright of equal size.

  4. Shadow total Notes: n = shadow total  = corner between two mirrors

  5. Curve mirror spheris Concave mirror : Convex mirror :

  6. Rules : • No. R thing + no. R shadow = 5 • No. thing < no. R shadow  enlarged • Shadow in front of mirror  real upside down • Shadow rear mirror  upright illusion

  7. Notes: R = mirror radius (cm) f = focus distance (cm) S = object distance (cm) S’= shadow distance (cm) h = object height (cm) h’= tall shadow (cm) M = shadow magnification • Notes: • R = 2f • concave mirror f & R (+) • convex mirror f & R (–)

  8. 2. LIGHT REFRACTION • Light Laws of Refraction • light comes, normal line and refracted ray lays in one flat. • incidence angle sine comparison (i) and angle of refraction sine (r) always permanent.

  9. In operative light refraction : n1 sin i = n2 sin r n1 V1 = n2 V2 n1 . 1 = n2 . 2 f1 = f2 Notes: n1, n2 = refraction profitabiliti medium 1 and 2 v1, v2 = fast spread light in medium 1 and 2 f1, f2 = light frequency in medium 1 and 2 i = come corner r = angle of refraction

  10. B. Refraction in lens • Thick lens Notes: n1, n2 = refraction profitabiliti medium 1 and 2 s = thing location (cm) s’ = shadow location (cm) R = curvature radius (cm) M = shadow magnification

  11. In operative thin lens : Notes: f = focus distance (cm) S = object distance (cm) S’ = shadow distance (cm) h = object height (cm) h’ = tall shadow (cm) M = shadow magnification • Thin lens

  12. Thin lens there 2 kinds : • convex lens (positive lens) • concave lens (negative lens) Rules in thin lens: No. R thing + no. R bay = 5 No. R thing < no. R  enlarged Shadow in front of lens  upright illusion

  13. Lens shaper similarity: Strong lens : Notes: f = focus of lens distance (cm) n2 = indeks lens refraction n1 = indeks environment refraction R = curvature radius (cm) P = strong lens (dioptri=D)

  14. Notes: fgab = federation focus of lens distance (cm) f1,2,3 = focus of lens distance 1, 2, 3 (cm) Pgab = strong federation lens (dioptri=D) P1,2,3 = strong lens 1, 2, 3 (dioptri=D) In similarity operative federation lens:

  15. Light refraction in prism • Angle of deviation :  = i1 + r2 -  • = r1 + i2 • Deviation minimum : i1 = r2dan r1 = i2 very little ( < 150) m = (n2/n1 – 1)  • Light dispersi •  = u - m • = (nu – nm).prism on the air, deviation minimum and  little

  16. 3. INTERFERENSI LIGHT Interferensidouble gap(Young) (bright pattern) d sin  (k – ½ ) (dark pattern) Jika <<, maka: k(bright pattern) dp/l = (k – ½ )(dark pattern) Keterangan:  = angle of deviation d = distance 2 gaps P = distance 2 patterns in sail l = gap distance to sail  = monochromatic light wavelength that is used

  17. Interferensicincin Newton • k(dark pattern) • rk2/R = • (k – ½ ) (bright pattern) • Notes: • r = dark/bright ring radius • R = lens curvature radius • k = 1, 2, 3, … •  = light wavelength that dropped in lens B. Interferensiin thin layer k(pattern min) 2 ndcos r= (k – ½)(pattern max) Notes: n = layer refractive index d = thick layer r = angle of refraction k = 1, 2, 3, …  = wavelength hits layer

  18. 4. INTERFERENSI CAHAYA Difraksicelahtunggal k(dark pattern) d sin  (k + ½) (bright pattern) Notes: k = 1, 2, 3, … d = wide gap  = angle of deviation  = light wavelength

  19. Diffraction multi gap (grid diffraction) k(bright pattern) d sin  (k - ½)(dark pattern) if q <<, so d sin q = dp/l p = pattern distance at sail l = gap distance to sail Notes: d = grid constant = distance 2 gaps serially k = 1, 2, 3,…. If  <<, so d sin  = dp/l p = pattern distance at sail l= gap distance to sail

  20. 5. LIGHT POLARIZATION Polarization because reflection Light bounces back polarization, if refracted ray vertical reflected ray. tgip = n2/n1 n2 > n1 ip = polarization corner = Brewster corner

  21. Polarization because selective absorption • P = polarisator • A = analisator • Electricity field sustained analisator: • E = E0cos • Intensity sustained: • I = I0 cos2 • = corner between axis • polarisator and • analisator

  22. 6. OPTICS TOOLS A. Eye • Thing visible clear if shadow falls in retina • Shadow character: real, upside down, decried • Normal eye : Sn = pp = 25 cm PR = ~ B. Glasses • To help eye defect sufferer sight.

  23. Eye defect kind: 1. Miop (far nearsighted) • less clear see far • helped negative lens 2. Hipermetrop (nearsighted near) • less clear see near • helped positive lens 3. Presbiop (old eye) • less clear see far/near • weak accomodations power the cause • helped lens bifokal

  24. Lup (authority glass) Shadow character: illusion, upright, enlarged. Magnification anguler: Keterangan: Sn = normal distance f = focus distance lup x = eye distance to shadow d = eye distance to lup without accomodations x = PR normal eye: PR = ~ M = Sn/f maximum accomodations x = Sn Normal eye, d = 0  M = Sn/f + 1

  25. D. Microscope Microscope formulas : 1/fob = 1/Sob + 1/S’ob 1/fok = 1/Sok + 1/S’ok d = S’ob + Sok d = long microscope tube Microscope magnification: M = Mob . Mok Mob = S’ob/Sob Mok = Sn/fok + 1 maximum accomodations Mok = Sn/fokwithout accomodations

  26. Binoculars Long binoculars : d = fob + fok relax d = fob + Sokaccomodations in distance x maximum accomodations : S’ok = - Sn Magnification anguler : M = fob/fok relax M = fob/Sokaccomodations in distance x For tube long earth binoculars augmentings 4 fp, (fp = commutator focus of lens distance)

  27. Resolution corner minimum : m = 1,22 . /D dm = 1,22 . Notes: m = resolution corner minimum  = light wavelength (m) d = optics tool aperture (m) dm = power decomposes optics tool (m) l = object distance to optics tool (m) F. Power decomposes optics tool

More Related