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Visual Optics

Page 3.34. Visual Optics. Chapter 3 Retinal Image Quality. Q1. The origins of spherical aberration (SA), coma and off-axis astigmatism (OAA) respectively are: . (a) all three are longitudinal (b) SA longitudinal, coma transverse, OAA longitudinal

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Visual Optics

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  1. Page 3.34 Visual Optics Chapter 3 Retinal Image Quality

  2. Q1. The origins of spherical aberration (SA), coma and off-axis astigmatism (OAA) respectively are: (a) all three are longitudinal (b) SA longitudinal, coma transverse, OAA longitudinal (c) SA longitudinal, coma transverse, OAA transverse (d) SA transverse, coma transverse, OAA longitudinal

  3. Q2. Decentered ablation is one of the more common causes of visual problems in post-LASIK or PRK patients. One reason for the problems is: (a) Longitudinal Spherical Aberration (b) Transverse Spherical Aberration (c) Coma (d) Off-Axis Astigmatism

  4. ′S ′T Quantifying Astigmatic Error Page 3.66 For an equiconvex spherical lens, distant object (and angles of obliquity up to 25): For a near object (as in figure): +5.0 D spherical lens,  = 25 Astigmatic error varies with the square of the angle of obliquity of the chief ray (tan2) OBJ

  5. Oblique Astigmatism of the Human Eye

  6. Ocular OA Page 3.78 Figure 3.68 – The human eye has significant intrinsic oblique astigmatism for larger retinal eccentricities.

  7. Ocular OA Page 3.78 • Oblique rays travel to more peripheral retinal locations • Resolving power decreases rapidly with retinal eccentricity • Rapid increase in ocular OA with eccentricity not a problem because peripheral retina has low resolution potential • Exception: patients with central retinal disease and VA loss

  8. Curvature of Field

  9. Curvature of Field Page 3.68 • Removing SA, coma and OA: mono- point object  point image • Plane objects do not necessarily form plane images • Common example of curvature of field seen with 35 mm projector image (parts of image clear; parts blurred) Figure *.** – Curvature of field: 3D wavefront profile in the (exit) pupil plane produced by curvature of field for a plane object

  10. Origin of Curvature of Field Page 3.68 Figure 3.57 – refracting surface (devoid of spherical aberration, coma, or oblique astigmatism) with focal length, f, images parallel on-axis light rays at its second focus (F’). Oblique incident rays also refract at the curved surface and focus the same distance away.

  11. Origin of Curvature of Field Page 3.68 • Parallel incident rays focus at F′ (distance f′ from surface) • Oblique parallel incident rays also focus a distance f ′ from surface • Oblique direction of f ′ places the focal point short of the axial position of F′ (error “p”) • Resulting image surface “Petzval’s Surface”

  12. Curvature of Field & Petzval’s Surface Page 3.69 Positive meniscus lens produces a concave image of a plane object Figure 3.58 - The image of a plane object produced by an ophthalmic lens is curved. Here a positive lens produces negative (concave) image curvature for the plane object.

  13. Spherical refracting surface: Origin of Curvature of Field Page 3.68

  14. Origin of Curvature of Field Page 3.68 • Radius of curvature of Petzval’s surface varies with focal length and index of lens (or image space medium of spherical refracting surface) • This limits design options to reduce curvature of field in any optical system

  15. Eliminating Curvature of Field Page 3.68 Petzval Condition for lens system: • To produce a flat-field image with a camera lens system or microscope, the Petzval condition must be met • Anastigmatic camera lenses have zero OA and also satisfy the Petzval condition (flat image)

  16. OA and Curvature of Field in Lens Design Page 3.66 Spread of T and S foci increases exponentially with  Equiconvex lens produces maximum OA (equal positive power distribution between front and back surfaces) Equiconvex lens also produces curvature of field 1.09 D 0.25 D Figure 3.55 – oblique astigmatism produced by an equiconvex positive lens for angles of obliquity  and 2 . In dioptric terms, the “astigmatic error” is the difference in image vergence between tangential and sagittal focus. Note that the astigmatic error increases exponentially between  and 2.

  17. +4 D Hyperope: Matching Petzval’s Surface to the FPS Far Point Sphere (FPS) = surface of Far Point loci traced out as the eye rotates Page 3.65 Figure 3.59 Petzval’s surface is flatter (longer radius) than the FPS with a +4.0 D spectacle correction. “Needing” more plus in the periphery to maintain the image on the FPS, the eye becomes “undercorrected.”

  18. OA in Spectacle Lenses Page 3.69 As the eye rotates off-axis, the amount of induced off-axis astigmatism increases. This can be corrected by “Corrected Curve” Lenses. However, these lenses cannot correct both OA and curvature of field. Punktal Lenses fully correct OA but undercorrect curvature of field Figure 3.63 – Left: +4.0 D Punktal lens corrects oblique astigmatism but not curvature of field. The eye becomes undercorrected as it rotates away from the primary position. FPS = Far Point Sphere; PS = Petzval’s surface. Right: Lens Field diagram: power error versus angle of gaze. At 35 the 0.21 D undercorrection could be compensated by accommodation.

  19. Q3. The aberration, curvature of field: (a) produces no image blur (b) blurs plane objects (c) blurs point objects (d) produces transverse displacement of the image

  20. Page 3.79 Distortion

  21. Distortion Page 3.79 Strongly dependent on paraxial image height Depends on aperture position in the optical system Distortion produces NO image blur Figure 3.69 – Distortion: 3D wavefront profile in the (exit) pupil plane produced by distortion of an object.

  22. Types of Distortion Page 3.79 Object Pincushion distortion Barrel distortion Take grid-shaped object and image through a plus lens-aperture stop combination. Resulting image: No distortion With aperture AT the plus lens: Pincushion distortion With aperture to right of plus lens: Barrel distortion With aperture to left of plus lens:

  23. CR CR With aperture AT the plus lens: chief ray and nodal ray “equivalent” Page 3.80   Figure 3.71 Could correctly define lateral magnification (m = /) using either  and  measured along the optic axis, or along the nodal ray (or chief ray) path

  24. With aperture to right of plus lens: Page 3.81 Figure 3.72

  25. With aperture to left of plus lens: Page 3.82 Figure 3.73

  26. Quantifying Distortion Page 3.54 D  (h)3 • D measured relative to paraxial image point • Negative lens distortion effects opposite to plus lens • Negative lens and aperture to right: • Negative lens and aperture to left: • Systems affected: system with asymmetric stop; eye with high-power spectacle lens • Correcting/reducing distortion: orthoscopic (distortion-free) lens; aspheric spectacle lens

  27. Q4. High plus spectacle lenses in front of a patient’s eye will produce: (a) pincushion distortion (b) barrel distortion (c) no image distortion (d) transverse displacement of the image

  28. Dispersion Page 3.83

  29. Objectives Explain the wavelength-dependence of refractive index Use this information to describe prism dispersion of white light Describe and quantify chromatic aberration (LCA and TCA) Define “Abbe Number” and explain its significance Explain the principle and function of an achromatic doublet

  30. Prism Deviation: mono- Light Page 3.83 AIR GLASS Why does a prism deviate incident light toward its base?

  31. Prism Dispersion: poly- Light Page 3.85 Angle of deviation vs :

  32. Prism Deviation Page 3.83  fixed for a given prism, so what determines angle of deviation, d ?

  33. Chromatic Aberration Page 3.84 Prism Dispersion is just one example of chromatic aberration

  34. Dispersion • The angle of deviation of white light incident at a prism decreases with increasing wavelength

  35. Chromatic Aberration

  36. Chromatic Aberration

  37. n air white white Prism Dispersion “Neutralized” by a 2nd Prism Page 3.85 glass   glass

  38. n air white Prism-Dispersed Colors recombined by a + Lens Fig 3.78 Page 3.86  white glass

  39. Quantifying Dispersion Page 3.86 • Purpose of a prism is to deviate light • For most applications, a uniform deviation of all wavelengths is the ideal • Prism dispersion is therefore an unwanted by-product in most applications/instruments that require deviation of light

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