1. ECEG105 & ECEU646 Optics for Engineers Course Notes Part 4: Apertures, Aberrations
Prof. Charles A. DiMarzio
Northeastern University
Fall 2003
July 2003
Chuck DiMarzio, Northeastern University

2. Advanced Geometric Optics
Introduction
Stops, Pupils, and Windows
f-Number
Examples
Magnifier
Microscope
Aberrations
Design Process
From Concept through Ray Tracing
Finalizing the Design
Fabrication and Alignment
July 2003
Chuck DiMarzio, Northeastern University

3. Some Assumptions We Made
All lenses are infinite in diameter
Every ray from every part of the object reaches the image
Angles are Small:
sin(q)=tan(q)=q
cos(q)=1
July 2003
Chuck DiMarzio, Northeastern University

4. Chuck DiMarzio, Northeastern University
What We Have Developed
Description of an Optical System in terms of Principal Planes, Focal Length, and Indices of Refraction
These equations describe a mapping
from image space (x,y,z)
to object space (x’,y’,z’)
s, s’ are z coordinates H H’ V V’ B B’
July 2003
Chuck DiMarzio, Northeastern University

5. Lens Equation as Mapping
The mapping can be applied to all ranges of z. (not just on the appropriate side of the lens)
We can consider the whole system or any part.
The object can be another lens L1 L2 L3 L4
L4’
July 2003
Chuck DiMarzio, Northeastern University

6. Stops, Pupils, and Windows (1)
Intuitive Description
Pupil Limits Amount of Light Collected
Window Limits What Can Be Seen
Window
Pupil
July 2003
Chuck DiMarzio, Northeastern University

7. Stops, Pupils and Windows (2)
Physical Components
Images in Object Space
Images in Image Space
Aperture Stop
Limits Cone of Rays from Object which Can Pass Through the System
Entrance Pupil Limits Cone of Rays from Object
Exit Pupil Limits Cone of Rays from Image
Entrance Window Limits Cone of Rays From Entrance Pupil
Field Stop
Limits Locations of Points in Object which Can Pass Through System
Exit Window Limits Cone of Rays From Exit Pupil
July 2003
Chuck DiMarzio, Northeastern University

8. Finding the Entrance Pupil
Find all apertures in object space
Entrance Pupil Subtends Smallest Angle from Object
L4’ is L4 seen through L1-L3 L1 L2 L3 L4 L1
L2’
L3’
L4’
L3’ is L3 seen through L1-L2
July 2003
Chuck DiMarzio, Northeastern University

9. Finding the Entrance Window
Entrance Window Subtends Smallest Angle from Entrance Pupil
Aperture Stop is the physical object conjugate to the entrance pupil
Field Stop is the physical object conjugate to the entrance window
All other apertures are irrelevant L1
L2’
L3’
L4’
July 2003
Chuck DiMarzio, Northeastern University

10. Chuck DiMarzio, Northeastern University
Field of View
f=28 mm
f=55 mm
Film=
Exit
Window
f=200 mm
July 2003
Chuck DiMarzio, Northeastern University

11. Example: The Telescope
Aperture
Stop
Field
Stop
July 2003
Chuck DiMarzio, Northeastern University

12. The Telescope in Object Space
Secondary’
Primary
Secondary
Entrance
Pupil
Entrance
Window
July 2003
Chuck DiMarzio, Northeastern University

13. The Telescope in Image Space
Primary
Primary’’
Secondary
Exit
Pupil
Exit
Window
July 2003
Chuck DiMarzio, Northeastern University
Stopped 26 Sep 03

14. Chuck DiMarzio, Northeastern University
Chief Ray
Aperture
Stop
Exit
Pupil
Field
Stop
Chief Ray passes through the center of every pupil
July 2003
Chuck DiMarzio, Northeastern University

15. Hints on Designing A Scanner
Place the mirrors at pupils
Put Mirrors Here
July 2003
Chuck DiMarzio, Northeastern University

16. f-Number & Numerical Apertureq F’ A’ A F
D is Lens Diameter 5 4 3
f#, f-number 2 1
0.2
0.4
0.6
0.8 1
NA, Numerical Aperture
July 2003
Chuck DiMarzio, Northeastern University

17. Importance of Aperture
``Fast’’ System
Low f-number, High NA (NA1, f# 1)
Good Light Collection (can use short exposure)
Small Diffraction Limit (l/D)
Propensity for Aberrations (sin q  q)
Corrections may require multiple elements
Big Diameter 
Big Thickness  Weight, Cost
Tight Tolerance over Large Area
July 2003
Chuck DiMarzio, Northeastern University

18. Chuck DiMarzio, Northeastern University
The Simple Magnifier F F’ A’ A
July 2003
Chuck DiMarzio, Northeastern University

19. The Simple Magnifier (2)
Image Size on Retina Determined by x’/s’
No Reason to go beyond s’ = 250 mm
Magnification Defined as
No Reason to go beyond D=10 mm
f# 1 Means f=10 mm
Maximum Mm=25
For the Interested Student: What if s>f ?
July 2003
Chuck DiMarzio, Northeastern University

20. Chuck DiMarzio, Northeastern University
Microscope F’ F’ F F A’ A
Two-Step Magnification
Objective Makes a Real Image
Eyepiece Used as a Simple Magnifier
July 2003
Chuck DiMarzio, Northeastern University

21. Chuck DiMarzio, Northeastern University
Microscope Objective F’ F’ F F A’ A
July 2003
Chuck DiMarzio, Northeastern University

22. Chuck DiMarzio, Northeastern University
Microscope Eyepiece F’ F’ F F A2 A
A2’
July 2003
Chuck DiMarzio, Northeastern University

23. Microscope Effective LensH H’
192 mm
Barrel Length = 160 mm A
f2=16mm F
f1=16mm F’
Effective Lens:
f = -1.6 mm D D’
19.2 mm
19.2 mm H H’ A F’ F
July 2003
Chuck DiMarzio, Northeastern University

24. Microscope Aperture Stop
Analysis in Image Space F’ F
Exit
Pupil
Image
Aperture
Stop
=Entrance
Pupil
Put the Entrance Pupil of your eye
at the Exit Pupil of the System, Not at the Eyepiece, because
1) It tickles (and more if it’s a rifle scope)
2) The Pupil begins to act like a window
July 2003
Chuck DiMarzio, Northeastern University
Stopped here 30 Sep 03

25. Chuck DiMarzio, Northeastern University
Microscope Field Stop F’ F
Entrance
Window
Field Stop
= Exit Window
July 2003
Chuck DiMarzio, Northeastern University

26. Microscope Effective Lens
July 2003
Chuck DiMarzio, Northeastern University

27. Chuck DiMarzio, Northeastern University
Aberrations
Failure of Paraxial Optics Assumptions
Ray Optics Based On sin(q)=tan(q)=q
Spherical Waves f=f0+2px2/rl
Next Level of Complexity
Ray Approach: sin(q)=q+q3/3!
Wave Approach: f=f0+2px2/rl+cr4+...
A Further Level of Complexity
Ray Tracing
July 2003
Chuck DiMarzio, Northeastern University

28. Examples of Aberrations (1)
Paraxial Imaging
0.5
R = 2,
n=1.00, n’=1.50
s=10, s’=10
In this example for a ray having height h at the surface, s’(h)<s’(0).
-0.5
m4061_3 -1
-10 -5 5 10
July 2003
Chuck DiMarzio, Northeastern University

29. Example of Aberrations (2)
0.2
D z(h=1.0)
Longitudinal
Aberration = D z
Transverse Aberration =D x
0.15
D z(h=0.6)
0.1
0.05
-0.05
Where Exactly is the image?
What is its diameter?
-0.1
-0.15
2D x(h=1.0)
m4061_3
-0.2
8.5 9
9.5 10
10.5
July 2003
Chuck DiMarzio, Northeastern University

30. Spherical Aberration Thin Lens in Air
July 2003
Chuck DiMarzio, Northeastern University

31. Transverse Spherical AberrationDs h Dx
s(0)
July 2003
Chuck DiMarzio, Northeastern University

32. Evaluating Transverse SA
July 2003
Chuck DiMarzio, Northeastern University

33. Coddington Shape Factors+1 -1
p=0 -1
q=0 +1
July 2003
Chuck DiMarzio, Northeastern University

34. Chuck DiMarzio, Northeastern University
Numerical Examples
Beam Size, m -2 5 10
s=1m, s’=4cm -3 10
n=2.4
n=1.5
n=1.5
n=4 10 -4
q, Shape Factor
DL at 10 mm
n=2.4 10 -5
DL at 1.06 mm
n=4
500 nm 1 -5 -6 10 -1
-0.5
0.5 -5 5
p, Position Factor
q, Shape Factor
July 2003
Chuck DiMarzio, Northeastern University

35. Phase Description of Aberrationsv y
Image z
Object
Entrance
Pupil
Exit
Pupil
Mapping from object space to image space
Phase changes introduced in pupil plane
Different in different parts of plane
Can change mapping or blur images
July 2003
Chuck DiMarzio, Northeastern University

36. Coordinates for Phase Analysisv v y
Solid Line is phase of a spherical wave toward the image point.
Dotted line is actual phase.
Our goal is to find
D(r,f,h). D z
phase v y 2a ra u h
0<r<1 x
July 2003
Chuck DiMarzio, Northeastern University

37. Chuck DiMarzio, Northeastern University
Aberration Terms
Odd Terms involve tilt,
not considered here.
July 2003
Chuck DiMarzio, Northeastern University

38. Chuck DiMarzio, Northeastern University
Second Order
Image Position Terms:
The spherical wave is approximated by a second-order phase term, so this error is simply a change in focal length.
July 2003
Chuck DiMarzio, Northeastern University

39. Chuck DiMarzio, Northeastern University
Fourth Order (1)
r2 is focus: depends on h2 and h2cosf
Spherical Aberration
Astigmatism and Field Curvature S
Sagittal
Plane
Tangential
Plane T
Sample Images
At T
At S
July 2003
Chuck DiMarzio, Northeastern University

40. Chuck DiMarzio, Northeastern University
Fourth Order (2)
r2cosf is Tilt: Depends
on h3
Coma y
Object v
Pincushion
Distortion
Barrel
Distortion x u
July 2003
Chuck DiMarzio, Northeastern University

41. Chuck DiMarzio, Northeastern University
Example: Mirrors
By Fermat’s Principle,
r1+r2 = constant v r1 r2 z
Result is an Ellipse with these foci.
One focus at infinity requires a parabola
Foci co-located requires a sphere.
July 2003
Chuck DiMarzio, Northeastern University

42. Chuck DiMarzio, Northeastern University
Mirrors for Focussing
v, cm.
-0.1
-0.08
-0.06
-0.04
-0.02
-0.05
0.05
0.1
Ellipse
Parabola
Sphere
s=30 cm,
s’=6cm
Note:
These Mirrors have a very large NA to illustrate the errors. In most mirrors, the errors could not be seen on this scale.
z, cm.
July 2003
Chuck DiMarzio, Northeastern University

43. Chuck DiMarzio, Northeastern University
Numerical Example
July 2003
Chuck DiMarzio, Northeastern University

44. Optical Design Process
July 2003
Chuck DiMarzio, Northeastern University

45. Ray Tracing Fundamentals
July 2003
Chuck DiMarzio, Northeastern University

46. Chuck DiMarzio, Northeastern University
Ray Tracing (1)
July 2003
Chuck DiMarzio, Northeastern University

47. Chuck DiMarzio, Northeastern University
Ray Tracing (2)
July 2003
Chuck DiMarzio, Northeastern University

48. If One Element Doesn’t Work...
Add Another Lens
“Let George Do It”
Different Index?
Smaller angles with
higher index. Thus germanium is better than ZnSe in IR. Not much hope in the visible.
Aspherics
July 2003
Chuck DiMarzio, Northeastern University

49. Summary of Concepts So Far
Paraxial Optics with Thin Lenses
Thick Lenses (Principal Planes)
Apertures: Pupils and Windows
Aberration Correction
Analytical
Ray Tracing
What’s Missing? Wave Optics
July 2003
Chuck DiMarzio, Northeastern University