1. ECEG105 & ECEU Optics for Engineers Course Notes Part 2: Geometric Optics (Reflection, Refraction, Thin Lenses)
Prof. Charles A. DiMarzio
Northeastern University
Fall 2003
July 2003
Chuck DiMarzio, Northeastern University

2. Chuck DiMarzio, Northeastern University
Where Are We Going?
Geometric Optics
Reflection
Refraction
The Thin Lens
Multiple Surfaces
Matrix Optics
Principle Planes
Effective Thin Lens
Stops
Field
Aperture
Aberrations
Ending with a word about ray tracing and optical design.
July 2003
Chuck DiMarzio, Northeastern University

3. Basic Geometric Optics
Reflection and Refraction
Imaging
Real and Virtual
Image Location; Conjugate Planes
Magnification
Transverse, Angular, Longitudinal
Reflecting Optics
Refracting Optics
July 2003
Chuck DiMarzio, Northeastern University

4. Chuck DiMarzio, Northeastern University
Snell’s Law (1)
Use Fermat’s Principle
Assume Correct Path to Start
Find Differential Path Length for Change ds
Index = n Q
Index = n’
Index = n
q’’ s’ q P s
Index = n’
-ds’
July 2003
Chuck DiMarzio, Northeastern University

5. Chuck DiMarzio, Northeastern University
Snell’s Law (2) ds
Index = n’
Index = n s’ s
-ds’
July 2003
Chuck DiMarzio, Northeastern University

6. Chuck DiMarzio, Northeastern University
Reflection q q
July 2003
Chuck DiMarzio, Northeastern University

7. Chuck DiMarzio, Northeastern University
Plane of Incidence
Contains Normal
Contains Incident Ray
And Thus Contains Refracted Ray
Is the Plane Shown in the Drawing
Angles
Defined from Normal
q’’ q
July 2003
Chuck DiMarzio, Northeastern University

8. Chuck DiMarzio, Northeastern University
Imaging
First, Assume a Point Object
Spherical Wavefronts and Radial Rays Define Object Location
Find Image Location
Real or Virtual?
Next Assume an Extended Object
Compute Magnification
Transverse, Longitudinal, Angular
July 2003
Chuck DiMarzio, Northeastern University

9. Chuck DiMarzio, Northeastern University
Sign Definitions B
Object Distance, s
Positive to Left
Image Distance, s’
For Refraction
Positive to Right
For Reflection
Notation
Capital Letter; Point
Lower Case; Distance
(Almost Always) A’ F A F’ f B’ s s’ s s’
July 2003
Chuck DiMarzio, Northeastern University

10. Real and Virtual Images
Real Image
Rays Converge
Can Image on Paper
Solid Lines in Notes
Virtual Image
Extended Rays Converge
Dotted-Lines in notes
July 2003
Chuck DiMarzio, Northeastern University

11. Chuck DiMarzio, Northeastern University
The Plane Mirror (1)
Point Object
Extended Object q B B’ q q h x’ x A A’ A A’ s
-s’
July 2003
Chuck DiMarzio, Northeastern University

12. Chuck DiMarzio, Northeastern University
The Plane Mirror (2)
Image is
Virtual (Dotted lines converge)
Erect (m>0),
Perverted (can not rotate to object)
but not distorted (|m|=|mz|)
Transverse Magnification
x’=x m=x’/x=1
Longitudinal Magnification
dy’
dx’
ds’
ds’=-ds mz=ds’/ds=-1
Angular Magnification
q’’=q ma=q’’/q =1 dx
(refer to picture
on left side of
previous page) dy ds
July 2003
Chuck DiMarzio, Northeastern University

13. Chuck DiMarzio, Northeastern University
The Retroreflector
2-D Example
3 Mirrors at 90 deg.
Low-Cost Configuration
Flat Plastic Front
Corner-Cube Patterned Back
Total Internal Reflection
3-D Retroreflector
or Corner Cube
July 2003
Chuck DiMarzio, Northeastern University

14. The Spherical Mirror (1)
Exterior Angles of Triangles
g=a+q b=g+q a+b=2g
Tangents of Angles
tan a=h/(s-d), tan b = h/(s’-d),
tan g = h/(R-d) d q h q b a g A C A’
Small-Angle Approximation s’ R
Conjugate Planes s
July 2003
Chuck DiMarzio, Northeastern University

15. The Spherical Mirror (2)B s’ x’ q A’ x A q B’
Transverse Magnification
ma=b/a =s/s’= |1/m|
July 2003
Chuck DiMarzio, Northeastern University

16. The Spherical Mirror (3)
Longitudinal Magnification
Compare Transverse
Image Equation
Differentiate
Image is
Real (Converging Rays),
Inverted (m<0),
Distorted (mz=-m2),
but Not Perverted (sign(m)=sign(mz))
July 2003
Chuck DiMarzio, Northeastern University

17. Chuck DiMarzio, Northeastern University
Focal Length Defined C F F’ A’
Object at Infinity
Definition
Application
July 2003
Chuck DiMarzio, Northeastern University

18. Refracting Surfaces (1)
Snell’s Law 50
Air to Water n n’ 45
Air to Glass
Air to ZnSe (10 m m) 40
Air to Ge (10 m m) 35
q’’ 30 q
Angle of Refraction 25 20 15 10 5 10 20 30 40 50 60 70 80 90
Angle of Incidence
July 2003
Chuck DiMarzio, Northeastern University

19. Refracting Surfaces (2)
Snell’s Law 90
Water to Air n n’ 80
Glass to Air
ZnSe to Air (10 m m) 70
Ge to Air(10 m m) 60 q 50 q’
Angle of Refraction 40 30 20 10
Critical Angle 10 20 30 40 50 60 70 80 90
Angle of Incidence
July 2003
Chuck DiMarzio, Northeastern University

20. Roadmap of Refractive Optics
Snell’s Law: Refraction at a Plane Surface
Refraction at a Spherical Surface
Gaussian Optics: Small-Angle Approximation
The Simple Lens
One Glass Element = Two Surfaces
The Thin Lens (Good Approximation & More)
Matrix Optics for Complicated Systems
Equivalent Thin Lens
July 2003
Chuck DiMarzio, Northeastern University

21. The Single Plane Surface (1)
Angles
Snell’s Law
Point Object (n’>n as shown) q’
Small-Angle Approximation q h A’ A s
-s’
July 2003
Chuck DiMarzio, Northeastern University

22. The Single Plane Surface (2)
Snell’s Law
Angles
Extended Object
Small-Angle Approximation B’ B x’ x q
Transverse Magnification A’ A q’ s
-s’
mz, ma and summary left for the interested student
July 2003
Chuck DiMarzio, Northeastern University

23. The Spherical Surface (1)d
Exterior Angles of Triangles q h q’ a g b A C A’
Tangents of Angles s R
Small-Angle
Approximation s’
July 2003
Chuck DiMarzio, Northeastern University

24. The Spherical Surface (2)
Back Focal Point
Object at Infinity
Front Focus
Image at Infinity
Optical Power
Units: m-1 = diopeters F’ f’ F f
July 2003
Chuck DiMarzio, Northeastern University

25. The Spherical Surface (3)
Angles B x A’ q A q’
-x’ s B’ s’
Snell’s Law &
Small Angles
Transverse
Magnification
July 2003
Chuck DiMarzio, Northeastern University

26. The Spherical Surface Summary
Focal Length
Front
Back
Optical Power
Magnification
Transverse
Longitudinal
July 2003
Chuck DiMarzio, Northeastern University

27. Chuck DiMarzio, Northeastern University
The Simple Lens (1)
Two Surfaces:
Air-Glass
Glass-Air A1
A1’ A2 1
Find Image from First
Surface: s1 R1
s1’
July 2003
Chuck DiMarzio, Northeastern University

28. Chuck DiMarzio, Northeastern University
The Simple Lens (2) 2
Object Distance for Second
Surface:
n2’ n1
n1’ = n2
-s2+d = s1’ s2 = d-s1’
A2’
Find Image from
Second Surface:
A1’ A2 3
Note Virtual
Object R2
s’2
-s2 d
s1’
July 2003
Chuck DiMarzio, Northeastern University

29. Chuck DiMarzio, Northeastern University
The Simple Lens (3) 4
Summarize
n2’ n1
n1’ = n2
Note, w for working
distance instead of s.
This is important later
A2’ A1 s1 w
s2 = d-s1’
s’2 w’ d
July 2003
Chuck DiMarzio, Northeastern University

30. Chuck DiMarzio, Northeastern University
The Thin Lens (1)
July 2003
Chuck DiMarzio, Northeastern University

31. Chuck DiMarzio, Northeastern University
The Thin Lens (2)
Back Focal Length
Front Focal Length f f’
July 2003
Chuck DiMarzio, Northeastern University

32. Special Case: Thin Lens in Airf f’
Lens Equation
Lens Makers Equation with d = 0
July 2003
Chuck DiMarzio, Northeastern University