Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Matrix methods in paraxial optics Wednesday September 25, 2002.

Published byMoses Parks Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Matrix methods in paraxial optics Wednesday September 25, 2002."— Presentation transcript:

1 1 Matrix methods in paraxial optics Wednesday September 25, 2002

2 2 Matrices in paraxial Optics Translation (in homogeneous medium) 0000 L yoyoyoyo y 

3 3 Matrix methods in paraxial optics Refraction at a spherical interface  y ’’’’φ  ’’’’ nn’

4 4 Matrix methods in paraxial optics Refraction at a spherical interface  y ’’’’φ  ’’’’ nn’

5 5 Matrix methods in paraxial optics Lens matrix n nLnLnLnLn’ For the complete system Note order – matrices do not, in general, commute.

6 6 Matrix methods in paraxial optics

7 7 Matrix properties

8 8 Matrices: General Properties For system in air, n=n’=1

9 9 System matrix

10 10 System matrix: Special Cases (a) D = 0   f = Cy o (independent of  o ) yoyoyoyo ffff Input plane is the first focal plane

11 11 System matrix: Special Cases (b) A = 0  y f = B  o (independent of y o ) oooo yfyfyfyf Output plane is the second focal plane

12 12 System matrix: Special Cases (c) B = 0  y f = Ay o yfyfyfyf Input and output plane are conjugate – A = magnification yoyoyoyo

13 13 System matrix: Special Cases (d) C = 0   f = D  o (independent of y o ) Telescopic system – parallel rays in : parallel rays out oooo ffff

14 14 Examples: Thin lens Recall that for a thick lens For a thin lens, d=0 

15 15 Examples: Thin lens Recall that for a thick lens For a thin lens, d=0  In air, n=n’=1

16 16 Imaging with thin lens in air oooo ’’’’ ss’ yoyoyoyoy’ Inputplane Output plane

17 17 Imaging with thin lens in air For thin lens: A=1 B=0 D=1 C=-1/f y’ = A’y o + B’  o

18 18 Imaging with thin lens in air y’ = A’y o + B’  o For imaging, y’ must be independent of  o  B’ = 0 B’ = As + B + Css’ + Ds’ = 0 s + 0 + (-1/f)ss’ + s’ = 0 For thin lens: A=1 B=0 D=1 C=-1/f

19 19 Examples: Thick Lens n nfnfnfnfn’ yoyoyoyo y’ H’ h’ x’ f’ ’’’’ h’ = - ( f’ - x’ )

20 20 Cardinal points of a thick lens

21 21 Cardinal points of a thick lens

22 22 Cardinal points of a thick lens Recall that for a thick lens As we have found before h can be recovered in a similar manner, along with other cardinal points

Download ppt "1 Matrix methods in paraxial optics Wednesday September 25, 2002."

Similar presentations

Lenses and Imaging (Part II) Reminders from Part I Surfaces of positive/negative power Real and virtual images Imaging condition Thick lenses Principal.

Lenses and Imaging (Part II) Reminders from Part I Surfaces of positive/negative power Real and virtual images Imaging condition Thick lenses Principal.
Properties of Thin Lenses

Properties of Thin Lenses
Chapter 23.

Chapter 23.
Hecht 5.2, 6.1 Monday September 16, 2002

Hecht 5.2, 6.1 Monday September 16, 2002
Modern Optics Lab Experiment 2: REFLECTION AND REFRACTION AT SPHERICAL INTERFACES  Measuring: Radii of mirrors and lenses Focal points of mirrors, spherical.

Modern Optics Lab Experiment 2: REFLECTION AND REFRACTION AT SPHERICAL INTERFACES  Measuring: Radii of mirrors and lenses Focal points of mirrors, spherical.
Ray Diagrams.

Ray Diagrams.
1 Cardinal planes/points in paraxial optics Wednesday September 18, 2002.

1 Cardinal planes/points in paraxial optics Wednesday September 18, 2002.
Reference Book is Geometric Optics.

Reference Book is Geometric Optics.
Chapter 36 Image Formation. Summary: mirrors Sign conventions: + on the left - on the right Convex and plane mirrors: only virtual images (for real objects)

Chapter 36 Image Formation. Summary: mirrors Sign conventions: + on the left - on the right Convex and plane mirrors: only virtual images (for real objects)
Geometric Optics of thick lenses and Matrix methods

Geometric Optics of thick lenses and Matrix methods
 a  b tan  ~  etc. so  = h / s,  = h / s’,  = h / R Snell’s Law: n a sin  a = n b sin  b n a  a = n b  b  b = ( 

 a  b tan  ~  etc. so  = h / s,  = h / s’,  = h / R Snell’s Law: n a sin  a = n b sin  b n a  a = n b  b  b = ( 
Waves on a spherical refracting surface. Suppose that light is incident parallel to the optic axis.

Waves on a spherical refracting surface. Suppose that light is incident parallel to the optic axis.
Homework Set 4: From “Seeing the Light” Chapter 3: (starting page 101) P9, P10, P11, PM3 From “Seeing the Light” Chapter 4: P2, P5, P7, P13 Due: Monday,

Homework Set 4: From “Seeing the Light” Chapter 3: (starting page 101) P9, P10, P11, PM3 From “Seeing the Light” Chapter 4: P2, P5, P7, P13 Due: Monday,
Chapter 36 Serway & Jewett 6 th Ed.. Fig Q36-26, p.1167 Mirrors and Lenses.

Chapter 36 Serway & Jewett 6 th Ed.. Fig Q36-26, p.1167 Mirrors and Lenses.
Lenses We will only consider “thin” lenses where the thickness of the lens is small compared to the object and image distances. Eugene Hecht, Optics, Addison-Wesley,

Lenses We will only consider “thin” lenses where the thickness of the lens is small compared to the object and image distances. Eugene Hecht, Optics, Addison-Wesley,
Imaging Science FundamentalsChester F. Carlson Center for Imaging Science The Geometric Optics of Image Formation Graphical Ray Tracing.

Imaging Science FundamentalsChester F. Carlson Center for Imaging Science The Geometric Optics of Image Formation Graphical Ray Tracing.
Design Realization lecture 26 John Canny 11/25/03.

Design Realization lecture 26 John Canny 11/25/03.
C F V Light In Side S > 0 Real Object Light Out Side S ’ > 0 Real Image C This Side, R > 0 S < 0 Virtual Object S ’ < 0 Virtual Image C This Side, R

C F V Light In Side S > 0 Real Object Light Out Side S ’ > 0 Real Image C This Side, R > 0 S < 0 Virtual Object S ’ < 0 Virtual Image C This Side, R
Imaging Science FundamentalsChester F. Carlson Center for Imaging Science The Geometric Optics of Image Formation.

Imaging Science FundamentalsChester F. Carlson Center for Imaging Science The Geometric Optics of Image Formation.
Lecture 17 Ray Optics-3 Chapter 23 PHYSICS 270 Dennis Papadopoulos March 22, 2010.

Lecture 17 Ray Optics-3 Chapter 23 PHYSICS 270 Dennis Papadopoulos March 22, 2010.

Similar presentations

Ads by Google