March 02002 Chuck DiMarzio, Northeastern University 10100-2-1 ECE-1466 Modern Optics Course Notes Part 2 Prof. Charles A. DiMarzio Northeastern University.

Slides:

Advertisements

Similar presentations

Chapter 4 Companion site for Light and Video Microscopy Author: Wayne.

Advertisements

Consider Refraction at Spherical Surfaces:

Option G: Electromagnetic Waves G2: Optical Instruments.

Happyphysics.com Physics Lecture Resources Prof. Mineesh Gulati Head-Physics Wing Happy Model Hr. Sec. School, Udhampur, J&K Website: happyphysics.com.

Lenses in the Paraxial Limit

1 Stops in optical systems (5.3) Hecht 5.3 Monday September 30, 2002.

1 From Last Time… Lenses and image formation Object Image Lens Object Image Thurs. Sep. 17, 2009Physics 208, Lecture 5.

and Optical Instruments

Lecture 25-1 Locating Images Real images form on the side of a mirror where the objects are, and virtual images form on the opposite side. only using the.

Aperture Pupil (stop) Exit Pupil Entrance Pupil.

3. Geometrical Optics. Geometric optics—process of light ray through lenses and mirrors to determine the location and size of the image from a given object.

Physics 1502: Lecture 30 Today’s Agenda Announcements: –Midterm 2: Monday Nov. 16 … –Homework 08: due Friday Optics –Mirrors –Lenses –Eye.

Physics 1402: Lecture 31 Today’s Agenda Announcements: –Midterm 2: Monday Nov. 16 … –Homework 08: due Wednesday (after midterm 2) Optics –Lenses –Eye.

Fiber Optics Defining Characteristics: Numerical Aperture Spectral Transmission Diameter.

Hong Kong Polytechnic University Optics 1----by Dr.H.Huang, Department of Applied Physics1 Light Control through Optical System Our major concerns: field.

Optical Instruments Chapter 25.

Physics 52 - Heat and Optics Dr. Joseph F. Becker Physics Department San Jose State University © 2005 J. F. Becker San Jose State University Physics 52.

Image Formation III Chapter 1 (Forsyth&Ponce) Cameras “Lenses”

The Ray Vector A light ray can be defined by two co-ordinates: x in,  in x out,  out its position, x its slope,  Optical axis optical ray x  These.

Cameras Major components Lens (or combo) Film (or CCD) Aperture Shutter speed.

Biology 177: Principles of Modern Microscopy

Chapter 33 Lenses and Optical Instruments

Copyright © 2009 Pearson Education, Inc. Chapter 33 Lenses and Optical Instruments.

Lecture 14 Images Chp. 35 Opening Demo Topics –Plane mirror, Two parallel mirrors, Two plane mirrors at right angles –Spherical mirror/Plane mirror comparison.

Chapter 25 Optical Instruments.

Visual Angle How large an object appears, and how much detail we can see on it, depends on the size of the image it makes on the retina. This, in turns,

Design of photographic lens Shinsaku Hiura Osaka University.

Diffraction: single slit How can we explain the pattern from light going through a single slit? w screen L x.

Images Flat Mirror Images Your eyes tell you where/how big an object is Mirrors and lenses can fool your eyes – this is sometimes a good thing Place a.

Physics 213 General Physics Lecture Last Meeting: Diffraction Today: Optical Instruments.

Refraction. Optical Density  Inverse measure of speed of light through transparent medium  Light travels slower in more dense media  Partial reflection.

Lenses in Combination The analysis of multi-lens systems requires only one new rule: The image of the first lens acts as the object for the second lens.

Index of Refraction Index of refraction of a medium is defined in terms of the speed of light in this medium In general, the speed of light in any material.

Chapter 18 Ray Optics.

LIGHT: Geometric Optics. The Ray Model of Light Light travels in straight lines under a wide variety of circumstances Light travels in straight line paths.

Dr. Andrew Tomasch 2405 Randall Lab

Fundamental of Optical Engineering Lecture 3.  Aberration happens when the rays do not converge to a point where it should be. We may distinguish the.

A diffraction grating with 10,000 lines/cm will exhibit the first order maximum for light of wavelength 510 nm at what angle? (1 nm = 10-9 m) 0.51° 0.62°

Magnifiers, Projectors, CamerasPaul Avery (PHY 3400)1 Magnifiers, Projectors, Cameras Applied Optics Paul Avery University of Florida

1 Chapter 6 More on geometrical optics February 4 Thick lenses Review: Paraxial imaging from a single refracting spherical surface: Thin lens equation:

Copyright © 2010 Pearson Education, Inc. Lecture Outline Chapter 27 Physics, 4 th Edition James S. Walker.

PHYS 1442 – Section 004 Lecture #22-23 MW April 14-16, 2014 Dr. Andrew Brandt 1 Cameras, Film, and Digital The Human Eye; Corrective Lenses Magnifying.

Chapter 34 Lecture Eight: Images: II. Image Formed by a Thin Lens A thin lens is one whose thickness is small compared to the radii of curvature For a.

Optics Real-time Rendering of Physically Based Optical Effects in Theory and Practice Masanori KAKIMOTO Tokyo University of Technology.

Chapter 35 MirrorsLenses Images. We will use geometrical optics: light propagates in straight lines until its direction is changed by reflection or refraction.

Principal maxima become sharper Increases the contrast between the principal maxima and the subsidiary maxima GRATINGS: Why Add More Slits?

Geometrical Optics Chapter 24 + Other Tidbits 1. On and on and on …  This is a short week.  Schedule follows  So far, no room available for problem.

Optical Density - a property of a transparent medium that is an inverse measure of the speed of light through the medium. (how much a medium slows the.

Notes 2-5 OPTICAL TOOLS. Cameras: How do they work? Light from object travels through one or more convex lenses Lens focuses light Puts an image on film.

ECEN 4616/5616 Optoelectronic Design Class website with past lectures, various files, and assignments: (The.

Physics 203/204 4: Geometric Optics Images formed by refraction Lens Makers Equation Thin lenses Combination of thin lenses Aberration Optical Instruments.

Dispersion The spreading of light into its color components is called dispersion. When light enters a prism, the refracted ray is bent towards the normal,

Chapter 27 Lenses and Optical Instruments. Lenses Converging lens Diverging lens.

Thin Lenses A lens is an optical device consisting of two refracting surfaces The simplest lens has two spherical surfaces close enough together that we.

Prof. Charles A. DiMarzio Northeastern University Fall 2003 July 2003

Today Multiple Lenses The Eye Magnifiers & Microscopes

Physics 1202: Lecture 22 Today’s Agenda Announcements: –Lectures posted on: –HW assignments, etc.

Light refraction Chapter 29 in textbook.

Biology 227: Methods in Modern Microscopy

Matrix methods, aberrations & optical systems

Image Formation III Chapter 1 (Forsyth&Ponce) Cameras “Lenses” Guido Gerig CS-GY 6643, Spring 2016 (slides modified from Marc Pollefeys, UNC Chapel Hill/

July © Chuck DiMarzio, Northeastern University ECEG105/ECEU646 Optics for Engineers Course Notes Part 2: Geometric Optics (Reflection,

ECEG105 & ECEU646 Optics for Engineers Course Notes Part 2: Geometric Optics (Reflection, Refraction, Thin Lenses) Prof. Charles A. DiMarzio Northeastern.

1 Optical systems Hecht 5.7 Wednesday October 2, 2002.

Example: What kind of lens must be used, in order to give an erect image 1/5 as large as an object placed 15 cm in front of it? M = -q/p  -q/p=1/5 So.

Geometrical Optics.

Mirrors and Lenses How do eyeglasses correct your vision? When you look in a mirror, where is the face you see? In which ways is a cell phone camera similar.

July © Chuck DiMarzio, Northeastern University ECEG105/ECEU646 Optics for Engineers Course Notes Part 4: Apertures, Aberrations Prof.

Jeffrey R. Regester Physics Department High Point University

Mirrors, Plane and Spherical Spherical Refracting Surfaces

Presentation transcript:

March Chuck DiMarzio, Northeastern University ECE-1466 Modern Optics Course Notes Part 2 Prof. Charles A. DiMarzio Northeastern University Spring 2002

March Chuck DiMarzio, Northeastern University 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 L1L1 L2L2 L3L3 L4L4 L4’L4’

March 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,s) –to object space (x’,y’,s’) H H’ VV’ B B’

March Chuck DiMarzio, Northeastern University An Example; 10X Objective s= 16 mm s’=160 mm (A common standard) F’ F A’ A F’ F

March Chuck DiMarzio, Northeastern University The Simple Magnifier F F’ AA’

March Chuck DiMarzio, Northeastern University 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#  Means f=10 mm Maximum M m =25 For the Interested Student: What if s>f ?

March Chuck DiMarzio, Northeastern University Where Are We Going? Geometric Optics –Reflection –Refraction The Thin Lens –Multiple Surfaces –(From Matrix Optics) Principal Planes Effective Thin Lens –Stops Field Aperture –Aberrations Ending with a word about ray tracing and optical design.

March Chuck DiMarzio, Northeastern University Microscope Two-Step Magnification –Objective Makes a Real Image –Eyepiece Used as a Simple Magnifier F’ F A’ A F’ F

March Chuck DiMarzio, Northeastern University Microscope Objective F’ F A’ A F’ F

March Chuck DiMarzio, Northeastern University Microscope Eyepiece F’ F A2A2 A F A2’A2’

March Chuck DiMarzio, Northeastern University Microscope Effective Lens A D’D F F’ H H’ A F H F’ H’ 192 mm 19.2 mm f 1 =16mm f 2 =16mm Barrel Length = 160 mm Effective Lens: f = -1.6 mm

March Chuck DiMarzio, Northeastern University Microscope Effective Lens

March Chuck DiMarzio, Northeastern University Where Are We Going? Geometric Optics –Reflection –Refraction The Thin Lens –Multiple Surfaces –(From Matrix Optics) Principal Planes Effective Thin Lens –Stops Field Aperture –Aberrations Ending with a word about ray tracing and optical design.

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

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

March Chuck DiMarzio, Northeastern University Finding the Entrance Pupil Find all apertures in object space L1L1 L2L2 L3L3 L4L4 L 4 ’ is L 4 seen through L 1 -L 3 L 3 ’ is L 3 seen through L 1 -L 2 Entrance Pupil Subtends Smallest Angle from Object L1L1 L2’L2’ L4’L4’L3’L3’

March Chuck DiMarzio, Northeastern University 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 L1L1 L2’L2’ L4’L4’L3’L3’

March Chuck DiMarzio, Northeastern University Microscope Aperture Stop F’ F Aperture Stop =Entrance Pupil Exit 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 Image Analysis in Image Space

March Chuck DiMarzio, Northeastern University Microscope Field Stop F’ F Field Stop = Exit Window Entrance Window

March Chuck DiMarzio, Northeastern University f-Number & Numerical Aperture F’ F A A’ f D is Lens Diameter  NA, Numerical Aperture f#, f-number f-Number Numerical Aperture

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

March Chuck DiMarzio, Northeastern University Field of View Film= Exit Window

March Chuck DiMarzio, Northeastern University Chief Ray Aperture Stop Field Stop Exit Pupil Chief Ray passes through the center of every pupil

March Chuck DiMarzio, Northeastern University Hints on Designing A Scanner Place the mirrors at pupils Put Mirrors Here

March Chuck DiMarzio, Northeastern University Aberrations Failure of Paraxial Optics Assumptions –Ray Optics Based On sin(  )=tan(  )=  –Spherical Waves  =  0 +2  x 2 /  Next Level of Complexity –Ray Approach: sin(  )=    –Wave Approach:  =  0 +2  x 2 /  c    A Further Level of Complexity –Ray Tracing

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

March Chuck DiMarzio, Northeastern University Example of Aberrations (2) m4061_3  z(h=0.6)  z(h=1.0) Longitudinal Aberration =  z Transverse Aberration =  x  x(h=1.0) Where Exactly is the image? What is its diameter?

March Chuck DiMarzio, Northeastern University Spherical Aberrations Beam Size, m q, Shape Factor s=1m, s’=4cm DL at 10  m n=2.4n=1.5 n=4 DL at 1.06  m 500 nm p, Position Factor q, Shape Factor n=4 n=2.4 n=1.5

March Chuck DiMarzio, Northeastern University Ray Tracing Fundamentals

March Chuck DiMarzio, Northeastern University Ray Tracing (1)

March Chuck DiMarzio, Northeastern University Ray Tracing (2)

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

March Chuck DiMarzio, Northeastern University 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