Lecture 15 Refraction, Lenses, Aberrations Chapter 23.4  23.7 Outline Atmospheric Refraction Thin Lenses Aberrations.

Slides:

Advertisements

Similar presentations

Option G2: Optical Instruments

Advertisements

Mirrors And Lenses Chapter 23.

Flat Mirrors Consider an object placed in front of a flat mirror

Chapter 15 Pretest Light and Refraction

Refraction of Light Chapter 18, Section 1.

Chapter 23 Mirrors and Lenses.

Chapter 31 Images.

Chapter 23 Mirrors and Lenses.

Chapter 23 Mirrors and Lenses Conceptual questions: 4,5,10,14,15,17

Chapter 36 Image Formation.

Chapter 34 Geometric Optics. What is Geometric Optics It is the study of light as particles. Geometric optics treats light as particles (or rays) that.

Chapter 23 Mirrors and Lenses. Notation for Mirrors and Lenses The object distance is the distance from the object to the mirror or lens Denoted by p.

Chapter 23 Mirrors and Lenses.

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.

Lecture 23 Mirrors Lens.

Reference Book is Geometric Optics.

Image Formation 2 Thin Lens Multi lens/mirror system

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

Image Formation by Mirrors and Lenses

Chapter 33 Lenses and Optical Instruments Refraction: Snell’s Law Example 32-8: Refraction through flat glass. Light traveling in air strikes a.

Lenses Physics 202 Professor Lee Carkner Lecture 21.

Copyright © 2009 Pearson Education, Inc. Lecture 2 – Geometrical Optics b) Thin Lenses.

Geometric Optics Ray Model assume light travels in straight line

Chapter 23 Mirrors and Lenses.

Refraction (bending light) Refraction is when light bends as it passes from one medium into another. When light traveling through air passes into the glass.

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.

S-95 Explain how a curved mirror, and a curved lens are different. Think in terms of image formation and in terms of what light photons do.

A. can be focused on a screen. B. can be projected on a wall.

Lenses Chapter 30.

 Mirrors that are formed from a section of a sphere.  Convex: The reflection takes place on the outer surface of the spherical shape  Concave: The.

Chapter 23 Mirrors and Lenses.

Chapter 14 Section 2 Thin lenses.

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

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.

Unit 11: Part 2 Mirrors and Lenses. Outline Plane Mirrors Spherical Mirrors Lenses The Lens Maker’s Equation Lens Aberrations.

Geometric Optics This chapter covers how images form when light bounces off mirrors and refracts through lenses. There are two different kinds of images:

 When light strikes the surface of an object  Some light is reflected  The rest is absorbed (and transferred into thermal energy)  Shiny objects,

Lesson 25 Lenses Eleanor Roosevelt High School Chin-Sung Lin.

1. How is the index of refraction calculated? How is light refracted as it speeds up? How is light refracted as it slows down? Index of refraction = speed.

Chapter 36 Image Formation.

Lecture 18 Optical Instruments

Announcements Two exams down, one to go! No HW this week. Office hours: My office hours today from 2-3 pm (or make an appointment) Always check out

Today’s agenda: Death Rays. You must know when to run from Death Rays. Refraction at Spherical Surfaces. You must be able to calculate properties of images.

Thin Lens Chapter Bending of Light Any transparent object that is curved with affect the path of light rays. Ex: o Glass bottle full of water will.

© Houghton Mifflin Harcourt Publishing Company Preview Objectives Refraction of Light The Law of Refraction Sample Problem Chapter 14 Section 1 Refraction.

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.

 Mirrors that are formed from a section of a sphere.  Convex: The reflection takes place on the outer surface of the spherical shape  Concave: The.

Chapter 14 Preview Objectives Refraction of Light

Ying Yi PhD Lab 5: Lenses 1 PHYS II HCC. Outline PHYS II HCC 2 Basic concepts: image, convex lens, concave lens, focal length Lab objectives.

Part 10 Optics --Mirrors and Lenses Chapter 24 Geometric Optics.

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.

Refraction of Light Chapter 18, Section 1. Refraction  When light encounters a transparent or translucent medium, some light is reflected from the surface.

Refraction. Refraction of Light When light waves pass from one medium to the next, its speed changes, causing it to bend. Going from lower to higher index.

Refraction & Lenses. Refraction of Light When a ray of light traveling through a transparent medium encounters a boundary leading into another transparent.

Lenses Converging Lens Diverging Lens F F f f.

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.

College Physics by Serway and Faughn Chapter 23 and 25

Chapter 23 Mirrors and Lenses © 2014 A. Dzyubenko.

Physics 2102 Jonathan Dowling Lecture 37: MON 20 APR Optics: Images.

Speed of light The speed of light is 3.0 x 108 m/s in a vacuum

Refraction at Spherical Surfaces.

Geometrical Optics Seminar add-on Ing. Jaroslav Jíra, CSc.

Light and Lenses While Mirrors involve the reflection of light and the images we see, Lenses involve another property of light, refraction, or the effects.

Presentation transcript:

Lecture 15 Refraction, Lenses, Aberrations Chapter 23.4  23.7 Outline Atmospheric Refraction Thin Lenses Aberrations

Atmospheric Refraction Atmospheric refraction is bending of light due to gradual changing density of the air throughout the atmosphere. Images of objects, close to the horizon, appear at a higher elevation that the real objects are. Atmospheric refraction is hardly noticeable at high viewing angles (e.g., near zenith).

Atmospheric Refraction

Mirages The mirage is an atmospheric refraction phenomenon due to large temperature changes of the air at different heights above the Earth. There are superior (inverted image above the ‘normal’) and inferior (inverted image is below the ‘normal’). Light rays from an object move toward the observer in two different ways through the different temperature layers.two

Thin Lenses A lens is a piece of glass (plastic) with two refracting surfaces, which are either curved (e.g., a segment of a sphere) or plain. Lenses are used to form images by refraction in optical instruments (microscopes, telescopes, cameras, etc.) Two types of lenses: converging (thickest in the middle) and diverging (thickest at the edges).types

Thin Lenses The focal length of a lens is the image distance of an object at an infinite distance from it. The focal point is where a group of rays parallel to the lens’ axis converges.where The thin-lens equation has the same form as the mirror equation.equation  +  =  p q f  = (n  1)    F R 1 R 2 Lens maker’s equation

Sign Convention

Ray Diagram for Thin Lenses Ray 1: parallel to the lens’ axis, to its center, through the focus on the other lens’ side. Ray 2: through the lens’ center, continues in a straight line. Ray 3: through the closest focus, emerging from the lens parallel to the lens’ axis.

Combinations of Thin Lenses For a system of two lenses, the image formed by the first one is treated as the object for the second one. The image formed by the second lens is the final image of the system. The overall magnification is the product of the magnifications of the individual lenses.

Problem with a Two-Lens System Problem: Find the image location. Solution: p' = 12cm f '=  6cm    =  f ' p' q' q' =  4cm p = 12+4=16cm f = 8cm 1/q = 1/8  1/16=1/16 q = 16cm image

Aberrations Departures of real images from the ideal predicted by simple theory are called aberrations. Types of aberrations To reduce spherical aberration, parabolic mirrors are used instead of spherical.parabolic To reduce chromatic aberration, combinations of converging and diverging lenses are used.

Summary Atmospheric refraction is a phenomenon that moves images of objects, seen through the air, due to a gradual change of the air density and temperature. Thin lenses are used to form images by refraction in optical instruments to enhance our vision. Aberrations are distortions of images, predicted by the simple theory of geometric optics.