AP Physics IV.C Geometric Optics. 25.1 Wave Fronts and Rays.

Slides:

Advertisements

Similar presentations

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

Advertisements

Law of Reflection (Smooth Surface):

Suppose that you hold the transparency in the photograph below in front of a mirror. How will its reflection appear? Is the image: (1) inverted top-to-bottom?

Optics Review #1 LCHS Dr.E.

Mirrors Law of Reflection The angle of incidence with respect to the normal is equal to the angle of reflection.

A wave front consists of all points in a wave that are in the same phase of motion. A wave front is one of many properties that light waves share with.

Chapter 26 Geometrical Optics. Units of Chapter 26 The Reflection of Light Forming Images with a Plane Mirror Spherical Mirrors Ray Tracing and the Mirror.

Physics Light: Geometric Optics 23.1 The Ray Model of Light 23.2 Reflection - Plane Mirror 23.3 Spherical Mirrors 23.5 Refraction - Snell’s law.

1 UCT PHY1025F: Geometric Optics Physics 1025F Geometric Optics Dr. Steve Peterson OPTICS.

AP Physics B Mrs. Wallace. Reflection Reflection occurs when light bounces off a surface. There are two types of reflection Specular reflection Off a.

Reflection of Light. When light rays hit an object, they change direction. The type of surface the light encounters determines the type of reflection.

Light, Reflection, and Refraction Chapters 14 and 15 OPTICS.

The Refraction of Light The speed of light is different in different materials. We define the index of refraction, n, of a material to be the ratio of.

Optics The Study of Light.

Reflection and Refraction. Reflection  Reflection occurs when light bounces off a surface.  There are two types of reflection – Specular reflection.

Geometric Optics The Law of Reflection.

Chapter 25. Mirrors and the Reflection of Light Our everyday experience that light travels in straight lines is the basis of the ray model of light. Ray.

26.6 Lenses. Converging Lens Focal length of a converging lens is real and considered positive.

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

Copyright © 2009 Pearson Education, Inc. Chapter 32 Light: Reflection and Refraction.

Geometric Optics Ray Model assume light travels in straight line

Physics 1502: Lecture 29 Today’s Agenda Announcements: –Midterm 2: Monday Nov. 16 … –Homework 08: due Friday Optics –Index of Refraction.

Example: An object 3 cm high is placed 20 cm from (a) a convex and (b) a concave spherical mirror, each of 10 cm focal length. Determine the position.

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.

Chapter 34. Images What is Physics? Two Types of Image

Copyright © 2010 Pearson Education, Inc. Lecture Outline Chapter 26 Physics, 4 th Edition James S. Walker.

Geometric Optics Conceptual Quiz 23.

Image Formation. We will use geometrical optics: light propagates in straight lines until its direction is changed by reflection or refraction. When we.

Geometric Optics September 14, Areas of Optics Geometric Optics Light as a ray. Physical Optics Light as a wave. Quantum Optics Light as a particle.

 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.

Light: Geometric Optics Chapter Ray Model of Light Light travels in a straight line so a ray model is used to show what is happening to the light.

Mirrors & Reflection.

Optics 2: REFRACTION & LENSES. REFRACTION Refraction: is the bending of waves because of the change of speed of a wave when it passes from one medium.

Chapter 25. Mirrors and the Reflection of Light

8. Thin lenses Thin lenses are those whose thickness is small compared to their radius of curvature. They may be either converging or diverging. 1) Types.

Ch23 Geometric Optics Reflection & Refraction of Light.

The Reflection of Light: Mirrors

Optics Review #1 LCHS Dr.E. When a light wave enters a new medium and is refracted, there must be a change in the light wave’s (A) color (B) frequency.

PROOF OF d i = d o ii rr 11 22 . DESCRIPTION OF d i = d o  Ray of light leaves base & strikes mirror at  i (reflected at same  )  Angles.

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

Ch 23 1 Chapter 23 Light: Geometric Optics © 2006, B.J. Lieb Some figures electronically reproduced by permission of Pearson Education, Inc., Upper Saddle.

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

Mirror Equation Ray diagrams are useful for determining the general location and size of the image formed by a mirror. However, the mirror equation and.

Chapter 7 Light and Geometric Optics

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.

Chapter 36 Image Formation.

AP Physics IV.C Geometric Optics. Wave Fronts and Rays.

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.

AP Physics 2 Unit 6 Wave Motion and Geometric Optics.

Lab 9: Geometrical optics Only 3 more labs to go!! Today we are going to do three experiments: 1. Measure the intensity of light as a function of distance.

Reflection & Mirrors. Reflection The turning back of an electromagnetic wave (light ray) at the surface of a substance. The turning back of an electromagnetic.

Optics The Study of Light Areas of Optics Geometric Optics Light as a ray. Physical Optics Light as a wave. Quantum Optics Light as a particle.

Reflection at Mirrors and Curved Surfaces Amy C Nau, OD.

 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.

AP Physics 2 Unit 7 Refraction and Physical Optics.

Optics Day 1 The Law of Reflection Optics The Study of Light.

PHY 102: Lecture Index of Refraction 10.2 Total Internal Reflection 10.3 Prism and Rainbows 10.4 Lenses 10.5 Formation of Images 10.6 Lens Equations.

Geometrical Optics.

Chapter 32Light: Reflection and Refraction Formation of Images by Spherical Mirrors Example 32-7: Convex rearview mirror. An external rearview car.

Light & Optics Chapters Electromagnetic Wave.

Reflection of Light Reflection – The bouncing back of a particle or wave that strikes the boundary between two media. Law of Reflection – The angle of.

Lecture 2: Reflection of Light: Mirrors (Ch 25) & Refraction of Light: Lenses (Ch 26)

Reflection of Light Reflection – The bouncing back of a particle or wave that strikes the boundary between two media. Law of Reflection – The angle of.

Geometric Optics AP Physics Chapter 23.

Reflection & Mirrors There are two kinds of mirrors Plane mirrors

17.2 Mirrors, Lenses, and Images

Refraction at Spherical Surfaces.

air water As light reaches the boundary between two media,

Presentation transcript:

AP Physics IV.C Geometric Optics

25.1 Wave Fronts and Rays

25.2 Reflection of Light

Specular and diffuse reflection

25.3 Plane Mirrors

Five Properties of the image of a Plane Mirror Upright Same size Located as far behind the mirror as the object is in front of the mirror Left to right reversed Virtual image

Ray Diagram for a Plane Mirror

Ex. What is the minimum mirror height needed for a person to see their full image?

25.4 Spherical Mirrors (concave – converging and convex – diverging)

The focal length and radius of curvature

Ray diagrams for curved mirrors

25.6 The mirror equation and magnification (and an impressive proof thrown in for free)

Summary of sign conventions for curved mirrors f is positive for a concave mirror and negative for a convex mirror s o is positive for an image located in front of the mirror (our only concern at this point) s i is positive for a real image (in front of the mirror) and negative for a virtual image (behind the mirror)

Ex. A 2.00 cm object is placed 7.10 cm from a concave mirror whose radius of curvature is cm. Find the location and size of the image.

Ex. An object with a height of 1.20 cm is placed 6.00 cm in front of a concave mirror with a focal length of 10.0 cm. Find the location and height of the image.

Ex. An object is placed 66 cm in front of a convex mirror that has a focal length of 46 cm. Find the image distance and magnification.

26.1 Refraction and Lenses

Refraction – the bending of light as it passes between two media with different optical densities

The index of refraction

p. 821: 1-6; Rev. 04B3, 04B , ? B3 a)1.2 EE -3 Wb b) V c)i A ii. ? d)? 04B5 a)i J ii. Tough one – ΔU is number of gas particles times ΔK av (5400 J) iii J b)Drawing c)i. drawing ii. yours

26.2 Snell’s Law

Ex. Light is incident upon an equilateral crown glass prism at an angle of 45.0º to one face. Calculate the angle at which the light emerges from the opposite face.

p. 821: 9-10, 13, 16; Rev. 03B º 16.a) 33ºb) 32º 03B1 a)Drawing b)100 N c)615 N d)Yours e)1.7 m/s 2

26.3 Total Internal Reflection

Ex. A ray of light in a diamond (n = 2.42) strikes an interface at 28º. Will the beam of light enter the air or will it be reflected internally? Will the beam of light be reflected internally if the diamond is surrounded by water?

Applications of total internal reflection

26.5 Dispersion of Light

p. 822: 23-25, 87B5, 01B º 87B5 a)? b)53º c)1.9 EE 8 m/s d)3.2 EE -7 m (320 nm) e)39º 01B4 a)1.6 (hint: use slope of graph and Snell’s Law) b)i. 4.4 EE 14 Hz ii.1.9 EE 8 m/s iii. 4.3 EE -7 m c)Drawing d)37º

26.6 Lenses

Two types of lenses

Images formed by converging lenses

Image formed by a diverging lens

A familiar friend

Sign conventions for lenses: f is positive for converging lenses and negative for diverging lenses s o is positive when light is reflected from the object (a real object) s i is positive when it is behind the lens (real image) and negative when it is in front of the lens (virtual image)

81B5, 82B6, 86B6, 94B5 81B5 a)Drawing b) ? c)9 cm d) note: 2 nd lens is at F of 1 st 82B6a) 3fb) drawing c)? 86B6a) drawing b) 6 cm c) Drawing d)-2 cme) ? f)Hint: use image of 1 st lens as object of 2 nd 94B5 a) 2.3 EE 8 m/s b)Drawing c) 49º d)40 cm below pool bottom e)i. ?ii. Hint: are values for n closer or farther away than in water?