Light and Reflection. Chapter 13 Page 444

Similar documents
Preview. Light and Reflection Section 1. Section 1 Characteristics of Light. Section 2 Flat Mirrors. Section 3 Curved Mirrors

Light sources can be natural or artificial (man-made)

UNIT 12 LIGHT and OPTICS

Light and Applications of Optics

Algebra Based Physics. Reflection. Slide 1 / 66 Slide 2 / 66. Slide 3 / 66. Slide 4 / 66. Slide 5 / 66. Slide 6 / 66.

Ch 24. Geometric Optics

Test Review # 8. Physics R: Form TR8.17A. Primary colors of light

CH. 23 Mirrors and Lenses HW# 6, 7, 9, 11, 13, 21, 25, 31, 33, 35

Mirrors and Lenses. Images can be formed by reflection from mirrors. Images can be formed by refraction through lenses.

Geometric Optics. Ray Model. assume light travels in straight line uses rays to understand and predict reflection & refraction

Reflection and Color

Algebra Based Physics. Reflection. Slide 1 / 66 Slide 2 / 66. Slide 3 / 66. Slide 4 / 66. Slide 5 / 66. Slide 6 / 66.

Test Review # 9. Physics R: Form TR9.15A. Primary colors of light

Chapter 23. Light Geometric Optics

OPTICS DIVISION B. School/#: Names:

Notation for Mirrors and Lenses. Chapter 23. Types of Images for Mirrors and Lenses. More About Images

Image Formation. Light from distant things. Geometrical optics. Pinhole camera. Chapter 36

Academic Year: 2017/2018 Term 3 Physics - Grade 10 Revision sheet Chapter 13: section 1,2,3 / Chapter 14: section 1 pages: ( ),( )

Physics for Kids. Science of Light. What is light made of?

Final Reg Optics Review SHORT ANSWER. Write the word or phrase that best completes each statement or answers the question.

LlIGHT REVIEW PART 2 DOWNLOAD, PRINT and submit for 100 points

PHYS 160 Astronomy. When analyzing light s behavior in a mirror or lens, it is helpful to use a technique called ray tracing.

E X P E R I M E N T 12

Section 1: Sound. Sound and Light Section 1

Chapter 23. Mirrors and Lenses

Person s Optics Test KEY SSSS

Chapter 23. Mirrors and Lenses

Life Science Chapter 2 Study Guide

Chapter 36. Image Formation

Subtractive because upon reflection from a surface, some wavelengths are absorbed from the white light and subtracted from it.

Chapter 36. Image Formation

Answers to Chapter 11

Optics Practice. Version #: 0. Name: Date: 07/01/2010

Spherical Mirrors. Concave Mirror, Notation. Spherical Aberration. Image Formed by a Concave Mirror. Image Formed by a Concave Mirror 4/11/2014

Section 3 Curved Mirrors. Calculate distances and focal lengths using the mirror equation for concave and convex spherical mirrors.

Phys214 Fall 2004 Midterm Form A

Astronomy 80 B: Light. Lecture 9: curved mirrors, lenses, aberrations 29 April 2003 Jerry Nelson

mirrors and lenses PHY232 Remco Zegers Room W109 cyclotron building

Chapter 16 Light Waves and Color

Unit 3 - Foundations of Waves

LIGHT. ENERGY FOR LIFE 2 Presented by- Ms.Priya

Chapter 23. Mirrors and Lenses

NORTHERN ILLINOIS UNIVERSITY PHYSICS DEPARTMENT. Physics 211 E&M and Quantum Physics Spring Lab #8: Thin Lenses

Physics Worksheet. Topic -Light. Q1 If the radius of curvature of spherical mirror is 20 cm, what is its focal length.

Chapter 18 Optical Elements

ii) When light falls on objects, it reflects the light and when the reflected light reaches our eyes then we see the objects.

Waves & Oscillations

King Saud University College of Science Physics & Astronomy Dept.

Practice Problems (Geometrical Optics)

Name. Light Chapter Summary Cont d. Refraction

DEEPAK SIR LIGHT

19. Ray Optics. S. G. Rajeev. April 2, 2009

Experiment 3: Reflection

Light: Lenses and. Mirrors. Test Date: Name 1ÿ-ÿ. Physics. Light: Lenses and Mirrors

Chapter 3 Mirrors. The most common and familiar optical device

Refraction is the when a ray changes mediums. Examples of mediums:

LIGHT REFLECTION AND REFRACTION

Physics II. Chapter 23. Spring 2018

Condition Mirror Refractive Lens Concave Focal Length Positive Focal Length Negative. Image distance positive

Chapter 23. Geometrical Optics: Mirrors and Lenses and other Instruments

Waves & Oscillations

Physics 132: Lecture Fundamentals of Physics II

Converging Lenses. Parallel rays are brought to a focus by a converging lens (one that is thicker in the center than it is at the edge).

Chapter 34 Geometric Optics (also known as Ray Optics) by C.-R. Hu

Ch 16: Light. Do you see what I see?

1. Draw the Ray Diagram, name lens or mirror shown and determine the SALT for each picture

2015 EdExcel A Level Physics EdExcel A Level Physics. Lenses

Class-X Assignment (Chapter-10) Light-Reflection & Refraction

Match the correct description with the correct term. Write the letter in the space provided.

GEOMETRICAL OPTICS Practical 1. Part I. BASIC ELEMENTS AND METHODS FOR CHARACTERIZATION OF OPTICAL SYSTEMS

13. A beam of yellow light and a beam of magenta light are both shined on a white wall. What color does the wall appear to be?

Physics 132: Lecture Fundamentals of Physics II

Physics 132: Lecture Fundamentals of Physics

Chapter Ray and Wave Optics

Dr. Todd Satogata (ODU/Jefferson Lab) Monday, April

28 Thin Lenses: Ray Tracing

Chapter 24 Geometrical Optics. Copyright 2010 Pearson Education, Inc.

Lecture 3: Geometrical Optics 1. Spherical Waves. From Waves to Rays. Lenses. Chromatic Aberrations. Mirrors. Outline

Chapter 36. Image Formation

Chapter 2 - Geometric Optics

Fill in the blanks. Reading Skill: Compare and Contrast - questions 3, 17

AP Physics Problems -- Waves and Light

Mirrors, Lenses &Imaging Systems

Assignment X Light. Reflection and refraction of light. (a) Angle of incidence (b) Angle of reflection (c) principle axis

Gaussian Ray Tracing Technique

ECEN 4606, UNDERGRADUATE OPTICS LAB

Chapter: Sound and Light

1) An electromagnetic wave is a result of electric and magnetic fields acting together. T 1)

G1 THE NATURE OF EM WAVES AND LIGHT SOURCES

4.6.1 Waves in air, fluids and solids Transverse and longitudinal waves Properties of waves


Chapter 29/30. Wave Fronts and Rays. Refraction of Sound. Dispersion in a Prism. Index of Refraction. Refraction and Lenses

Reading: Lenses and Mirrors; Applications Key concepts: Focal points and lengths; real images; virtual images; magnification; angular magnification.

always positive for virtual image

Aberrations of a lens

General Physics II. Ray Optics

REFLECTION THROUGH LENS

Station # 1. Reflection off of a rough surface. The Law of reflection. Problem: How is light reflected off of a flat smooth surface?

Geometrical Optics. Have you ever entered an unfamiliar room in which one wall was covered with a

Lecture 21. Physics 1202: Lecture 21 Today s Agenda

Transcription:

Light and Reflection Chapter 13 Page 444

Characteristics of Light Let s talk about the electromagnetic spectrum. This includes visible light. What looks like white light can be split into many different colors. Light possesses characteristics of both particles and waves. For our purposes, we will model light as a wave. Just like other waves, electromagnetic waves vary depending on their frequency and wavelength.

Characteristics of Light Differences in frequency and wavelength account for the different colors we see, as well as whether or not the wave is even visible. Light is composed of oscillating electric and magnetic fields, which are perpendicular to each other, and perpendicular to the direction of the wave s motion. There s a table of different waves on the EM spectrum on page 447. Wavelength, λ, is measured in units of length, like m, mm, cm. Frequency is measured in Hertz.

Characteristics of Light

Characteristics of Light ALL electromagnetic waves move at the speed of light! In a vacuum: 2.99792458 x 10 8 m/s. In air: 2.99709 x 10 8 m/s. There is a relationship between frequency, wavelength, and speed that we ve seen before as regards waves. This applies to light waves, as well! c=fλ Sample Problem A page 448 Practice A page 449

Characteristics of Light The motion of electromagnetic waves can be approximated as rays. In reality, light spreads out as it travels. A laser is an example of a light source that spreads very little; it is concentrated and focused, unlike for example our fluorescent lights.

Characteristics of Light Illuminance decreases as the square of the distance from the source. The rate at which light is emitted from a source is called the luminous flux and is measured in lumens. My dad will talk for hours about lumens. He used to work for Sylvania. He once had to travel by air with a xenon lamp for Imax movies, but this was before 9/11 so security just asked some questions and didn t hassle him about it. I ve heard this story fifty times. Zzzzzzz...

Characteristics of Light The illuminance the luminous flux divided by the area of the surface is measured in lm/m 2 which is called lux. It decreases as the radius squared when you move away from a light source. Section Review page 450

Flat Mirrors Light interacts with surfaces in two ways: some of the light may be absorbed, and some of the light may be reflected. No surface is a perfect reflector, though good mirrors can reflect around 90% of incident light. A rougher surface reflects incoming light in many different directions. This is called diffuse reflection. A smooth surface reflects incoming light in one direction. This is called specular reflection. (The direction depends on the direction of incoming light.)

Flat Mirrors Incoming and reflected angles are equal. Imagine a straight line drawn perpendicular to the surface at the point where the incoming light is striking it. (Another word for this kind of line is normal.) The angle of incidence is measured between the ray of incoming light and the normal line. The angle of reflection is measured between the normal line and the ray of reflected light.

Flat Mirrors The simplest mirror is a flat mirror. Light bounces off objects in front of the mirror and is reflected to an observer. To the observer, the light originates on the other side of the mirror.

Flat Mirrors An object s image is said to be at a location behind the mirror. The image will be the same distance from the mirror as the object. The image is also the same size as the object. This image is known as a virtual image. It can never be displayed on a physical surface.

Flat Mirrors We can predict an image location by using geometric ray diagrams. Sizes and distances will be reflected symmetrically in a flat mirror. The object s distance from the mirror at any given point will be the same as the image s distance from the mirror. All dimensions in the image will be the same as on the object.

Curved Mirrors While flat mirrors create images with the same dimensions as the original object, curved mirrors create images with different dimensions compared to the original object. A basic type of curved mirror is a concave spherical mirror a mirror that is shaped like part of a sphere s surface. Concave mirrors like these can magnify nearby objects, as needed, and are often used when applying makeup, for example.

Curved Mirrors As you get farther away from a concave spherical mirror, the image will appear smaller and upsidedown. The location of the image is determined in part by the radius of curvature of the mirror s surface, R. The radius of curvature is the distance from the mirror s surface to the center of curvature, C. A mirror s principal axis extends from the center of the mirror s surface through its center of curvature.

Curved Mirrors Rays that are farther away from the principal axis don t exactly intersect at the image point. This is called spherical aberration. Ray diagrams and the mirror equations are valid for rays that are near the principal axis of the mirror. These are called paraxial rays. (Para near, axial axis.)

Curved Mirrors The Mirror Equation: If you know the mirror radius and the distance the object is from the mirror, you can predict where the image will appear using the mirror equation. Object distance: p Image distance: q Radius of curvature: R Focal length: f

Curved Mirrors Consider light coming from very far away from the mirror. From large enough distances, we say that the light is coming from infinity. Light coming from infinity will be directed towards the same location, called the focal point halfway between the mirror and its center of curvature. Real images are formed on the front side of the mirror. Virtual images are formed behind the mirror, on the back side.

Curved Mirrors The image from a curved mirror is rarely the same size as the object. Thus, we can talk about the magnification of an image. Once you know the object s image location, you can determine its magnification. Magnification: M Object height: h Image height: h

Curved Mirrors For negative values of M, the image will be upsidedown. For values of M between 0 and 1, the image will be smaller. For values of M larger than 1, the image will be larger.

Curved Mirrors Another type of curved mirror is a convex spherical mirror. These are also called diverging mirrors, as all rays coming from infinity will bounce off at a greater angle away from the principal axis. The focal length for a convex spherical mirror is negative; the focal point and center of curvature are behind the mirror. Think: fisheye mirrors opposite driveways; smaller insets in rear-view mirrors. Sample Problem C page 465 Practice C page 466

Curved Mirrors In our ray diagrams for spherical mirrors, you may have noticed that our rays rarely intersect perfectly at the image s location. This is a real phenomenon called a spherical aberration, and when you see images reflected in spherical mirrors they will appear blurry. A mirror whose surface cross-section is parabolic eliminates this problem completely!

Curved Mirrors Parabolic mirrors are used in some telescopes!

Color and Polarization Objects can absorb certain wavelengths of light while reflecting others. We perceive the reflected wavelengths of light. For example, a fresh, green leaf reflects green light.

Color and Polarization Colors of light can be additive. Additive primary colors of light red, green, and blue will combine to make white light. Additive properties of colors are applied in television screens and projections. Colors can be subtractive. Subtractive primary colors of light cyan, magenta, and yellow will combine to filter out all light. Subtractive properties of colors can be applied in painting, coloring, etc.

Color and Polarization Light from a normal source will include various waves that have electric fields which oscillate in many directions. This light is unpolarized. Polarization is when light passes through a filter which only allows waves with a certain orientation to pass through. These waves have linear polarization.

Color and Polarization Light is polarized along the transmission axis of the substance it passes through. If light is shone at two substances with perpendicular transmission axes, light will not get through.

Color and Polarization Polarization can also occur by reflection and by scattering. Light reflected off a surface will be polarized parallel to the surface. Light can be scattered off molecules of atmospheric gas.

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback