Chapter 33 - Light and Illumination. A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University

Similar documents
Overview. What is EMR? Electromagnetic Radiation (EMR) LA502 Special Studies Remote Sensing

Physical Science Study Guide Unit 7 Wave properties and behaviors, electromagnetic spectrum, Doppler Effect

MAKING SENSE OF ENERGY Electromagnetic Waves

After a wave passes through a medium, how does the position of that medium compare to its original position?

Sample Exercise 6.1 Concepts of Wavelength and Frequency

Theremino System Theremino Spectrometer Technology

Energy. Mechanical Energy

Review Vocabulary spectrum: a range of values or properties

AP Physics B Ch. 23 and Ch. 24 Geometric Optics and Wave Nature of Light

Name Date Class ELECTRONS IN ATOMS. Standard Curriculum Core content Extension topics

ILLUSTRATIVE EXAMPLE: Given: A = 3 and B = 4 if we now want the value of C=? C = = = 25 or 2

Q1. The diagram below shows the range of wavelengths and frequencies for all the types of radiation in the electromagnetic spectrum.

Waves Sound and Light

Solar Energy. Outline. Solar radiation. What is light?-- Electromagnetic Radiation. Light - Electromagnetic wave spectrum. Electromagnetic Radiation

From lowest energy to highest energy, which of the following correctly orders the different categories of electromagnetic radiation?

INTRODUCTION FIGURE 1 1. Cosmic Rays. Gamma Rays. X-Rays. Ultraviolet Violet Blue Green Yellow Orange Red Infrared. Ultraviolet.

How To Understand Light And Color

Science In Action 8 Unit C - Light and Optical Systems. 1.1 The Challenge of light

WAVES AND ELECTROMAGNETIC RADIATION

Reflection Lesson Plan

Radiation Transfer in Environmental Science

Chapter 17: Light and Image Formation

Introduction to Light, Color, and Shadows

STAAR Science Tutorial 30 TEK 8.8C: Electromagnetic Waves

ATOMIC SPECTRA. Apparatus: Optical spectrometer, spectral tubes, power supply, incandescent lamp, bottles of dyed water, elevating jack or block.

Experiment #5: Qualitative Absorption Spectroscopy

Take away concepts. What is Energy? Solar Energy. EM Radiation. Properties of waves. Solar Radiation Emission and Absorption

Physics 30 Worksheet # 14: Michelson Experiment

Upon completion of this lab, the student will be able to:

PHYS 222 Spring 2012 Final Exam. Closed books, notes, etc. No electronic device except a calculator.

PHOTOELECTRIC EFFECT AND DUAL NATURE OF MATTER AND RADIATIONS

Light as a Wave. The Nature of Light. EM Radiation Spectrum. EM Radiation Spectrum. Electromagnetic Radiation

To explain the basics of how lasers work and let visitors experiment with laser properties.

Interference. Physics 102 Workshop #3. General Instructions

Treasure Hunt. Lecture 2 How does Light Interact with the Environment? EMR Principles and Properties. EMR and Remote Sensing

Light Waves and Matter

Color and Light. DELTA SCIENCE READER Overview Before Reading Guide the Reading After Reading

Conceptual Physics Review (Chapters 25, 26, 27 & 28) Chapter 25 Describe the period of a pendulum. Describe the characteristics and properties of

ProfessionalLighting. Section1. Introduction to Lighting. SourceBook. The. for Photo, Video, Cine & Theatrical

Spectroscopy. Biogeochemical Methods OCN 633. Rebecca Briggs

THE NATURE OF LIGHT AND COLOR

D.S. Boyd School of Earth Sciences and Geography, Kingston University, U.K.

Infrared Spectroscopy: Theory

Name Class Date. spectrum. White is not a color, but is a combination of all colors. Black is not a color; it is the absence of all light.

Physics 25 Exam 3 November 3, 2009

The Electromagnetic Spectrum

Activity 9: Solar-Electric System PUZZLE

GRID AND PRISM SPECTROMETERS

Specific Intensity. I ν =

Physics 6C, Summer 2006 Homework 2 Solutions

5. The Nature of Light. Does Light Travel Infinitely Fast? EMR Travels At Finite Speed. EMR: Electric & Magnetic Waves

Preview of Period 3: Electromagnetic Waves Radiant Energy II

Fiber Optics: Fiber Basics

Photosynthesis and Light in the Ocean Adapted from The Fluid Earth / Living Ocean Heather Spalding, UH GK-12 program

Blackbody Radiation References INTRODUCTION

Light. What is light?

v = fλ PROGRESSIVE WAVES 1 Candidates should be able to :

Astronomy 110 Homework #04 Assigned: 02/06/2007 Due: 02/13/2007. Name:

Atomic Structure: Chapter Problems

Principle of Thermal Imaging

Light Transmission and Reflectance

Chemistry 111 Lab: Intro to Spectrophotometry Page E-1

Current Staff Course Unit/ Length. Basic Outline/ Structure. Unit Objectives/ Big Ideas. Properties of Waves A simple wave has a PH: Sound and Light

Experiment 5. Lasers and laser mode structure

Production of X-rays. Radiation Safety Training for Analytical X-Ray Devices Module 9

Hello and Welcome to this presentation on LED Basics. In this presentation we will look at a few topics in semiconductor lighting such as light

DSM155 Digital LED Light Meter User s Manual DSM155

Electromagnetic Radiation (EMR) and Remote Sensing

Chapter 36 - Lenses. A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University

Physics 202 Problems - Week 8 Worked Problems Chapter 25: 7, 23, 36, 62, 72

Improved predictive modeling of white LEDs with accurate luminescence simulation and practical inputs

E190Q Lecture 5 Autonomous Robot Navigation

Chapter 23. The Reflection of Light: Mirrors

UNIVERSITY OF SASKATCHEWAN Department of Physics and Engineering Physics

Illumination Fundamentals

Waves - Transverse and Longitudinal Waves

Diffraction and Young s Single Slit Experiment

Blackbody radiation derivation of Planck s radiation low

Using the Spectrophotometer

Robot Perception Continued

CPI Links Content Guide & Five Items Resource

Measuring Light. 1 Executive Summary Luminance Illuminance Luminous Efficiency Summary... 4

Study Guide for Exam on Light

DOING PHYSICS WITH MATLAB COMPUTATIONAL OPTICS RAYLEIGH-SOMMERFELD DIFFRACTION INTEGRAL OF THE FIRST KIND

What is Solar Control?

Honeywell Night Vision Security. The Night Hawk Advantage

physics 1/12/2016 Chapter 20 Lecture Chapter 20 Traveling Waves

CHEM 1411 Chapter 5 Homework Answers

Calculating particle properties of a wave

Chapter 30 - Magnetic Fields and Torque. A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University

COLLATED QUESTIONS: ELECTROMAGNETIC RADIATION

PHYSICAL QUANTITIES AND UNITS

Tech Bulletin. Understanding Solar Performance

TOPIC 5 (cont.) RADIATION LAWS - Part 2

Using light scattering method to find The surface tension of water

13- What is the maximum number of electrons that can occupy the subshell 3d? a) 1 b) 3 c) 5 d) 2

Examples of Uniform EM Plane Waves

Ch 25 Chapter Review Q & A s

4.4 WAVE CHARACTERISTICS 4.5 WAVE PROPERTIES HW/Study Packet

Owner s Manual

Transcription:

Chapter 33 - Light and Illumination A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University 2007

Objectives: After completing this module, you should be able to: Define light,, discuss its properties, and give the range of wavelengths for visible spectrum. Apply the relationship between frequencies and wavelengths for optical waves. Define and apply the concepts of luminous flux, luminous intensity,, and illumination. Solve problems similar to those presented in this module.

A Beginning Definition All objects are emitting and absorbing EM radia- tion.. Consider a poker placed in a fire. As heating occurs, the emitted EM waves have higher energy and eventually become visible. First red... then white. 1 2 3 4 Light may be defined as electromagnetic radiation that is is capable of of affecting the sense of of sight.

Electromagnetic Waves Electric E Magnetic B B E c 3 x 10 8 m/s Wave Properties: 1. Waves travel at the speed of light c. 2. Perpendicular electric and magnetic fields. 3. equire no medium for propagation. For a complete review of of the electromagnetic properties, you should study module 32C.

The Wavelengths of Light The electromagnetic spectrum spreads over a tremendous range of of frequencies or or wavelengths. The wavelength is is related to to the frequency f: f: c = fc = 3 x 10 8 m/s Those EM waves that are visible (light) have wave- lengths that range from 0.00004 to 0.00007 cm. ed, 0.00007 cm Violet, 0.00004 cm

Frequency wavelength f (Hz) nm) 10 24 10 23 10 22 10 21 10 20 10 19 10 18 10 17 10 16 10 15 10 14 10 13 10 12 10 11 10 10 10 9 10 8 10 7 10 6 10 5 10 4 Gamma rays X-rays Ultraviolet Infrared rays Short adio waves Broadcast adio Long adio waves 10-7 10-6 10-4 10-3 10-1 1 10 10 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 10 10 10 11 10 12 10 13 The EM Spectrum A wavelength of one nanometer 1 nm is: 1 nm = 1 x 10-9 -9 m Visible Spectrum 400 nm 700 nm ed 700 nm Violet 400 nm c = fc = 3 x 10 8 m/s

Example 1. Light from a Helium-Neon laser has a wavelength of 632 nm.. What is the frequency of this wave? The Helium Neon Laser Laser Wavelength = 632 nm c c f f 8 3 x 10 m/s -9 632 x 10 m f f = 4.75 x 10 14 14 Hz ed light

Properties of Light Any study of of the nature of of light must explain the following observed properties: ectilinear propagation: Light travels in straight lines. eflection: Light striking a smooth surface turns back into the original medium. efraction: Light bends when entering a transparent medium.

The Nature of Light Physicists have studied light for centuries, finding that it it sometimes behaves as a particle and sometimes as a wave. Actually, both are correct! eflection and rectilinear propagation (straight line path) Dispersion of white light into colors.

Photons and Light ays Light may be thought of as little bundles of waves emitted in discrete packets called photons. The wave treatment uses rays to show the direction of advancing wave fronts. photons Light ray Light rays are convenient for describing how light behaves.

Light ays and Shadows A geometric analysis may be made of shadows by tracing light rays from a point light source: Point source shadow screen The dimensions of of the shadow can be found by using geometry and known distances.

Example 2: The diameter of the ball is 4 cm and it is located 20 cm from the point light source. If the screen is 80 cm from the source, what is the diameter of the shadow? h 80cm 20 cm 4cm 20cm 4 cm 80 cm h The ratio of of shadow to to the source is is same as that of of ball to to source. Therefore: h (4 cm)(80 cm) 20 cm h = 16 cm

Shadows of Extended Objects Extended source penumbra umbra The The umbra umbra is the is the region region where where no light no light reaches the reaches screen. the screen. The penumbra is the outer area where only part of the light reaches the screen.

The Sensitivity Curve Human eyes are not equally sensitive to all colors. Eyes are most sensi- tive in the mid-range near = = 555 nm. Sensitivity Sensitivity curve 555 nm 400 nm 700 nm Wavelength 40 W 40 W Yellow light appears brighter to to the eye than does red light.

Luminous Flux Luminous flux is the portion of total radiant power that is capable of affecting the sense of sight. Typically only about 10% of the power (flux) emitted from a light bulb falls in the visible region. The unit for luminous flux is the lumen which will be given a quantitative definition later.

A Solid Angle: Steradians Working with luminous flux requires the use of of a solid angle measure called the steradian (sr). A solid angle of of one steradian (1 sr) ) is is subtended at at the center of of a sphere by an area A equal to to the square of of its radius ( 22 ). ). A The Steradian 2 A

Example 3. What solid angle is subtended at the center of a sphere by an area of 1.6 m 2? The radius of the sphere is 5 m. m 5 m A 1.6 m 2 A The Steradian 2 A 2 2 1.60 m (5.00 m) = 0.00640 sr sr 2

The Lumen as a Unit of Flux One lumen (lm) is the luminous flux emitted from a 1/60 cm 2 opening in a standard source and included in a solid angle of one steradian (1 sr). In practice, sources of light are usually rated by comparison to a commercially prepared standard light source. A typical 100-W incandescent light bulb emits a total radiant power of about 1750 lm.. This is for light emitted in all directions.

The Lumen in Power Units ecalling that luminous flux is really radiant power allows us to define the lumen as follows: One lumen is is equal to to 1/680 W of of yellow- green light of of wavelength 555 nm. A disadvantage of this approach is the need to refer to sensitivity curves to determine the flux for different colors of light. Sensitivity curve Wavelength

Luminous Intensity The luminous intensity I for a light source is the luminous flux per unit solid angle. F I Luminous intensity: F I Unit is the candela (cd) A source having an intensity of of one candela emits a flux of of one lumen per steradian.

Total flux for Isotropic Source An isotropic source emits in all directions; i.e., over a solid angle of 4 steradians. = = 44 sr Thus, for such F a source, the I intensity is: 4 Total flux: F = 4I The flux confined to area A is: F = I A F 3 m

Example 4. A 30 cd spotlight is located 3 m above a table. The beam is focused on a surface area of 0.4 m 2. Find the intensity of the beam. Total flux: F = 4I F T = 4(304 cd) ) = 377 lm The luminous intensity of the beam depends on 2 0.4 m 2 2 ; 0.0444 sr A (3 m) I F 754 lm 0.0444 sr 3 m Beam Intensity: I = 8490 cd

Illumination of a Surface The illumination Eof a surface Ais defined as the luminous flux per unit area (F/A) ( ) in in lumens per square meter which is is renamed a lux (lx). An illumination of of one lux occurs when a flux of of one lumen falls on an area of of one square meter. F E Unit: lux (lx) A Illumination, E Area A

Illumination Based on Intensity The illumination E of of a surface is is directly proportional to to the intensity II and inversely proportional to to the square of of the distance. F F E ; I ; F I A I A E but so that 2 A Illumination, E I 2 Area A This equation applies for perpendicular surfaces.

Example 5. A 400-cd light is located 2.4 m from a tabletop of area 1.2 m 2. What is the illumination and what flux F falls on the table? E I 400 cd (2.40 m) 2 2 Illumination: E = 69.4 lx Now, recalling that E = F/A,, we find F from: F = EA = (69.4 lx)(1.20 m 2 ) F = 93.3 lm

The Inverse Square elationship E I 2 E 1 m E/9 E/4 1 m 2 4 m 2 2 m 9 m 2 3 m If the intensity is 36 lx at 1 m, it will be 9 lx at 2 m and only 4 lx at 3 m.

Summary Light may be defined as electromagnetic radiation that is is capable of of affecting the sense of of sight. General Properties of Light: ectilinear propagation eflection c efraction = fc = 3 x 10 8 m/s ed, 700 nm Violet, 400 nm

Summary (Continued) The formation of shadows: Extended source penumbra umbra Luminous flux is the portion of total radiant power that is capable of affecting the sense of sight.

Summary (Continued) A The Steradian 2 A Total flux: F = 4I Luminous intensity: F I Unit is the candela (cd) E F A Unit: lux (lx)

Summary (Cont.) Illumination, E I 2 Illumination, E 9 m 2 3 m E/9 E/4 4 m 2 1 m 2 2 m 1 m E Area A

CONCLUSION: Chapter 33 Light and Illumination

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information