Part 1 Investigating Snell s Law
|
|
- Harriet Collins
- 6 years ago
- Views:
Transcription
1 Geometric Optics with Lenses PURPOSE: To observe the refraction of light off through lenses; to investigate the relationship between objects and images; to study the relationship between object distance, image distance, and focal length and to investigate magnification. EQUIPMENT: Ray box with power supply, lens kit, white paper, ruler, protractor, colored pencils, optics bench with component holders, 100 mm focal length convex lenses, viewing screen, calculator. Part 1 Investigating Snell s Law Light waves refract (bend) if they pass through a transparent medium which causes them to change speed. Snell s Law describes the relationship of incident and refracted rays when the medium changes. We shall investigate what occurs when light rays go from air to acrylic. The speed of light through acrylic is 2.00 x 10 8 m/s. Assume the speed of light in air = c. What is the index of refraction for: a. air, (n 1 in Fig.1)? Fig.1 b. acrylic (n 2 in Fig. 1) Procedure ➀ Place the ray box, on a white sheet of paper on the table. Slide the ray mask until only one white ray is showing. This will be the incident ray, as shown on the diagram, right. ➁ Place the rhombus from the lens kit on the table and position it so the ray passes through the parallel sides as shown in Fig. 2. ➂ Trace the parallel surfaces of the rhombus, the incident ray, Fig.2 and the transmitted ray (leaves the rhombus). Indicate the incoming and the outgoing rays with arrows in the appropriate directions. ➃ Remove the rhombus and draw a line connecting the points where the ray entered and left the rhombus. This represents the refracted ray inside the rhombus. ➄ At the point where the ray enters the rhombus, draw the normal to the incident surface with a dashed line. Continue it all the way through to the parallel side, as shown in Fig 2. ➅ Measure the angle of incidence (θ1) and the angle of refraction (θ2) with a protractor. Both these angles should be measured from the normal. Record the values in the data table, below. Repeat for another angle. ➆ Use Snell s Law to calculate a theoretical angle of refraction (θ2-th). Record the values in the data table. Calculate the percent difference between theoretical and measured (experimental) values for θ 2. 1
2 Data Table for Snell s Law Angle of incidence (θ1) Angle of Refraction (θ2) Experimental Angle of Refraction (θ2-th) Theoretical Percent difference Questions: 1. Explain how your data support Snell s Law: 2. What is the angle of the ray that leaves the rhombus (transmitted ray) relative to the incident ray? Explain why this is the case? Part 2 Concave and Convex Lens Procedure ➀ Place the ray box on a white piece of paper. Using five white rays from the ray box, shine the rays straight into the Fig. 3 convex lens from the lens kit. Trace around the surface of the lens and trace the incident and transmitted rays. Indicate the incoming and the outgoing rays with arrows in the appropriate directions. ➁ The ray box simulates light rays coming from a long distance and striking the lens parallel to the principal axis. Measure the length from the center of the convex lens to where the refracted rays cross. Record the result in the data table below. What is the place called where the five refracted rays cross each other? ➂ Repeat the procedure for the concave lens. Note that in Step 2, the rays leaving the lens are diverging and they will not cross. Use a ruler to extend the outgoing rays straight back through the lens to find where these extended rays cross. ➃ What is different about where the focal point for the concave lens is located, relative to the focal point of the convex lens? 2
3 ➄Nest the convex and concave lenses together and place them in the path of the parallel rays. the rays. What does this tell you about the relationship between the focal lengths of these two lenses? Part 3 Image Formation for the Convex Lens PROCEDURE: 1. Set up the optics bench as shown below. Note that in this picture the light source (ray box) and the object (crossed arrow target) are the same. 2. Use the lens labeled 100 mm. Please note that this is a nominal focal length, and they are all somewhat different. Assume 100 mm is the true focal length for the time being, choose a distance, d o, that is greater than twice the focal length (i.e. greater than 200mm). Predict the following for this value of d o : Fig.4 a. Will the image be larger, smaller, or the same size? b. Will the image be upright or inverted? c. Will the image be real or virtual? d. Will the value for d i be greater than, equal to, or less than d o? 3. Do it! Put the lens at your chosen distance of d o from the crossed arrow target and slide the screen to the place where the image is the most sharply focused. Now calculate the actual focal length for your 100mm lens. Is d o greater than the true value of 2f? If not, change your d o value so that it is and find the new image. Enter your results in the table, below. You may get a slightly different value of f for each measurement. When measuring the size of the object, choose something easily seen in the image (e.g. the arrow, or the inner target). 3
4 Distance of lens from object d o > 2f f < d o < 2f d o = 2f d o < f d o = f d o mm d i mm f mm (calculate) size of object mm size of image mm Actual magnification h i /h 0 4. How did your predictions compare with the experiment? Explain: 5. Repeat the process for a value of d o which is greater than f, but less than 2f. Predict the following for this value of d o : a. Will the image be larger, smaller, or the same size? b. Will the image be upright or inverted? c. Will the image be real or virtual? d. Will the value for d i be greater than, equal to, or less than d o? 5. Do it! Enter the results in the table. How was this image different than the previous case? How was it similar? 6. Based on the previous two experiments, predict the magnification of the image when the lens is placed at a distance of exactly 2f from the crossed arrow target. m = 7. Do it! Enter the results in the table. What do you notice about the values of d o and d i compared to each other? Did the actual magnification agree with your prediction? 8. Predict the following for a value of d o that is less than the focal length: 4
5 a. Will the image be larger, smaller, or the same size? b. Will the image be upright or inverted? c. Will the image be real or virtual? d. Will the value for d i be greater than, equal to, or less than d o? 9. Do it! In this case, it is not possible to obtain the value of d i by finding a focused image on the screen. Determine where the image should be and how you should go about finding it. 10. Put the lens at the focal length (use the average of all the calculated focal lengths). Can you find an image with the screen? By looking through the lens? Where should the image be? Fill in the table with the values that you can obtain, either by measurement or by calculation. 11. Which of these arrangements (d o > 2f, f < d o < 2f, etc.) is used to make a slide projector show an image on a screen. How do you make the screen image appear upright? 12. Which of these arrangements (d o > 2f, f < d o < 2f, etc.) is used to make the image at the back of a camera? 13. When you take a picture, you often use an adjustment to get the object in focus. What do you think is happening inside of the camera when you do this? 14. Use the 3 special rays for the thin lens configurations that follow. 5
6 6
7 7
Geometric Optics. Ray Model. assume light travels in straight line uses rays to understand and predict reflection & refraction
Geometric Optics Ray Model assume light travels in straight line uses rays to understand and predict reflection & refraction General Physics 2 Geometric Optics 1 Reflection Law of reflection the angle
More informationExperiment 3: Reflection
Model No. OS-8515C Experiment 3: Reflection Experiment 3: Reflection Required Equipment from Basic Optics System Light Source Mirror from Ray Optics Kit Other Required Equipment Drawing compass Protractor
More informationConverging 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 30: Lenses Types of Lenses Piece of glass or transparent material that bends parallel rays of light so they cross and form an image Two types: Converging Diverging Converging Lenses Parallel rays
More informationAlgebra Based Physics. Reflection. Slide 1 / 66 Slide 2 / 66. Slide 3 / 66. Slide 4 / 66. Slide 5 / 66. Slide 6 / 66.
Slide 1 / 66 Slide 2 / 66 Algebra Based Physics Geometric Optics 2015-12-01 www.njctl.org Slide 3 / 66 Slide 4 / 66 Table of ontents lick on the topic to go to that section Reflection Refraction and Snell's
More informationLO - Lab #05 - How are images formed from light?
LO - Lab #05 - Helpful Definitions: The normal direction to a surface is defined as the direction that is perpendicular to a surface. For example, place this page flat on the table and then stand your
More informationPhysics 197 Lab 7: Thin Lenses and Optics
Physics 197 Lab 7: Thin Lenses and Optics Equipment: Item Part # Qty per Team # of Teams Basic Optics Light Source PASCO OS-8517 1 12 12 Power Cord for Light Source 1 12 12 Ray Optics Set (Concave Lens)
More informationAlgebra Based Physics. Reflection. Slide 1 / 66 Slide 2 / 66. Slide 3 / 66. Slide 4 / 66. Slide 5 / 66. Slide 6 / 66.
Slide 1 / 66 Slide 2 / 66 lgebra ased Physics Geometric Optics 2015-12-01 www.njctl.org Slide 3 / 66 Slide 4 / 66 Table of ontents lick on the topic to go to that section Reflection Refraction and Snell's
More informationBasic Optics System OS-8515C
40 50 30 60 20 70 10 80 0 90 80 10 20 70 T 30 60 40 50 50 40 60 30 70 20 80 90 90 80 BASIC OPTICS RAY TABLE 10 0 10 70 20 60 50 40 30 Instruction Manual with Experiment Guide and Teachers Notes 012-09900B
More informationChapter 36. Image Formation
Chapter 36 Image Formation Real and Virtual Images Real images can be displayed on screens Virtual Images can not be displayed onto screens. Focal Length& Radius of Curvature When the object is very far
More informationLab 11: Lenses and Ray Tracing
Name: Lab 11: Lenses and Ray Tracing Group Members: Date: TA s Name: Materials: Ray box, two different converging lenses, one diverging lens, screen, lighted object, three stands, meter stick, two letter
More information10.2 Images Formed by Lenses SUMMARY. Refraction in Lenses. Section 10.1 Questions
10.2 SUMMARY Refraction in Lenses Converging lenses bring parallel rays together after they are refracted. Diverging lenses cause parallel rays to move apart after they are refracted. Rays are refracted
More informationComplete the diagram to show what happens to the rays. ... (1) What word can be used to describe this type of lens? ... (1)
Q1. (a) The diagram shows two parallel rays of light, a lens and its axis. Complete the diagram to show what happens to the rays. (2) Name the point where the rays come together. (iii) What word can be
More informationChapter 23. Light Geometric Optics
Chapter 23. Light Geometric Optics There are 3 basic ways to gather light and focus it to make an image. Pinhole - Simple geometry Mirror - Reflection Lens - Refraction Pinhole Camera Image Formation (the
More informationCondition Mirror Refractive Lens Concave Focal Length Positive Focal Length Negative. Image distance positive
Comparison between mirror lenses and refractive lenses Condition Mirror Refractive Lens Concave Focal Length Positive Focal Length Negative Convex Focal Length Negative Focal Length Positive Image location
More informationFinal Reg Optics Review SHORT ANSWER. Write the word or phrase that best completes each statement or answers the question.
Final Reg Optics Review 1) How far are you from your image when you stand 0.75 m in front of a vertical plane mirror? 1) 2) A object is 12 cm in front of a concave mirror, and the image is 3.0 cm in front
More informationChapter 18 Optical Elements
Chapter 18 Optical Elements GOALS When you have mastered the content of this chapter, you will be able to achieve the following goals: Definitions Define each of the following terms and use it in an operational
More informationP202/219 Laboratory IUPUI Physics Department THIN LENSES
THIN LENSES OBJECTIVE To verify the thin lens equation, m = h i /h o = d i /d o. d o d i f, and the magnification equations THEORY In the above equations, d o is the distance between the object and the
More informationDetermination of Focal Length of A Converging Lens and Mirror
Physics 41 Determination of Focal Length of A Converging Lens and Mirror Objective: Apply the thin-lens equation and the mirror equation to determine the focal length of a converging (biconvex) lens and
More informationGeometric Optics Practice Problems. Ray Tracing - Draw at least two principle rays and show the image created by the lens or mirror.
Geometric Optics Practice Problems Ray Tracing - Draw at least two principle rays and show the image created by the lens or mirror. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Practice Problems - Mirrors Classwork
More informationLaboratory 12: Image Formation by Lenses
Phys 112L Spring 2013 Laboratory 12: Image Formation by Lenses The process by which convex lenses produce images can be described with reference to the scenario illustrated in Fig. 1. An object is placed
More informationName: Lab Partner: Section:
Chapter 10 Thin Lenses Name: Lab Partner: Section: 10.1 Purpose In this experiment, the formation of images by concave and convex lenses will be explored. The application of the thin lens equation and
More informationInstructions. To run the slideshow:
Instructions To run the slideshow: Click: view full screen mode, or press Ctrl +L. Left click advances one slide, right click returns to previous slide. To exit the slideshow press the Esc key. Optical
More informationThin Lenses. Lecture 25. Chapter 23. Ray Optics. Physics II. Course website:
Lecture 25 Chapter 23 Physics II Ray Optics Thin Lenses Course website: http://faculty.uml.edu/andriy_danylov/teaching/physicsii Lecture Capture: http://echo360.uml.edu/danylov201415/physics2spring.html
More informationNORTHERN ILLINOIS UNIVERSITY PHYSICS DEPARTMENT. Physics 211 E&M and Quantum Physics Spring Lab #8: Thin Lenses
NORTHERN ILLINOIS UNIVERSITY PHYSICS DEPARTMENT Physics 211 E&M and Quantum Physics Spring 2018 Lab #8: Thin Lenses Lab Writeup Due: Mon/Wed/Thu/Fri, April 2/4/5/6, 2018 Background In the previous lab
More informationLAB 12 Reflection and Refraction
Cabrillo College Physics 10L Name LAB 12 Reflection and Refraction Read Hewitt Chapters 28 and 29 What to learn and explore Please read this! When light rays reflect off a mirror surface or refract through
More informationOptics Practice. Version #: 0. Name: Date: 07/01/2010
Optics Practice Date: 07/01/2010 Version #: 0 Name: 1. Which of the following diagrams show a real image? a) b) c) d) e) i, ii, iii, and iv i and ii i and iv ii and iv ii, iii and iv 2. A real image is
More informationAP Physics Problems -- Waves and Light
AP Physics Problems -- Waves and Light 1. 1974-3 (Geometric Optics) An object 1.0 cm high is placed 4 cm away from a converging lens having a focal length of 3 cm. a. Sketch a principal ray diagram for
More informationPHYS 160 Astronomy. When analyzing light s behavior in a mirror or lens, it is helpful to use a technique called ray tracing.
Optics Introduction In this lab, we will be exploring several properties of light including diffraction, reflection, geometric optics, and interference. There are two sections to this lab and they may
More informationWaves & Oscillations
Physics 42200 Waves & Oscillations Lecture 27 Geometric Optics Spring 205 Semester Matthew Jones Sign Conventions > + = Convex surface: is positive for objects on the incident-light side is positive for
More informationDepartment of Physics & Astronomy Undergraduate Labs. Thin Lenses
Thin Lenses Reflection and Refraction When light passes from one medium to another, part of the light is reflected and the rest is transmitted. Light rays that are transmitted undergo refraction (bending)
More information28 Thin Lenses: Ray Tracing
28 Thin Lenses: Ray Tracing A lens is a piece of transparent material whose surfaces have been shaped so that, when the lens is in another transparent material (call it medium 0), light traveling in medium
More informationActivity 6.1 Image Formation from Spherical Mirrors
PHY385H1F Introductory Optics Practicals Day 6 Telescopes and Microscopes October 31, 2011 Group Number (number on Intro Optics Kit):. Facilitator Name:. Record-Keeper Name: Time-keeper:. Computer/Wiki-master:..
More informationAssignment X Light. Reflection and refraction of light. (a) Angle of incidence (b) Angle of reflection (c) principle axis
Assignment X Light Reflection of Light: Reflection and refraction of light. 1. What is light and define the duality of light? 2. Write five characteristics of light. 3. Explain the following terms (a)
More informationE X P E R I M E N T 12
E X P E R I M E N T 12 Mirrors and Lenses Produced by the Physics Staff at Collin College Copyright Collin College Physics Department. All Rights Reserved. University Physics II, Exp 12: Mirrors and Lenses
More informationKing Saud University College of Science Physics & Astronomy Dept.
King Saud University College of Science Physics & Astronomy Dept. PHYS 111 (GENERAL PHYSICS 2) CHAPTER 36: Image Formation LECTURE NO. 9 Presented by Nouf Saad Alkathran 36.1 Images Formed by Flat Mirrors
More informationLenses. A transparent object used to change the path of light Examples: Human eye Eye glasses Camera Microscope Telescope
SNC2D Lenses A transparent object used to change the path of light Examples: Human eye Eye glasses Camera Microscope Telescope Reading stones used by monks, nuns, and scholars ~1000 C.E. Lenses THERE ARE
More informationCHAPTER 3LENSES. 1.1 Basics. Convex Lens. Concave Lens. 1 Introduction to convex and concave lenses. Shape: Shape: Symbol: Symbol:
CHAPTER 3LENSES 1 Introduction to convex and concave lenses 1.1 Basics Convex Lens Shape: Concave Lens Shape: Symbol: Symbol: Effect to parallel rays: Effect to parallel rays: Explanation: Explanation:
More informationO5: Lenses and the refractor telescope
O5. 1 O5: Lenses and the refractor telescope Introduction In this experiment, you will study converging lenses and the lens equation. You will make several measurements of the focal length of lenses and
More informationChapter 23. Mirrors and Lenses
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 The image distance is the distance from the image to
More informationNotation for Mirrors and Lenses. Chapter 23. Types of Images for Mirrors and Lenses. More About Images
Notation for Mirrors and Lenses Chapter 23 Mirrors and Lenses Sections: 4, 6 Problems:, 8, 2, 25, 27, 32 The object distance is the distance from the object to the mirror or lens Denoted by p The image
More informationCh 24. Geometric Optics
text concept Ch 24. Geometric Optics Fig. 24 3 A point source of light P and its image P, in a plane mirror. Angle of incidence =angle of reflection. text. Fig. 24 4 The blue dashed line through object
More informationLECTURE 17 MIRRORS AND THIN LENS EQUATION
LECTURE 17 MIRRORS AND THIN LENS EQUATION 18.6 Image formation with spherical mirrors Concave mirrors Convex mirrors 18.7 The thin-lens equation Sign conventions for lenses and mirrors Spherical mirrors
More informationSpherical Mirrors. Concave Mirror, Notation. Spherical Aberration. Image Formed by a Concave Mirror. Image Formed by a Concave Mirror 4/11/2014
Notation for Mirrors and Lenses Chapter 23 Mirrors and Lenses The object distance is the distance from the object to the mirror or lens Denoted by p The image distance is the distance from the image to
More informationPhysics 132: Lecture Fundamentals of Physics
Physics 132: Lecture Fundamentals of Physics II Agenda for Today Mirrors Concave Convex e Mirror equation Physics 201: Lecture 1, Pg 1 Curved mirrors A Spherical Mirror: section of a sphere. R light ray
More informationChapter 2 - Geometric Optics
David J. Starling Penn State Hazleton PHYS 214 The human eye is a visual system that collects light and forms an image on the retina. The human eye is a visual system that collects light and forms an image
More informationRefraction is the when a ray changes mediums. Examples of mediums:
Refraction and Lenses Refraction is the when a ray changes mediums. Examples of mediums: Lenses are optical devices which take advantage of the refraction of light to 1. produces images real and 2. change
More informationLight: Lenses and. Mirrors. Test Date: Name 1ÿ-ÿ. Physics. Light: Lenses and Mirrors
Name 1ÿ-ÿ Physics Light: Lenses and Mirrors i Test Date: "Shadows cannot see themselves in the mirror of the sun." -Evita Peron What are lenses? Lenses are made from transparent glass or plastice and refract
More informationName. Light Chapter Summary Cont d. Refraction
Page 1 of 17 Physics Week 12(Sem. 2) Name Light Chapter Summary Cont d with a smaller index of refraction to a material with a larger index of refraction, the light refracts towards the normal line. Also,
More informationPHYSICS 289 Experiment 8 Fall Geometric Optics II Thin Lenses
PHYSICS 289 Experiment 8 Fall 2005 Geometric Optics II Thin Lenses Please look at the chapter on lenses in your text before this lab experiment. Please submit a short lab report which includes answers
More informationThin Lenses. Physics 227 Lab. Introduction:
Introduction: From last week's lab, Reflection and Refraction, you should already be familiar with the following terms: principle axis, focal point, focal length,f, converging lens (f is +), and diverging
More informationPhysics 2310 Lab #6: Multiple Thin Lenses Dr. Michael Pierce (Univ. of Wyoming)
Physics 2310 Lab #6: Multiple Thin Lenses Dr. Michael Pierce (Univ. of Wyoming) Purpose: The purpose of this lab is to investigate the properties of multiple thin lenses. The primary goals are to understand
More informationEXPERIMENT 10 Thin Lenses
Objectives ) Measure the power and focal length of a converging lens. ) Measure the power and focal length of a diverging lens. EXPERIMENT 0 Thin Lenses Apparatus A two meter optical bench, a meter stick,
More informationRefraction and Lenses
Refraction and Lenses Name Q.(a) Figure shows a ray of light entering a glass block. (i) The angle of incidence in Figure is labelled with the letter i. On Figure, use the letter r to label the angle of
More information2010 Catherine H. Crouch. Lab I - 1
The following laboratories were developed by Catherine Crouch at Swarthmore College for Physics 4L (Electricity, Magnetism, and Optics with Biomedical Applications) drawing on problem-solving laboratories
More informationTest Review # 8. Physics R: Form TR8.17A. Primary colors of light
Physics R: Form TR8.17A TEST 8 REVIEW Name Date Period Test Review # 8 Light and Color. Color comes from light, an electromagnetic wave that travels in straight lines in all directions from a light source
More informationConverging and Diverging Surfaces. Lenses. Converging Surface
Lenses Sandy Skoglund 2 Converging and Diverging s AIR Converging If the surface is convex, it is a converging surface in the sense that the parallel rays bend toward each other after passing through the
More informationLenses. Optional Reading Stargazer: the life and times of the TELESCOPE, Fred Watson (Da Capo 2004).
Lenses Equipment optical bench, incandescent light source, laser, No 13 Wratten filter, 3 lens holders, cross arrow, diffuser, white screen, case of lenses etc., vernier calipers, 30 cm ruler, meter stick
More informationPhysics II. Chapter 23. Spring 2018
Physics II Chapter 23 Spring 2018 IMPORTANT: Except for multiple-choice questions, you will receive no credit if you show only an answer, even if the answer is correct. Always show in the space on your
More informationGeneral Physics II. Ray Optics
General Physics II Ray Optics 1 Dispersion White light is a combination of all the wavelengths of the visible part of the electromagnetic spectrum. Red light has the longest wavelengths and violet light
More informationPhysics Learning Guide Name:
Physics Learning Guide Name: Instructions: Using a pencil, complete the following notes as you work through the related lessons. Show ALL work as is explained in the lessons. You are required to have this
More informationChapter 23. Mirrors and Lenses
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 The image distance is the distance from the image to
More informationReadings: Hecht, Chapter 24
5. GEOMETRIC OPTICS Readings: Hecht, Chapter 24 Introduction In this lab you will measure the index of refraction of glass using Snell s Law, study the application of the laws of geometric optics to systems
More informationChapter 23. Mirrors and Lenses
Chapter 23 Mirrors and Lenses Mirrors and Lenses The development of mirrors and lenses aided the progress of science. It led to the microscopes and telescopes. Allowed the study of objects from microbes
More informationLENSES. a. To study the nature of image formed by spherical lenses. b. To study the defects of spherical lenses.
Purpose Theory LENSES a. To study the nature of image formed by spherical lenses. b. To study the defects of spherical lenses. formation by thin spherical lenses s are formed by lenses because of the refraction
More informationGeometric Optics. PSI AP Physics 2. Multiple-Choice
Geometric Optics PSI AP Physics 2 Name Multiple-Choice 1. When an object is placed in front of a plane mirror the image is: (A) Upright, magnified and real (B) Upright, the same size and virtual (C) Inverted,
More informationCHAPTER 18 REFRACTION & LENSES
Physics Approximate Timeline Students are expected to keep up with class work when absent. CHAPTER 18 REFRACTION & LENSES Day Plans for the day Assignments for the day 1 18.1 Refraction of Light o Snell
More informationChapter 29/30. Wave Fronts and Rays. Refraction of Sound. Dispersion in a Prism. Index of Refraction. Refraction and Lenses
Chapter 29/30 Refraction and Lenses Refraction Refraction the bending of waves as they pass from one medium into another. Caused by a change in the average speed of light. Analogy A car that drives off
More informationBHARATIYA VIDYA BHAVAN S V M PUBLIC SCHOOL, VADODARA QUESTION BANK
BHARATIYA VIDYA BHAVAN S V M PUBLIC SCHOOL, VADODARA QUESTION BANK Ch Light : Reflection and Refraction One mark questions Q1 Q3 What happens when a ray of light falls normally on the surface of a plane
More informationPhysics 222, October 25
Physics 222, October 25 Key Concepts: Image formation by refraction Thin lenses The eye Optical instruments A single flat interface Images can be formed by refraction, when light traverses a boundary between
More informationSnell s Law, Lenses, and Optical Instruments
Physics 4 Laboratory Snell s Law, Lenses, and Optical Instruments Prelab Exercise Please read the Procedure section and try to understand the physics involved and how the experimental procedure works.
More informationCH. 23 Mirrors and Lenses HW# 6, 7, 9, 11, 13, 21, 25, 31, 33, 35
CH. 23 Mirrors and Lenses HW# 6, 7, 9, 11, 13, 21, 25, 31, 33, 35 Mirrors Rays of light reflect off of mirrors, and where the reflected rays either intersect or appear to originate from, will be the location
More informationMirrors and Lenses. Images can be formed by reflection from mirrors. Images can be formed by refraction through lenses.
Mirrors and Lenses Images can be formed by reflection from mirrors. Images can be formed by refraction through lenses. Notation for Mirrors and Lenses The object distance is the distance from the object
More informationTable of Contents DSM II. Lenses and Mirrors (Grades 5 6) Place your order by calling us toll-free
DSM II Lenses and Mirrors (Grades 5 6) Table of Contents Actual page size: 8.5" x 11" Philosophy and Structure Overview 1 Overview Chart 2 Materials List 3 Schedule of Activities 4 Preparing for the Activities
More informationChapter 24 Geometrical Optics. Copyright 2010 Pearson Education, Inc.
Chapter 24 Geometrical Optics Lenses convex (converging) concave (diverging) Mirrors Ray Tracing for Mirrors We use three principal rays in finding the image produced by a curved mirror. The parallel ray
More informationLight sources can be natural or artificial (man-made)
Light The Sun is our major source of light Light sources can be natural or artificial (man-made) People and insects do not see the same type of light - people see visible light - insects see ultraviolet
More informationLight and Applications of Optics
UNIT 4 Light and Applications of Optics Topic 4.1: What is light and how is it produced? Topic 4.6: What are lenses and what are some of their applications? Topic 4.2 : How does light interact with objects
More informationImage Formation by Lenses
Image Formation by Lenses Bởi: OpenStaxCollege Lenses are found in a huge array of optical instruments, ranging from a simple magnifying glass to the eye to a camera s zoom lens. In this section, we will
More informationWAVES: REFLECTION QUESTIONS
WAVES: REFLECTION QUESTIONS Concave and convex mirrors (2017;1) Sarah placed a candle in front of a concave mirror. Draw two rays from the candle (object) to locate the position of the image. Draw and
More informationOptics: Lenses & Mirrors
Warm-Up 1. A light ray is passing through water (n=1.33) towards the boundary with a transparent solid at an angle of 56.4. The light refracts into the solid at an angle of refraction of 42.1. Determine
More informationPhysics 132: Lecture Fundamentals of Physics II
Physics 132: Lecture Fundamentals of Physics II Mirrors Agenda for Today Concave Convex Mirror equation Curved mirrors A Spherical Mirror: section of a sphere. R light ray C Concave mirror principal axis
More informationIntroduction. The Human Eye. Physics 1CL OPTICAL INSTRUMENTS AND THE EYE SPRING 2010
Introduction Most of the subject material in this lab can be found in Chapter 25 of Serway and Faughn. In this lab, you will make images of images using lenses and the optical bench (Experiment A). IT
More informationalways positive for virtual image
Point to be remembered: sign convention for Spherical mirror Object height, h = always positive Always +ve for virtual image Image height h = Always ve for real image. Object distance from pole (u) = always
More information2015 EdExcel A Level Physics EdExcel A Level Physics. Lenses
2015 EdExcel A Level Physics 2015 EdExcel A Level Physics Topic Topic 5 5 Lenses Types of lenses Converging lens bi-convex has two convex surfaces Diverging lens bi-concave has two concave surfaces Thin
More informationGeometric Optics. This equation is known as the mirror equation or the thin lens equation, depending on the setup.
Geometric Optics Purpose (Write the purposes at the beginning of each problem.) Problem 1: find the focal length of a concave mirror to verify the mirror equation; Problem 2: find the focal length of a
More informationGeometric Optics. Find the focal lengths of lenses and mirrors; Draw and understand ray diagrams; and Build a simple telescope
Geometric Optics I. OBJECTIVES Galileo is known for his many wondrous astronomical discoveries. Many of these discoveries shook the foundations of Astronomy and forced scientists and philosophers alike
More informationWhere should the fisherman aim? The fish is not moving.
Where should the fisherman aim? The fish is not moving. When a wave hits a boundary it can Reflect Refract Reflect and Refract Be Absorbed Refraction The change in speed and direction of a wave Due to
More informationPHYS:1200 LECTURE 31 LIGHT AND OPTICS (3)
1 PHYS:1200 LECTURE 31 LIGHT AND OPTICS (3) In lecture 30, we applied the law of reflection to understand how images are formed using plane and curved mirrors. In this lecture we will use the law of refraction
More informationFocal Length of Lenses
Focal Length of Lenses OBJECTIVES Investigate the properties of converging and diverging lenses. Determine the focal length of converging lenses both by a real image of a distant object and by finite object
More informationPhysics 228 Lecture 3. Today: Spherical Mirrors Lenses.
Physics 228 Lecture 3 Today: Spherical Mirrors Lenses www.physics.rutgers.edu/ugrad/228 a) Santa as he sees himself in a mirrored sphere. b) Santa as he sees himself in a flat mirror after too much eggnog.
More informationMirrors, Lenses &Imaging Systems
Mirrors, Lenses &Imaging Systems We describe the path of light as straight-line rays And light rays from a very distant point arrive parallel 145 Phys 24.1 Mirrors Standing away from a plane mirror shows
More information13. Optical Instruments*
13. Optical Instruments* Objective: Here what you have been learning about thin lenses is applied to make a telescope. In the process you encounter general optical instrument design concepts. The learning
More informationREFLECTION THROUGH LENS
REFLECTION THROUGH LENS A lens is a piece of transparent optical material with one or two curved surfaces to refract light rays. It may converge or diverge light rays to form an image. Lenses are mostly
More informationPhysics 1411 Telescopes Lab
Name: Section: Partners: Physics 1411 Telescopes Lab Refracting and Reflecting telescopes are the two most common types of telescopes you will find. Each of these can be mounted on either an equatorial
More informationPhysics 2020 Lab 8 Lenses
Physics 2020 Lab 8 Lenses Name Section Introduction. In this lab, you will study converging lenses. There are a number of different types of converging lenses, but all of them are thicker in the middle
More informationAcademic Year: 2017/2018 Term 3 Physics - Grade 10 Revision sheet Chapter 13: section 1,2,3 / Chapter 14: section 1 pages: ( ),( )
Academic Year: 2017/2018 Term 3 Physics - Grade 10 Revision sheet Chapter 13: section 1,2,3 / Chapter 14: section 1 pages: (442-462),(482-487) Spherical curved mirrors : a mirror that has the shape of
More informationSCIENCE 8 WORKBOOK Chapter 6 Human Vision Ms. Jamieson 2018 This workbook belongs to:
SCIENCE 8 WORKBOOK Chapter 6 Human Vision Ms. Jamieson 2018 This workbook belongs to: Eric Hamber Secondary 5025 Willow Street Vancouver, BC Table of Contents A. Chapter 6.1 Parts of the eye.. Parts of
More informationPhysics 2310 Lab #5: Thin Lenses and Concave Mirrors Dr. Michael Pierce (Univ. of Wyoming)
Physics 2310 Lab #5: Thin Lenses and Concave Mirrors Dr. Michael Pierce (Univ. of Wyoming) Purpose: The purpose of this lab is to introduce students to some of the properties of thin lenses and mirrors.
More informationINSIDE LAB 6: The Properties of Lenses and Telescopes
INSIDE LAB 6: The Properties of Lenses and Telescopes OBJECTIVE: To construct a simple refracting telescope and to measure some of its properties. DISCUSSION: In tonight s lab we will build a simple telescope
More informationPhysics 142 Lenses and Mirrors Page 1. Lenses and Mirrors. Now for the sequence of events, in no particular order. Dan Rather
Physics 142 Lenses and Mirrors Page 1 Lenses and Mirrors Now or the sequence o events, in no particular order. Dan Rather Overview: making use o the laws o relection and reraction We will now study ormation
More informationCh. 18 Notes 3/28/16
Section 1 Light & Color: Vocabulary Transparent material: transmits most of the light that strikes it. Light passes through without being scattered, so you can see clearly what is on the other side. Ex.
More information