Quest Chapter 30. Same hint as in #1. Consider the shapes of lenses that make them converge or diverge.

Similar documents
Light, Photons, and MRI

General Physics II. Mirrors & Lenses

Algebra Based Physics

M = h' h = #i. n = c v

Welcome to: Physics I. I m Dr Alex Pettitt, and I ll be your guide!

LIGHT. Speed of light Law of Reflection Refraction Snell s Law Mirrors Lenses

Light and Lenses Notes

Ray Diagrams. Ray Diagrams Used for determining location, size, orientation, and type of image

LIGHT & OPTICS. Fundamentals of Physics 2112 Chapter 34 1

Dispersion (23.5) Neil Alberding (SFU Physics) Physics 121: Optics, Electricity & Magnetism Spring / 17

Chapter 33 Continued Properties of Light. Law of Reflection Law of Refraction or Snell s Law Chromatic Dispersion Brewsters Angle

GEOMETRIC OPTICS. LENSES refract light, so we need to know how light bends when entering and exiting a lens and how that interaction forms an image.

Reflection and Refraction. Geometrical Optics

Today s Topic: Ray Diagrams Intro to & Converging

1. What is the law of reflection?

LECTURE 17 MIRRORS AND THIN LENS EQUATION. Instructor: Kazumi Tolich

Optics Course (Phys 311) Geometrical Optics Refraction through Lenses

AP Physics: Curved Mirrors and Lenses

PSC20 - Properties of Waves 3

Homework Set 3 Due Thursday, 07/14

Essential Physics I. Lecture 13:

Physics 1C Lecture 26A. Beginning of Chapter 26

Optics Homework. Assignment #2. Assignment #1. Textbook: Read Section 23-1 and 23-2

Review Session 1. Dr. Flera Rizatdinova

3. Confirm Does the law of reflection apply to rough surfaces? Explain. Diffuse Reflection

Chapter 11 Mirrors and Lenses KEY

Refraction and Lenses. Honors Physics

Chapter 3: Mirrors and Lenses

Physics 102: Lecture 17 Reflection and Refraction of Light

PHYSICS. Chapter 34 Lecture FOR SCIENTISTS AND ENGINEERS A STRATEGIC APPROACH 4/E RANDALL D. KNIGHT

Lenses. Learning Objectives: Explain how light travels through convex and concave lenses Explain why light is refracted

index of refraction-light speed

Chapter 5 Mirror and Lenses

Ray Optics. Physics 11. Sources of Light Rays: Self-Luminous Objects. The Ray Model of Light

Chapter 7: Geometrical Optics. The branch of physics which studies the properties of light using the ray model of light.

Draw a diagram showing the fibre and the path of the ray of light. Describe one use of optical fibres in medicine. You may draw a diagram.

Refraction Section 1. Preview. Section 1 Refraction. Section 2 Thin Lenses. Section 3 Optical Phenomena. Houghton Mifflin Harcourt Publishing Company

When light strikes an object there are different ways it can be affected. Light can be

Figure 27a3See Answer T5. A convex lens used as a magnifying glass.

Physics 1C. Lecture 23A. "If Dracula can t see his reflection in the mirror, how come his hair is always so neatly combed?

3. For an incoming ray of light vacuum wavelength 589 nm, fill in the unknown values in the following table.

LIGHT CLASS X STUDY MATERIAL & QUESTION BANK:

Light travels in straight lines, this is referred to as... this means that light does not bend...

Light and Mirrors MIRRORS

Chapter 12 Notes: Optics

4. Refraction. glass, air, Perspex and water.

Chapter 26 Geometrical Optics

Name: Chapter 14 Light. Class: Date: 143 minutes. Time: 143 marks. Marks: Comments: Page 1 of 53

Physics 102: Lecture 17 Reflection and Refraction of Light

Ch. 26: Geometrical Optics

AP* Optics Free Response Questions

Recap: Refraction. Amount of bending depends on: - angle of incidence - refractive index of medium. (n 2 > n 1 ) n 2

Science 8 Chapter 5 Section 1

Ray Optics. Ray model Reflection Refraction, total internal reflection Color dispersion Lenses Image formation Magnification Spherical mirrors

Today s Topic: Refraction / Snell s Law

Textbook Reference: Glencoe Physics: Chapters 16-18

In order to get the G.C.S.E. grade you are capable of, you must make your own revision notes using your Physics notebook.

Thin Lenses 4/16/2018 1

Physics 1230 Light and Color Fall 2012 M. Goldman. Practice Exam #1 Tuesday, Sept 25, Your full name: Last First and middle.

Unit 11 Light and Optics Holt Chapter 14 Student Outline Light and Refraction

Chapter 18 Ray Optics

Light Refraction. 7. For the three situations below, draw a normal line and measure and record the angles of incidence and the angles of refraction.

Stevens High School AP Physics II Work for Not-school

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

Light: Geometric Optics

Chapter 5 Mirrors and Lenses

AP Physics 2: Algebra-Based

Assuming: f = 10 cm C = 20 cm p = 12 cm q = 60 cm h = 5 cm h = - 25 cm M = -5

Thin Lenses. Lecture 23. Chapter 34. Ray Optics. Physics II. Course website:

Chapter 26 Geometrical Optics

Light: Geometric Optics

Physics 11 Chapter 18: Ray Optics

Outline The Refraction of Light Forming Images with a Plane Mirror 26-3 Spherical Mirror 26-4 Ray Tracing and the Mirror Equation

What is it? How does it work? How do we use it?

normal: a line drawn perpendicular (90 ) from the point of incidence of the reflecting surface

Which row could be correct for the colours seen at X, at Y and at Z?

P H Y L A B 1 : G E O M E T R I C O P T I C S

LECTURE 25 Spherical Refracting Surfaces. Geometric Optics

The Lens. Refraction and The Lens. Figure 1a:

On Fig. 7.1, draw a ray diagram to show the formation of this image.

Geometrical Optics. 1 st year physics laboratories. University of Ottawa

Section 2 Flat Mirrors. Distinguish between specular and diffuse reflection of light. Apply the law of reflection for flat mirrors.

2/26/2016. Chapter 23 Ray Optics. Chapter 23 Preview. Chapter 23 Preview

3. LENSES & PRISM

Light: Geometric Optics (Chapter 23)

Light and Optics Learning Goals Review

OPTICS: Solutions to higher level questions

Wave Properties. Page 1 of 13

Chapter 23. Images and Mirrors 3/23/11. Mirrors and Lenses QUESTIONS? PLEASE ASK! Types of Images for Mirrors and Lenses.

Chapter 26 Geometrical Optics

34.2: Two Types of Image

normal angle of incidence increases special angle no light is reflected

2t = (m+ 1 /2) λ = (m+ 1 /2)(λ/n); min, m = 0, 1, 2,... n1 < n2 < n3 2t = m λ = m(λ/n); min, m = 0, 1, 2,... n1 < n2 > n3

A concave mirror is a converging mirror because parallel rays will. A convex mirror is a diverging mirror because parallel rays will

Physics 123 Optics Review

Physics 9 Wednesday, February 17, 2016

Reflection and Image Formation by Mirrors

Physics 1202: Lecture 18 Today s Agenda

Refraction of Light. This bending of the ray is called refraction

Chapter 5: Mirrors and Lenses. 5.1 Ray Model of Light

Transcription:

1 Consider the light rays depicted in the figure. 1. diverging mirror 2. plane mirror 3. converging mirror 4. converging lens 5. diverging lens 6. Unable to determine. 2 Consider the light rays depicted in the figure. 1. converging lens 2. diverging mirror 3. diverging lens 4. converging mirror 5. plane mirror 6. Unable to determine. 3 Consider the light rays depicted in the figure. 1. converging lens 2. plane mirror 3. diverging lens 4. converging mirror 5. Unable to determine. 6. diverging mirror 4 Which of the glass lenses above, when placed in air, will cause rays of light (parallel to the central axis) to converge? 1. Z, R, and Y 2. H and G 3. Z, H, Y, and B 4. Z, Y, and B 5. Z, G, and B 6. H and Y 7. Z, H, and G 8. Z, R, and G 9. Z, H, R, and B 10. R and Y Quest Chapter 30 Look at the behavior of the rays not only their direction. What would a mirror do? Bounce What would a lens do? Bend Are they coming together? Converge Are the splitting apart? Diverge Same hint as in #1. Same hint as in #1. Consider the shapes of lenses that make them converge or diverge.

5 Which of the glass lenses above, when placed in air, will cause rays of light (parallel to the central axis) to diverge? 1. H and F 2. N, Z, and B 3. N, W, H, and B 4. N, W, F, and B 5. W and Z 6. N, H, and F 7. N, F, and B 8. W and F 9. N, W, and Z 10. N, H, and Z 6 Poke a hole in a piece of cardboard and hold the cardboard in the sunlight. Note the image of the sun that is cast below. Try a square hole; what is the image of the sun? 1. round 2. triangular 3. hexagon 4. pentagon 5. square 7 An ordinary magnifying glass produces an image which is 1. virtual and erect 2. real and erect 3. virtual and inverted 4. real and inverted 5. none of these Same hint as #4. What shape would you expect? Do you have to move the lens backward? (Yes: Inverted; No: Erect) Does light come from the image location directly to your eye? (Yes: Real; No: Virtual)

8 An object is placed at a distance of 1.5 f from a converging lens of focal length f, as shown. What type of image is formed and what is the size relative to the object? 1. Virtual Same size Inverted 2. Real Larger Upright 3. Real Smaller Upright 4. Virtual Larger Inverted 5. Real Smaller Inverted 6. Real Larger Inverted 7. Virtual Smaller Upright 8. Virtual Same size Upright 9. Virtual Larger Upright 10. Virtual Smaller Inverted 9 A converging lens has a focal length of 36.7 cm. If the object is 62.7 cm from the lens, what is the image distance? Answer in units of cm. 10 If the object distance for a converging thin lens is more than twice the focal length of the lens, the image is 1. virtual and erect. 2. located inside the focal point. 3. located at a distance more than 2 f from the lens. 4. located at a distance between f and 2 f from the lens. 5. larger than the object. 11 A convex lens has a focal length of 4.5481 cm. The object distance is 5.71429 cm. Find the image distance. Answer in units of cm. f is the focal distance. Draw the ray diagram. Use an arrow sitting on the principal axis. Two sets of rays. First: From the tip parallel to PA to the center of the lens then through the next focal point and beyond. Second: From the tip through the first focal point to the center of the lens then parallel until it meets the first set of rays. Substitute and solve. Beware of the fractions. Use the equation in #9. Use d o = 2.1f. Find d i. What will happen to d i as d o increases? Use the equation in #9. 12 Find the magnification. M = -d i / d o 13 Suppose you look out the window and see your friend, who is standing 28.3 m away. To what focal length must your eye muscles adjust the lens of your eye so that you may see your friend clearly? Remember that the distance from the front to the back of your eye is about 1.90 cm. Answer in units of cm.

14 The distance of the lens in the human eye from the retina, on which the image is focused, is about 1.7 cm. To focus on a book 52.4 cm from the eye, what must the focal length of the eye be? Answer in units of cm. 15 Compare a lens used to capture an image to the lens used to project that image back onto a screen for viewing. 1. Different types 2. Same types 16 Why is the image projected onto the back of the retina in your eyes upside down? 1. None of these 2. The focal length of the eye is very long. 3. The eye is a diverging lens. 4. The eye is a converging lens. 17 When your eyes are submerged in water, do light rays coming from water to your eyes bend more, less, or the same as in air? 1. The same 2. It depends on the speed of the water. 3. Less 4. More What do they have to do? What type of lenses do that? What type of lens inverts that way? The question is whether water-eye has more bending than air-eye. To figure this out, you have to compare the indices of refraction. Check out this site: http://hyperphysics.phyastr.gsu.edu/hbase/vision/eyescal.html How does the index of refraction for water (1.33) compare to the structures of the eye? How does that compare to air?

If the indices are close do they refract more or less? Check out Snells Law p451.

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