Week 3.

Slides:

Advertisements

Similar presentations

Option G2: Optical Instruments

Advertisements

PHYSICS InClass by SSL Technologies with S. Lancione Exercise-53

Lenses, Mirrors & the Human Eye

Lenses. Transparent material is capable of causing parallel rays to either converge or diverge depending upon its shape.

Geometric Optics Chapter Thin Lenses; Ray Tracing Parallel rays are brought to a focus by a converging lens (one that is thicker in the center.

Q34.1 Which of the following changes its focal length when it is immersed in water? 1. a concave mirror 2. a convex mirror 3. a diverging lens 4. all of.

Light and Optics Mirrors and Lenses. Types of Mirrors Concave mirrors – curve inward and may produce real or virtual images. Convex mirrors – curve outward.

Mirrors and Lenses: Mirrors reflect the light Lenses refract the light.

J.M. Gabrielse. Outline Reflection Mirrors Plane mirrors Spherical mirrors Concave mirrors Convex mirrors Refraction Lenses Concave lenses Convex lenses.

(10.3/10.4) Mirror and Magnification Equations (12.2) Thin Lens and Magnification Equations.

and Optical Instruments

Chapter 34: Thin Lenses 1 Now consider refraction through this piece of glass: optic axis This is called a “Double Convex Lens” converging light focal.

Chapter 36 Image Formation. Summary: mirrors Sign conventions: + on the left - on the right Convex and plane mirrors: only virtual images (for real objects)

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

Lenses PreAP Physics. Critical Angle At a certain angle where no ray will emerge into the less dense medium. –For water it is 48  which does not allow.

Lenses Physics 202 Professor Lee Carkner Lecture 21.

Copyright © 2009 Pearson Education, Inc. Lecture 2 – Geometrical Optics b) Thin Lenses.

Lenses Physics 202 Professor Lee Carkner Lecture 23.

Refraction (bending light) Refraction is when light bends as it passes from one medium into another. When light traveling through air passes into the glass.

Goal: To understand how mirrors and lenses work

Convex Lens A convex lens curves outward; it has a thick center and thinner edges.

Mirror equation How can we use ray diagrams to determine where to place mirrors in a telescope/ We need to know where the image will be formed, so that.

Magnifications in Mirrors & Lenses.  A measure of how much larger or smaller an image is compared with the object itself. Magnification = image height.

A. can be focused on a screen. B. can be projected on a wall.

Ch18.1 Mirrors Concave mirror All light rays that come in parallel to the optical axis, reflect thru the focal point. All light rays that come in thru.

Textbook sections 26-3 & 26-4 Physics 1161: Lecture 21 Curved Mirrors.

 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.

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

Images formed by lenses. Convex (converging) lenses, f>0.

Mirror and Magnification Equations

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.

ReflectionReflection and Mirrors The Law of Reflection always applies: “The angle of reflection is equal to the angle of incidence.”

Predicting Images in Convex and Concave Lenses. When the object is located at twice the focal length (2F)

Lenses – Application of Refraction AP Physics B. Lenses – An application of refraction There are 2 basic types of lenses A converging lens (Convex) takes.

1 32 Optical Images image formation reflection & refraction mirror & lens equations Human eye Spherical aberration Chromatic aberration.

Virtual Focal Point Concave Thin Lens Diverging Lens.

Unit 3 – Light & Optics. v  There are five (5) different situations, depending on where the object is located.

Thin Lens Optics Physics 11. Thin Lens Optics If we have a lens that has a small diameter when compared to the focal length, we can use geometrical optics.

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.

Ray Diagrams for Lenses. Convex (Converging) Lenses There are two Focal points One in Front and one Behind Focal point is ½ way between Center of Curvature.

The Thin Lens Equation. Let’s us predict mathematically the properties of an image produced by a lens.

Unit 3: Light.  Symbols used: ◦ Ho- height of the object ◦ Hi- height of the image ◦ m-magnification ◦ do (or p)- distance between object and vertex.

Dispersion The spreading of light into its color components is called dispersion. When light enters a prism, the refracted ray is bent towards the normal,

Lenses Convex lenses converge rays of light. Parallel rays converge a fixed distance away from the lens. This is known as the focal length.

Image Formation. Flat Mirrors  p is called the object distance  q is called the image distance  θ 1 = θ 2 Virtual Image: formed when light rays do.

Mirrors.  Recall: images formed by curved mirrors depend on position of image  Images could be: Real or virtual Upright or inverted Smaller or larger.

Mirrors. Types of mirror There are two types of mirror Plane (flat) Curved Concave (curves in) Convex (curves out)

Geometric Optics: Mirrors and Lenses. Mirrors with convex and concave spherical surfaces. Note that θ r = θ i for each ray.

Chapter 33 Lenses and Optical Instruments The Thin Lens Equation; Magnification Example 33-2: Image formed by converging lens. What are (a) the.

How Does a Lens Work? Light travels slower in the lens material than in the air around it. This means a linear light wave will be bent by the lens due.

Thin Lenses. Two Types of Lenses Converging – Thicker in the middle than on the edges FOCAL LENGTH (+) POSITIVE Produces both real and virtual images.

Q34.1 Which of the following changes its focal length when it is immersed in water? A. a concave mirror B. a convex mirror C. a diverging lens D. all of.

Mirror Equations Lesson 4.

Given: M = -5 di = 12 feet do =? f = ?

13.4 The Lens Equation.

Thin Lenses-Intro Notes

Refraction at Spherical Surfaces.

Unit 8, Lesson 7 Convex Lenses.

Geometrical Optics Seminar add-on Ing. Jaroslav Jíra, CSc.

Convex Lenses Thicker in the center than edges.

Converging lens.

Chapter 13 Light and Reflection

Equations with Lenses SNC2D.

Summary of Sign Conventions

Lens Equations.

Mirrors Physics Mr. Berman.

Thin Lens Equation 1

Lens Equation Word Problems

Lens Cases CONVERGING 2f f f’ 2f’ – object beyond 2f

Presentation transcript:

Week 3

What is the image position? What is the image height? A 3.0 cm tall object is 45 cm in front of a concave mirror that has a focal length of 25 cm. What is the image position? What is the image height? What is the magnification? Is this a real or virtual image? Week 3

What is the image position? What is the image height? A 3.0 cm tall object is 45 cm in front of a convex mirror that has a focal length of 25 cm. What is the image position? What is the image height? What is the magnification? Is this a real or virtual image? Week 3

Week 3

The human eye has a focal point, just like any other optical instrument Week 3

Week 3

Week 3

Is Maria near or far sighted? With her right eye, Maria can focus on a sign 0.5 m away but not on a tree 10 m away. Is Maria near or far sighted? What kind of lens does she need: converging or diverging? Which of the following could be the eyeglass prescription for her right eye? +3.0 D +10 D -5.0 D -1.5 D Week 3

Week 3

Week 3

Week 3

What is the location of the final image produced by this lens system? A compound lens system consists of two converging lenses, placed 40.0 cm apart. The first lens has a focal length of f1=+10.0 cm and the second has a focal length of f2=+8.0 cm. An object 1.0 cm tall is placed 30.0 cm in front of the first lens. What is the location of the final image produced by this lens system? How tall is the final image? Is the final image upright or inverted? Week 3