Presentation is loading. Please wait.

Presentation is loading. Please wait.

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.

Published byRobert Bennett Modified over 8 years ago

Similar presentations

Presentation on theme: "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."— Presentation transcript:

1 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 formed by refraction at spherical surfaces. Thin Lenses: Concave and Convex Lenses, Ray Diagrams, Solving the Lens Equation. You must understand the differences between these two kinds of lenses, be able to draw ray diagrams for both kinds of lenses, and be able to solve the lens equation for both kinds of lenses. Lens Combinations, Optical Instruments. You should be aware of this useful information, which will not be presented in lecture.

2 The Lensmaker’s Equation s s s’

3 Sign Conventions for The Lens Equation The object distance s is positive if the object is on the side of the lens from which the light is coming; otherwise s is negative. The image distance s’ is positive if the image is on the opposite side of the lens from where the light is coming; otherwise s’ is negative. (If s’ is negative, is the image real?) The focal length f is positive for converging lenses and negative for diverging lenses. The image height y’ is positive if the image is upright and negative if the image is inverted relative to the object.

4 Example: an object is located 5 cm in front of a converging lens of 10 cm focal length. Find the image distance and magnification. Is the image real or virtual? O FF’ Image distance is 10 cm, image is on side of lens light is coming from, so image is virtual. M=2 so image is upright. It’s just a coincidence that the image is located at F’.

Download ppt "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."

Similar presentations

Chapter 23:Mirrors and Lenses Flat Mirrors Homework assignment : 20,24,42,45,51  Image of a point source P P’ The reflected rays entering eyes look as.

Chapter 23:Mirrors and Lenses Flat Mirrors Homework assignment : 20,24,42,45,51  Image of a point source P P’ The reflected rays entering eyes look as.
Lenses. Transparent material is capable of causing parallel rays to either converge or diverge depending upon its shape.

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

Convex and Concave Lenses
Geometric Optics Chapter 27. 23.7 Thin Lenses; Ray Tracing Parallel rays are brought to a focus by a converging lens (one that is thicker in the center.

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.
→ ℎ

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

Light and Optics Mirrors and Lenses. Types of Mirrors Concave mirrors – curve inward and may produce real or virtual images. Convex mirrors – curve outward.
Week 3.

Week 3.
(10.3/10.4) Mirror and Magnification Equations (12.2) Thin Lens and Magnification Equations.

(10.3/10.4) Mirror and Magnification Equations (12.2) Thin Lens and Magnification Equations.
Physics 1C Lecture 26C. Recap from last lecture Optical characteristics of lens are defined by focal length f: For a given f, imaging properties are given.

Physics 1C Lecture 26C. Recap from last lecture Optical characteristics of lens are defined by focal length f: For a given f, imaging properties are given.
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 34: Thin Lenses 1 Now consider refraction through this piece of glass: optic axis This is called a “Double Convex Lens” converging light focal.
Ch. 18 Mirrors and Lenses Milbank High School. Sec. 18.1 Mirrors Objectives –Explain how concave, convex, and plane mirrors form images. –Locate images.

Ch. 18 Mirrors and Lenses Milbank High School. Sec Mirrors Objectives –Explain how concave, convex, and plane mirrors form images. –Locate images.
Chapter 36 Image Formation. Summary: mirrors Sign conventions: + on the left - on the right Convex and plane mirrors: only virtual images (for real objects)

Chapter 36 Image Formation. Summary: mirrors Sign conventions: + on the left - on the right Convex and plane mirrors: only virtual images (for real objects)
PH 103 Dr. Cecilia Vogel Lecture 5. Review  Refraction  Total internal reflection  Dispersion  prisms and rainbows Outline  Lenses  types  focal.

PH 103 Dr. Cecilia Vogel Lecture 5. Review  Refraction  Total internal reflection  Dispersion  prisms and rainbows Outline  Lenses  types  focal.
26.6 Lenses. Converging Lens Focal length of a converging lens is real and considered positive.

26.6 Lenses. Converging Lens Focal length of a converging lens is real and considered positive.
PH 103 Dr. Cecilia Vogel Lecture 6 NO QUIZDOM TODAY.

PH 103 Dr. Cecilia Vogel Lecture 6 NO QUIZDOM TODAY.
Copyright © 2009 Pearson Education, Inc. Lecture 2 – Geometrical Optics b) Thin Lenses.

Copyright © 2009 Pearson Education, Inc. Lecture 2 – Geometrical Optics b) Thin Lenses.
PHY 1371Dr. Jie Zou1 Chapter 36 Image Formation (Cont.)

PHY 1371Dr. Jie Zou1 Chapter 36 Image Formation (Cont.)
Geometric Optics Ray Model assume light travels in straight line

Geometric Optics Ray Model assume light travels in straight line
Thin Lenses If the thickness of the lens is small compared to the object and image distances we can neglect the thickness (t) of the lens. All thin lenses.

Thin Lenses If the thickness of the lens is small compared to the object and image distances we can neglect the thickness (t) of the lens. All thin lenses.
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.

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.

Similar presentations

Ads by Google