Image Formation by Lenses

Slides:

Advertisements

Similar presentations

Chapter 36 - Lenses A PowerPoint Presentation by

Advertisements

Option G2: Optical Instruments

Chapter 23 Mirrors and Lenses

Notation for Mirrors and Lenses

Mirror and Lens Properties. Image Properties/Characteristics Image Type: Real or Virtual Image Orientation: Erect or Inverted Image Size: Smaller, Larger,

Chapter 34B - Reflection and Mirrors II (Analytical)

Reflection and Mirrors Explain and discuss with diagrams, reflection, absorption, and refraction of light rays. Define and illustrate your understanding.

Created by Stephanie Ingle Kingwood High School

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

Convex and Concave Lenses

LENSES. LENSES A light ray bends as it enters glass and bends again as it leaves ◦This refraction is due to the difference in the average speed of light.

Flat Lens (Window) n1n1 n2n2 Incident ray is displaced, but its direction is not changed. tt 11 11 If  1 is not large, and if t is small, the.

Chapter 31 Images.

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

Chapter 23 Mirrors and Lenses.

Chapter 36 Image Formation.

Chapter 23 Mirrors and Lenses. Medical Physics General Physics Mirrors Sections 1–3.

Chapter 23 Mirrors and Lenses.

Geometrical Optics Mirrors and Thin 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.

Chapter 23 Mirrors and Lenses.

air water As light reaches the boundary between two media,

Lecture 25-1 Locating Images Real images form on the side of a mirror where the objects are, and virtual images form on the opposite side. only using the.

Lecture 23 Mirrors Lens.

Reflection and Refraction. Reflection  Reflection occurs when light bounces off a surface.  There are two types of reflection – Specular reflection.

Optics: Reflection, Refraction Mirrors and Lenses

Chapter 23 Mirrors and Lenses.

Chapter 25. Mirrors and the Reflection of Light Our everyday experience that light travels in straight lines is the basis of the ray model of light. Ray.

LENS any transparent object having two nonparallel curved surfaces or one plane surface and one curved surface Converging Lenses - thicker in middle than.

Ray Diagrams Notes.

Reflection of Light Reflection and Refraction of Light Refraction of Light.

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

Thin Lenses 91 is the highest grade while 75 is the lowest grade. 91 is the highest grade while 75 is the lowest grade. Best Project ( Website and Reflection.

Chapter 23 Mirrors and Lenses.

Refraction of Light EM lesson 8.  Thicker in the center than at the edges  Have positive focal lengths  Converge parallel rays of light that pass through.

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.

Curved Mirrors and Ray Diagrams SNC2D. Concave Mirrors A concave mirror is a curved mirror with the reflecting surface on the inside of the curve. The.

Mirrors & Lenses Chapter 23 Chapter 23 Learning Goals Understand image formation by plane or spherical mirrors Understand image formation by converging.

Thin Lenses Chapter 15.

Mirrors and Lenses.

Image Formation. We will use geometrical optics: light propagates in straight lines until its direction is changed by reflection or refraction. When we.

Lenses and Mirrors. How does light interact with pinholes? How does light interact with lenses? –___________ How does light interact with 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.

Chapter 23 Mirrors and Lenses.

Mirrors & Reflection.

8. Thin lenses Thin lenses are those whose thickness is small compared to their radius of curvature. They may be either converging or diverging. 1) Types.

The Reflection of Light: Mirrors

Plane Mirror Suppose we had a flat , plane mirror mounted vertically. A candle is placed 10 cm in front of the mirror. WHERE IS THE IMAGE OF THE CANDLE.

Chapter 34 Lecture Seven: Images: I HW 3 (problems): 34.40, 34.43, 34.68, 35.2, 35.9, 35.16, 35.26, 35.40, Due Friday, Sept. 25.

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.

Chapter 36 Image Formation.

1 Thin Lens Light refracts on the interface of two media, following Snell’s law of refraction: Light bends through a triangular prism: θ 1 and θ 2 are.

Ray Diagrams Noadswood Science, 2013.

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.

Lab 9: Geometrical optics Only 3 more labs to go!! Today we are going to do three experiments: 1. Measure the intensity of light as a function of distance.

Explain and discuss with diagrams, reflection, absorption, and refraction of light rays.Explain and discuss with diagrams, reflection, absorption, and.

Lenses Lenses do all the same things mirrors do and use all the same terms and variables. Lenses do all the same things mirrors do and use all the same.

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.

Part 10 Optics --Mirrors and Lenses Chapter 24 Geometric Optics.

Reflection of Light Reflection – The bouncing back of a particle or wave that strikes the boundary between two media. Law of Reflection – The angle of.

Lenses © 2007.

Thin Lenses-Intro Notes

Lenses and Ray Diagrams.

Lenses and Ray Diagrams.

Part 3: Optics (Lenses and Mirrors)

Objectives: After completing this module, you should be able to:

Chapter 25 Reflection and Mirrors

Presentation transcript:

Image Formation by Lenses If a piece of glass or other transparent material takes on the appropriate shape, it will be capable of taking parallel rays of incident light and either converging them to a point or appear to diverge them from a point. Such a piece of glass is referred to as a lens.

Converging and Diverging Lens Properties of lenses are due to the refraction (bending) of light passing thru them according to the law of refraction. Convergent (Convex) Lenses—brings together rays of light which are traveling parallel to its principal axis. Divergent (Concave) Lenses—separates rays of light

Converging and Diverging Lens Converging Lens Diverging Lens Real focus Virtual focus Double-convex Double-concave

The Focal Length of Lenses Converging Lens Diverging Lens Focal length f F f - f + The focal length f is positive for a real focus (converging) and negative for a virtual focus.

The Principal Focus Since light can pass through a lens in either direction, there are two focal points for each lens. Left to right The principal focal point F is shown here. Yellow F is the other one. F Right to left Now suppose light moves from right to left instead . . . F F

Types of Converging Lenses In order for a lens to converge light it must be thicker near the midpoint to allow more bending. Plano-convex lens Double-convex lens Converging meniscus lens

Types of Diverging Lenses In order for a lens to diverge light, it must be thinner near the midpoint to allow more bending. Double-concave lens Plano-concave lens Diverging meniscus lens

Image Construction: Ray 1: A ray parallel to the lens axis passes through the far focus of a converging lens or appears to come from the near focus of a diverging lens. Converging Lens Diverging Lens Ray 1 Ray 1 F F

Image Construction: Ray 2: A ray passing through the near focal point of a converging lens or proceeding toward the far focal point of a diverging lens is refracted parallel to the lens axis. Converging Lens Diverging Lens F Ray 1 Ray 2 Ray 2

Image Construction: Ray 3: A ray passing through the center of any lens continues in a straight line. The refraction at the first surface is balanced by the refraction at the second surface. Converging Lens Diverging Lens F Ray 1 Ray 2 Ray 3 Ray 3

Images’ Tracing Points Draw an arrow to represent the location of an object, then draw any two of the rays from the tip of the arrow. The image is where lines cross. 1. Is the image erect or inverted? 2. Is the image real or virtual? Real images are always on the opposite side of the lens. Virtual images are on the same side. 3. Is it enlarged, diminished, or same size?

Object Outside 2F F 2F Real; inverted; diminished 1. The image is inverted; i.e., opposite to the object orientation. 2. The image is real; i.e., formed by actual light rays in front of mirror. 3. The image is diminished in size; i.e., smaller than the object. Image is located between F and 2F

Object at 2F F 2F Real; inverted; same size 1. The image is inverted; i.e., opposite to the object orientation. 2. The image is real; i.e., formed by actual light rays in front of the mirror. 3. The image is the same size as the object. Image is located at 2F on other side

Object Between 2F and F F 2F Real; inverted; enlarged 1. The image is inverted; i.e., opposite to the object orientation. 2. The image is real; formed by actual light rays on the opposite side 3. The image is enlarged in size; i.e., larger than the object. Image is located beyond 2F

Object at Focal Length F Parallel rays; no image formed When the object is located at the focal length, the rays of light are parallel. The lines never cross, and no image is formed.

Object Inside F F 2F Virtual; erect; enlarged 1. The image is erect; i.e., same orientation as the object. 2. The image is virtual; i.e., formed where light does NOT go. 3. The image is enlarged in size; i.e., larger than the object. Image is located on near side of lens

Review of Image Formations Parallel rays; no image formed F 2F Real; inverted; enlarged F 2F Real; inverted; same size Object Outside 2F Region F 2F Real; inverted; diminished F 2F Virtual; erect; enlarged

Diverging Lens Imaging All images formed by diverging lenses are erect, virtual, and diminished. Images get larger as object approaches. Diverging Lens F Diverging Lens F

Analytical Approach to Imaging F 2F p f q y -y’ Lens Equation: Magnification:

Working With Reciprocals: The lens equation can easily be solved by using the reciprocal button (1/x) on most calculators: Possible sequence for finding f on linear calculators: P q 1/x + = Finding f: Same with reverse notation calculators might be: Finding f: P q 1/x + Enter

Alternative Solutions It might be useful to solve the lens equation algebraically for each of the parameters: Be careful with substitution of signed numbers!

Example 3. A magnifying glass consists of a converging lens of focal length 25 cm. A bug is 8 mm long and placed 15 cm from the lens. What are the nature, size, and location of the image? F p = 15 cm; f = 25 cm q = -37.5 cm The fact that q is negative means that the image is virtual (on same side as object).

Example 3 Cont.) A magnifying glass consists of a converging lens of focal length 25 cm. A bug is 8 mm long and placed 15 cm from the lens. What is the size of the image? F p = 15 cm; q = -37.5 cm y y’ Y’ = +20 mm The fact that y’ is positive means that the image is erect. It is also larger than object.

Example 4: What is the magnification of a diverging lens (f = -20 cm) if the object is located 35 cm from the center of the lens? F First we find q . . . then M q = -12.7 cm M = +0.364

The principal focus is denoted by the red F. Summary A converging lens is one that refracts and converges parallel light to a real focus beyond the lens. It is thicker near the middle. F The principal focus is denoted by the red F. F A diverging lens is one that refracts and diverges parallel light which appears to come from a virtual focus in front of the lens.

Summary of Math Approach q y -y’ Lens Equation: Magnification:

Summary of Sign Convention 1. Object p and image q distances are positive for real and images negative for virtual images. 2. Image height y’ and magnifi-cation M are positive for erect negative for inverted images. 3. The focal length f and the radius of curvature R is positive for converging mirrors and negative for diverging mirrors.