Reflection of Light Reflection: the turning back of a wave after meeting the boundary of a medium Regular Reflection Types of Behaviors: transmitted absorbed.

Slides:

Advertisements

Similar presentations

Learning Outcome Draw a ray diagram to find the position, nature and size of the image produced by a concave and convex mirrors.

Advertisements

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

Section 3 Curved Mirrors

SPHERICAL MIRRORS Free powerpoints at

Physics 1161: Lecture 16 Introduction to Mirrors.

Optics. Spherical Mirrors Spherical mirror – a section of a sphere of radius R and with a center of curvature C R C Mirror.

Mirrors Law of Reflection The angle of incidence with respect to the normal is equal to the angle of reflection.

Physics Light: Geometric Optics 23.1 The Ray Model of Light 23.2 Reflection - Plane Mirror 23.3 Spherical Mirrors 23.5 Refraction - Snell’s law.

UNIT 8 Light and Optics.

Grab Bag Wave Vocabulary Mirrors Light, Mirror, and Lens Lenses

Reflection Light incident upon a boundary between

Curved Mirrors.

Curved Mirrors Chapter 13 Section 3. Mirror Terminology  Ccenter of curvature  Rradius of curvature.

air water As light reaches the boundary between two media,

Curved Mirrors.

Reflection and Mirrors Chapter 23 Lesson 2 Notes.

Mirrors Ch. 20. Mirrors Mirror – any smooth object that reflects light to form an image.

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

CH 14: MIRRORS & LENSES 14.1: Mirrors. I. Plane Mirrors  Flat, smooth mirror  Creates a virtual image: an image your brain perceives even though no.

Mirrors Physics 202 Professor Lee Carkner Lecture 22.

Chapter 11 Review Mirrors & Lenses. What is an angle of incidence? 2 The angle between an incident ray and the normal of an optical device. Category:

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.

Mirrors Physics 202 Professor Lee Carkner Lecture 22.

Convex Mirrors LG: I can describe the uses on convex mirrors and draw ray diagrams involving convex mirrors.

Goal: To understand how mirrors and lenses work

Optics Can you believe what you see?. Optics Reflection: Light is retransmitted from or “bounces off” an object.

Physics 1161: Lecture 16 Introduction to Mirrors.

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.

Curved Mirrors Sections 11.5 & 11.6.

Concave Mirrors A concave spherical mirror a mirror whose reflecting surface is a segment of the inside of a sphere. Concave mirrors are used to magnify.

Ch. 14 Light and Reflection. Flat Mirrors Simplest mirror Object’s image appears behind the mirror Object’s distance from the mirror is represented as.

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.

Spherical Mirrors Spherical mirror – a section of a sphere of radius R and with a center of curvature C R C Mirror.

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

Geometric Optics Conceptual Quiz 23.

Chapter 19 – Optics Jennie L. Borders.

Chapter 14 Light and Reflection

Physics 1C Lecture 26A.

Grade 10 Applied Science – Curved Mirrors

Ray Optics: Reflection and Refraction Rays Representation of the path that light follows Represent beams of light that are composed of millions.

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

Chapter 18-1 Mirrors. Plane Mirror a flat, smooth surface light is reflected by regular reflection rather than by diffuse reflection Light rays are reflected.

Reflection Regular reflection occurs when parallel light rays strike a smooth surface and reflect in the same direction. Diffuse reflection occurs when.

Light wave Recall: Light must reflect off of an object before it can be used to see the object. A flat mirror is called a plane mirror. A plane mirror.

1 2 Curved mirrors have the capability to create images that are larger or smaller than the object placed in front of them. They can also create images.

Characteristics & Ray Diagrams

Properties of Reflective Waves Curved Mirrors. Image close to a concave mirror appear:

Curved Mirrors Chapter 14, Section 3 Pg

Chapter 7 Light and Geometric Optics

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

Plane Mirror: a mirror with a flat surface

Reflection & Mirrors. Reflection The turning back of an electromagnetic wave (light ray) at the surface of a substance. The turning back of an electromagnetic.

Reflection of Light. Reflectance u Light passing through transparent medium is transmitted, absorbed, or scattered u When striking a media boundary, light.

Reflection Regular reflection occurs when parallel light rays strike a smooth surface and reflect in the same direction. Diffuse reflection occurs when.

Calculate distances and focal lengths using the mirror equation for concave and convex spherical mirrors. Draw ray diagrams to find the image distance.

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

Reflection Regular reflection occurs when parallel light rays strike a smooth surface and reflect in the same direction. Diffuse reflection occurs when.

Curved Mirrors. Images in Mirrors S ize, A ttitude, L ocation, T ype Size –Is the image bigger, smaller or the same size as the object? Attitude –Is the.

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

A light beam striking a boundary between two media can be partly transmitted and partly reflected at the boundary.

Light and Mirrors Part II MIRRORS 1. Polarized Sunglasses- How do they work? light waves vibrate in more than one plane light waves can be made to vibrate.

AP Phys 12 – Class Starter 1.Let’s start by reviewing a 2003 AP Question 2.Work in groups of 2-3 to answer the following question… 3.Grab a Whiteboard.

Images in Curved Mirrors

Spherical Mirrors.

Images formed by Mirrors

Part 3: Optics (Lenses and Mirrors)

Curved / Spherical Mirrors

Presentation transcript:

Reflection of Light Reflection: the turning back of a wave after meeting the boundary of a medium Regular Reflection Types of Behaviors: transmitted absorbed Scattered reflection Animations courtesy of Dr. Dan Russell, Kettering University

Mirror: an object that produces regular reflection at a high percentage of reflectance. Types of Mirrors  A) Plane: Reflective surface lies in a plane B) Convex: Outside curve of the mirror is reflective C) Concave: Inside curve of the mirror is reflective Types of Images  Real image formed by light rays that actually converge through the image point.

**Real images can only be formed by concave mirrors! Virtual image is formed behind the mirror by reflected light rays that diverge, but appear to meet behind the mirror. **Virtual images are formed by plane, convex and concave mirrors! Plane Mirror Image  always form a virtual image that appears the same size as the object, and just as far behind the mirror as the object is in front.

Plane Mirror Image: h i = h o and d i = d o Always virtual and:

What is unusual about this picture?

The picture is upside down!

Convex Mirror Image: Always Virtual and… h i = d i h o d o h i < h o and d i < d o But in proportion to each other:

Concave Mirror Image: As the object approaches the mirror: A smaller real image is formed, then A same size real image, then No image at all, then Virtural image (h i > h o ) h i = d i h o d o Again:

Curved Mirror Terminology vertex principal axis F Principal Focus C Center of Curvature focal length (f) radius of curvature (r) r = 2f

 F didi dodo 1 = f d o d i h i = d i h o d o Concave Mirror Image Formation

Convex Mirror Image Formation dodo F didi Virtual distances cannot actually be measured! Virtual distances are negative! f is always negative for a convex mirror d i is always negative for a virtual image

A man places an object 5.0 m in front of a plane mirror and plans to photograph the image of the object in the mirror. How far away from the lens should the camera be focused to produce the clearest possible image? A face that is 28.0 cm long is moved in front of a concave make-up mirror. If the focal length of the mirror is 20.0 cm, and the face is 15.0 cm from the mirror, how tall will the image be? A convex shoplifting mirror makes an image of a 1.85 m man appear to be only 45.0 cm tall. What is the focal length of the mirror?

A candle that is 12.0 cm tall is placed in front of a concave mirror so that the image of the object is projected onto a screen. The image is measured to be 12.0 cm tall. What is the focal length of the mirror? A man whose eyes are 1.62 m above the floor stands 2.10 m in front of a plane mirror whose bottom edge is 43.0 cm above the floor. How much closer to the mirror must the man move in order to see his feet in the mirror?

A student uses a concave mirror of focal length 7.60 cm located at the cm mark on the optical bench. His object is located at the cm mark. At what mark should he place his screen in order to see the real image produced? An object that is 2.00 cm tall is placed in front of a concave mirror and produces a virtual image that appears 5.45 cm tall. If the image is placed 7.00 cm in front of mirror, what must be the focal length of that mirror?