Geometrical Optics (Lecture II)

Slides:

Advertisements

Similar presentations

Chapter 17 Geometrical Optics.

Advertisements

1 Geometric optics Light in geometric optics is discussed in rays and represented by a straight line with an arrow indicating the propagation direction.

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

TOC 1 Physics 212 and 222 Reflection and Mirrors What do we see? Law of Reflection Properties of Spherical Mirrors Ray Tracing Images and the Equations.

Chapter 31 Images.

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

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

Chapter 23 Mirrors and Lenses.

Reflection of Light. When light rays hit an object, they change direction. The type of surface the light encounters determines the type of reflection.

Curved Mirrors.

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.

air water As light reaches the boundary between two media,

Curved Mirrors.

Lecture 23 Mirrors Lens.

Reference Book is Geometric Optics.

Chapter 25. The Reflection of Light: Mirrors

Chapter 23 Mirrors and Lenses.

Light: Geometric Optics

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.

Chapter 36 Image Formation Dr. Jie Zou PHY 1371.

Physics 110G Light TOC 1 What do we see? Law of Reflection Properties of Spherical Mirrors Ray Tracing Images and the Equations.

Reflection Physics Department, New York City College of Technology.

Chapter 26 Optics I (Mirrors). LIGHT Properties of light: Light travels in straight lines: Laser.

Chapter 23 Mirrors and Lenses.

Optics Reflections/Mirrors 1 What do we see? Law of Reflection Properties of Spherical Mirrors Ray Tracing Images and the Equations.

Formation of Images by Spherical Mirrors

Curved Mirrors The most common type of curved mirror is a spherical mirror A spherical mirror has the shape of a section from the surface of a sphere.

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

Mirrors and Lenses.

Chapter 25 The Reflection of Light: Mirrors Wave Fronts and Rays A hemispherical view of a sound wave emitted by a pulsating sphere. The rays are.

Chapter 14 Light and Reflection

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

Physics 1C Lecture 26A.

Geometric Optics September 14, Areas of Optics Geometric Optics Light as a ray. Physical Optics Light as a wave. Quantum Optics Light as a particle.

Light: Geometric Optics Chapter Ray Model of Light Light travels in a straight line so a ray model is used to show what is happening to the light.

Chapter 25 The Reflection of Light: Mirrors. LAW OF REFLECTION The incident ray, the reflected ray, and the normal to the surface all lie in the same.

Chapter 23 Mirrors and Lenses. Types of Images for Mirrors and Lenses A real image is one in which light actually passes through the image point A real.

The Reflection of Light: Mirrors

PROOF OF d i = d o ii rr 11 22 . DESCRIPTION OF d i = d o  Ray of light leaves base & strikes mirror at  i (reflected at same  )  Angles.

3/4/ PHYS 1442 – Section 004 Lecture #18 Monday March 31, 2014 Dr. Andrew Brandt Chapter 23 Optics The Ray Model of Light Reflection; Image Formed.

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.

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

Curved Mirrors Chapter 14, Section 3 Pg

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.

Chapter 7 Light and Geometric Optics

Chapter 36 Image Formation.

AP Physics IV.C Geometric Optics. Wave Fronts and Rays.

Announcements Two exams down, one to go! No HW this week. Office hours: My office hours today from 2-3 pm (or make an appointment) Always check out

Plane Mirror: a mirror with a flat surface

Unit 8 – Curved Mirrors. Unit 8 – Concave Spherical Mirror Concave spherical mirror: a mirror whose reflecting surface is a segment of the inside of a.

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

Mirrors and Images. Light Review A luminous object emits light (ex: the sun) An illuminated object reflects light (ex: the moon) For both, light emits/reflects.

PHY 102: Lecture Wave Fronts and Rays 9.2 Reflection of Light

Basics Reflection Mirrors Plane mirrors Spherical mirrors Concave mirrors Convex mirrors Refraction Lenses Concave lenses Convex lenses.

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.

Millions of light rays reflect from objects and enter our eyes – that ’ s how we see them! When we study the formation of images, we will isolate just.

The Reflection of Light: Mirrors

The Reflection of Light: Mirrors

Millions of light rays reflect from objects and enter our eyes – that’s how we see them! When we study the formation of images, we will isolate just a.

Millions of light rays reflect from objects and enter our eyes – that’s how we see them! When we study the formation of images, we will isolate just a.

Millions of light rays reflect from objects and enter our eyes – that’s how we see them! When we study the formation of images, we will isolate just a.

REFLECTIONS of PLANE AND SPHERICAL MIRRORS

Part 3: Optics (Lenses and Mirrors)

Text Reference: Chapter 32.1 through 32.2

The Reflection of Light: Mirrors

The Reflection of Light: Mirrors

The Reflection of Light: Mirrors

The Reflection of Light: Mirrors

Presentation transcript:

Geometrical Optics (Lecture II) Chapter 26 Geometrical Optics (Lecture II) Dr. Jie Zou PHY 1161

Outline Forming images with a plane mirror Spherical mirrors Real world application: retroreflector Spherical mirrors Concave mirror and convex mirror Forming images with a concave or convex mirror Ray tracing (ray diagram) Mirror equation Dr. Jie Zou PHY 1161

Forming Images with a Plane Mirror Forming a mirror image: The light from an object reflects from a mirror before it enters our eyes. To the observer, it appears that the rays are emanating from behind the mirror. Some properties of a plane mirror image: It is upright, but appears reversed right to left. It is the same distance behind the mirror as the object is in front of the mirror. It is the same size as the object. It is a virtual but NOT a real image. Dr. Jie Zou PHY 1161

Real World Applications Retroreflection: If the angle between the two mirrors is 90°, the reflected beam will return to the source parallel to its original path. Dr. Jie Zou PHY 1161

Spherical Mirrors A spherical mirror has the same shape as a section of a sphere. Concave mirror: The inside surface is reflecting. Convex mirror: The outside surface is a reflecting. Center of curvature C: the center of the sphere with radius R of which the mirror is a section. Principal axis: a straight line drawn through the center of curvature and the midpoint of the mirror. Focal point and focal length (see next slide) Dr. Jie Zou PHY 1161

Focal Point and Focal Length of Convex and Concave Mirrors Focal point F Focal length f: For a convex mirror: f = - (1/2)R. “-” sign indicates that the focal point F lies behind the mirror. For a concave mirror: f = (1/2)R. “+” sign indicates that the focal point is in front of the mirror. In this case, the rays of light actually pass through and converge at the focal point F. Convex mirror Dr. Jie Zou PHY 1161 Concave mirror

Forming Images with a Convex and Concave Mirror Two techniques to find the orientation, size, and location of an image formed by a spherical mirror: (1) Ray tracing (ray diagram): Gives the orientation of the image as well as qualitative information on its location and size. (2) Mirror equation: Provides precise and quantitative information without the need for accurate scale drawing. Dr. Jie Zou PHY 1161

Raying Tracing Basic idea behind ray tracing: Follow the path of representative rays of light as they reflect from a mirror and form an image. Three representative rays: (1) Parallel ray (P ray): a ray parallel to the principle axis of the mirror (2) Focal-point ray (F ray): a ray that passes through (concave mirror) or moves toward (convex mirror) the focal point F (3) Center-of-curvature ray (C ray): a ray that moves along a straight line extending from the center of curvature C Concave mirror Dr. Jie Zou PHY 1161 Convex mirror

Ray Diagram for a Convex Mirror Image properties: It is a virtual image: no light actually passes through the image. Orientation: upright (the same orientation as the object). Size: smaller than the object. Location: between the mirror and the focal point F. Dr. Jie Zou PHY 1161

Ray Diagram for a Concave Mirror Consider three situations, (a), (b) and (c) Question: Is a makeup mirror concave or convex? (b) Dr. Jie Zou PHY 1161

Mirror Equation Mirror equation: Magnification, m: m = hi/ho= - di/do (1/do) + (1/di) = 1/f do (object distance): distance from the mirror to the object. di (image distance): distance from the mirror to the image. f: the focal length of the spherical mirror. Magnification, m: m = hi/ho= - di/do hi: height of the image ho: height of the object Dr. Jie Zou PHY 1161

Sign Conventions for the Mirror Equation Focal length f >0 for concave mirrors f<0 for convex mirrors Magnification m>0 for upright images m<0 for inverted images Image distance di >0 for images in front of a mirror (real images) di<0 for images behind a mirror (virtual images) Object distance do>0 for objects in front of a mirror (real objects) do<0 for objects behind a mirror (virtual objects) Dr. Jie Zou PHY 1161

Examples Exercise 26-1: The concave side of a spoon has a focal length of 5.00 cm. Find the image distance for this “mirror” when the object distance is (a) 25.0 cm, (b) 9.00 cm, and (c) 2.00 cm. Also, is the image in each case real or virtual? Upright or inverted? Smaller or enlarged? Exercise 26-2: The convex mirror has a 20.0-cm radius of curvature. Find the image distance for this mirror when the object distance is 6.33 cm. Dr. Jie Zou PHY 1161

Homework #12 Chapter 26, P. 939-941, Problems: #1, 10, 18, 28, 29, 31 (Physics, Walker, 4th edition). Dr. Jie Zou PHY 1161