The Reflection of Light: Mirrors

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.
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.
→ ℎ
Chapter 31 Images.
Mirrors Law of Reflection The angle of incidence with respect to the normal is equal to the angle of reflection.
A wave front consists of all points in a wave that are in the same phase of motion. A wave front is one of many properties that light waves share with.
Chapter 32Light: Reflection and Refraction. Electromagnetic waves can have any wavelength; we have given different names to different parts of the wavelength.
Reflection of Light. When light rays hit an object, they change direction. The type of surface the light encounters determines the type of reflection.
air water As light reaches the boundary between two media,
Chapter 25. The Reflection of Light: Mirrors
Light: Geometric Optics
Light and Reflection Level 1 Physics. Facts about Light It is a form of Electromagnetic Energy It is a part of the Electromagnetic Spectrum and the only.
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.
Chapter 26 Optics I (Mirrors). LIGHT Properties of light: Light travels in straight lines: Laser.
Physics Mechanics Fluid Motion Heat Sound Electricity Magnetism Light.
Geometrical Optics (Lecture II)
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.
Ray Model A useful model under certain circumstances to explain image formation. Ray Model: Light travels in straight-line paths, called rays, in ALL.
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.
1 Reflection and Mirrors. 2 The Law of Reflection “ The angle of incidence equals the angle of reflection.”
Image Formation. We will use geometrical optics: light propagates in straight lines until its direction is changed by reflection or refraction. When we.
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 25. Mirrors and the Reflection of Light
The Reflection of Light: Mirrors
AP Physics Chp 25. Wavefronts – location of the same point for the same phase of the wave Rays – perpendicular to the wavefront Plane waves – all rays.
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.
25.4: Spherical Mirrors. Concave Mirror Light rays near and parallel to the principal axis are reflected from a concave mirror and converge at the focal.
Chapter 36 Image Formation.
AP Physics IV.C Geometric Optics. Wave Fronts and Rays.
Physics Mechanics Fluid Motion Heat Sound Electricity Magnetism Light.
Chapter 36 Image Formation 1: 1. Flat mirror 2. Spherical mirrors.
Mirrors. Mirrors and Images (p 276) Light travels in straight lines, this is the reason shadows and images are produced (p 277) Real images are images.
Calculate distances and focal lengths using the mirror equation for concave and convex spherical mirrors. Draw ray diagrams to find the image distance.
A light beam striking a boundary between two media can be partly transmitted and partly reflected at the boundary.
Mirrors.
PHY 102: Lecture Wave Fronts and Rays 9.2 Reflection of Light
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.
Lecture 2: Reflection of Light: Mirrors (Ch 25) & Refraction of Light: Lenses (Ch 26)
1 Reflection and Mirrors Chapter The Law of Reflection When light strikes a surface it is reflected. The light ray striking the surface is called.
The Reflection of Light: Mirrors
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.
Geometric Optics Figure Mirrors with convex and concave spherical surfaces. Note that θr = θi for each ray.
Mechanics Fluids Sound Heat Electricity Magnetism Light
Reflection & Mirrors.
Chapter 32Light: Reflection and Refraction
Curved Mirrors
A light beam striking a boundary between two media can be partly transmitted and partly reflected at the boundary.
The Reflection of Light: Mirrors
Reflection.
air water As light reaches the boundary between two media,
Light and Sight.
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
Reflection.
Reflection.
Optics Mirrors and Lenses.
Plane and Curved Mirrors
Chapter 25 Reflection and Mirrors
The Reflection of Light: Mirrors
The Reflection of Light: Mirrors
Mirrors Reflection of Light.
The Reflection of Light: Mirrors
Presentation transcript:

The Reflection of Light: Mirrors Chapter 25 The Reflection of Light: Mirrors

A hemispherical view of a sound wave emitted by a pulsating sphere. 25.1 Wave Fronts and Rays A hemispherical view of a sound wave emitted by a pulsating sphere. The rays are perpendicular to the wave fronts.

At large distances from the source, the wave fronts become less 25.1 Wave Fronts and Rays At large distances from the source, the wave fronts become less and less curved.

25.2 The Reflection of Light LAW OF REFLECTION The incident ray, the reflected ray, and the normal to the surface all lie in the same plane, and the angle of incidence equals the angle of reflection.

25.2 The Reflection of Light In specular reflection, the reflected rays are parallel to each other.

25.3 The Formation of Images by a Plane Mirror The person’s right hand becomes the image’s left hand. The image has three properties: It is upright. It is the same size as you are. The image is as far behind the Mirror you are in front of it.

25.3 The Formation of Images by a Plane Mirror A ray of light from the top of the chess piece reflects from the mirror. To the eye, the ray seems to come from behind the mirror. Because none of the rays actually emanate from the image, it is called a virtual image.

25.3 The Formation of Images by a Plane Mirror The geometry used to show that the image distance is equal to the object distance.

25.3 The Formation of Images by a Plane Mirror Conceptual Example 1 Full-Length Versus Half-Length Mirrors What is the minimum mirror height necessary for her to see her full image?

25.3 The Formation of Images by a Plane Mirror Conceptual Example 2 Multiple Reflections A person is sitting in front of two mirrors that intersect at a right angle. The person sees three images of herself. Why are there three, rather than two, images?

mirror. If the outside surface is polished, is it a convex mirror. 25.4 Spherical Mirrors If the inside surface of the spherical mirror is polished, it is a concave mirror. If the outside surface is polished, is it a convex mirror. The law of reflection applies, just as it does for a plane mirror. The principal axis of the mirror is a straight line drawn through the center and the midpoint of the mirror.

A point on the tree lies on the principal axis of the concave mirror. 25.4 Spherical Mirrors A point on the tree lies on the principal axis of the concave mirror. Rays from that point that are near the principal axis cross the axis at the image point.

Light rays near and parallel to the principal axis are reflected 25.4 Spherical Mirrors Light rays near and parallel to the principal axis are reflected from the concave mirror and converge at the focal point. The focal length is the distance between the focal point and the mirror.

The focal point of a concave mirror is halfway between 25.4 Spherical Mirrors The focal point of a concave mirror is halfway between the center of curvature of the mirror C and the mirror at B.

Rays that lie close to the principal axis are called paraxial rays. 25.4 Spherical Mirrors Rays that lie close to the principal axis are called paraxial rays. Rays that are far from the principal axis do not converge to a single point. The fact that a spherical mirror does not bring all parallel rays to a single point is known as spherical abberation.

25.4 Spherical Mirrors

When paraxial light rays that are parallel to the principal axis 25.4 Spherical Mirrors When paraxial light rays that are parallel to the principal axis strike a convex mirror, the rays appear to originate from the focal point.

25.5 The Formation of Images by Spherical Mirrors CONCAVE MIRRORS This ray is initially parallel to the principal axis and passes through the focal point. This ray initially passes through the focal point, then emerges parallel to the principal axis. This ray travels along a line that passes through the center.

25.5 The Formation of Images by Spherical Mirrors Image formation and the principle of reversibility

25.5 The Formation of Images by Spherical Mirrors When an object is located between the focal point and a concave mirror, and enlarged, upright, and virtual image is produced.

25.5 The Formation of Images by Spherical Mirrors CONVEX MIRRORS Ray 1 is initially parallel to the principal axis and appears to originate from the focal point. Ray 2 heads towards the focal point, emerging parallel to the principal axis. Ray 3 travels toward the center of curvature and reflects back on itself.

25.5 The Formation of Images by Spherical Mirrors The virtual image is diminished in size and upright.

25.6 The Mirror Equation and Magnification

25.6 The Mirror Equation and Magnification These diagrams are used to derive the mirror equation.

25.6 The Mirror Equation and Magnification Example 5 A Virtual Image Formed by a Convex Mirror A convex mirror is used to reflect light from an object placed 66 cm in front of the mirror. The focal length of the mirror is -46 cm. Find the location of the image and the magnification.

25.6 The Mirror Equation and Magnification Summary of Sign Conventions for Spherical Mirrors