270 likes | 507 Vues
Chapter 13 . Section 3 Curved Mirrors . Calculate distances and focal lengths using the mirror equation for concave and convex spherical mirrors. Draw ray diagrams to find the image distance and magnification for concave and convex spherical mirrors.
E N D
Chapter 13 Section 3 Curved Mirrors
Calculate distances and focal lengths using the mirror equation for concave and convex spherical mirrors. • Draw ray diagrams to find the image distance and magnification for concave and convex spherical mirrors. • Distinguish between real and virtual images. • Describe how parabolic mirrors differ fromspherical mirrors. Objectives
Curved mirrors are like plane mirrors • they too have smooth, shiny surfaces that reflect light. • The surface can either curve in (concave) or out (convex) as shown below Curved Mirrors
Thus far in this unit, our focus has been the reflection of light off flat surfaces and the formation of images by plane mirrors. In Lessons 3 and 4 we will turn our attention to the topic curved mirrors, and specifically curved mirrors that have a sphericalshape. Such mirrors are called spherical mirrors. The two types of spherical mirrors are shown in the diagram on the right. Spherical mirrors can be thought of as a portion of a sphere that was sliced away and then silvered on one of the sides to form a reflecting surface Types of curved mirrors
A concave spherical mirror is a mirror whose reflecting surface is a segment of the inside of a sphere. • Concave mirrors can be used to form real images. • A real image is an image formed when rays of light actually pass through a point on the image. Real images can be projected onto a screen. Concave spherical mirror
Rays from very distant things are nearly parallel to each other • a concave mirror brings parallel rays to a focus at a point called the principal focus (F) • the distance from the mirror to the principal focus is called the focal length • highly curved mirror have short focal lengths Concave spherical mirror
If a concave mirror were thought of as being a slice of a sphere, then there would be a line passing through the center of the sphere and attaching to the mirror in the exact center of the mirror. This line is known as the principal axis. The point in the center of the sphere from which the mirror was sliced is known as the center of curvature and is denoted by the letter C in the diagram below. The point on the mirror's surface where the principal axis meets the mirror is known as the vertex and is denoted by the letter A in the diagram below. The vertex is the geometric center of the mirror. Midway between the vertex and the center of curvature is a point known as the focal point; the focal point is denoted by the letter F in the diagram below. The distance from the vertex to the center of curvature is known as the radius of curvature (represented by R). The radius of curvature is the radius of the sphere from which the mirror was cut. Finally, the distance from the mirror to the focal point is known as the focal length (represented by f). Since the focal point is the midpoint of the line segment adjoining the vertex and the center of curvature, the focal length would be one-half the radius of curvature. Concave mirrors
The Mirror Equation relates object distance (p), image distance (q), and focal length (f) of a spherical mirror. Mirror equation
Unlike flat mirrors, curved mirrors forms images that are not the same size as the object. The measure of how large or small the image is with respect to the original object’s size is called the magnification of the image. For an image in front of the mirror, m is negative and the image is upside down, or inverted When the image is behind the mirror, M is positive and the image is upright with respect to the object Magnification equation
Ray diagrams can be used for checking values calculated from the mirror and magnification equations for concave spherical mirrors. • Concave mirrors can produce both real and virtual images. Concave spherical mirrors
A concave spherical mirror has a focal length of 10.0 cm. Locate the image of a pencil that is placed upright 30.0 cm from the mirror. Find the magnification of the image. Draw a ray diagram to confirm your answer. Examples with concave mirrors
Determine the sign and magnitude of the focal length and object size. f = +10.0 cm p = +30.0 cm The mirror is concave, so f is positive. The object is in front of the mirror, so p is positive. • So using the mirror equation • Solve for q q=15 cm solution
Magnification equation 15/30 =-1/2=-.5 solution
A convex spherical mirror is a mirror whose reflecting surface is outward-curved segment of a sphere. • Light rays diverge upon reflection from a convex mirror, forming a virtual image that is always smaller than the object. Convex spherical mirror
Characteristic of convex mirror • A convex mirror is part of the outer surface of a hollow sphere • A convex mirror produces diverged rays • A convex mirror does not form real images • Convex mirror in daily life, used in cars, and used in stores to observe shoppers. Convex spherical mirrors
An upright pencil is placed in front of a convex spherical mirror with a focal length of 8.00 cm. An erect image 2.50 cm tall is formed 4.44 cm behind the mirror. Find the position of the object, the magnification of the image, and the height of the pencil. Convex mirror sample problem
Convex Mirrors Given: Because the mirror is convex, the focal length is negative. The image is behind the mirror, so q is also negative. f = –8.00 cm q = –4.44 cm h’ = 2.50 cm Unknown: p = ? h = ? • Using mirror equation solution Solve for p p=.1 cm
Using magnification equation M=-q/p M=.444 M=h’/h H=h’/m=5.63 cm solution
Three kinds of rays • The ray parallel to the principal axis is reflected as if it is from focal point (f) • The ray to focal point is reflected parallel to the principal axis • The ray to the center of curvature C is reflected along its same path through C Forming an image in convex mirrors
Images created by spherical mirrors suffer from spherical aberration. • Spherical aberration occurs when parallel rays far from the principal axis converge away from the mirrors focal point. • Parabolic mirrors eliminate spherical aberration. All parallel rays converge at the focal point of aparabolic mirror. Parabolic mirrors
Do worksheet problems Student guided practice
Today we learned about concave and convex mirrors • Next class we are going to learn about color and polarization Closure