COLLEGE PHYSICS
2nd Edition
ISBN: 9781464196393
Author: Freedman
Publisher: MAC HIGHER
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Chapter 24, Problem 22QAP
To determine
What kind of mirror should be used by a dentist to see an enlarged, upright image of a patient's tooth
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Rear-View Mirror. A mirror on the passenger side of your car is convex and has a radius of curvature with magnitude 18.0 cm. (a) Another car is behind your car, 9.00 m from the mirror, and this car is viewed in the mirror by your passenger. If this car is 1.5 m tall, what is the height of the image? (b) The mirror has a warning attached that objects viewed in it are closer than they appear. Why is this so?
Baxter Nachure lives in the country along Sinewave road. It is difficult to pull out of the driveway onto the road since the road is curved and trees prevent him from seeing around the corner. He recently installed a large convex mirror at one of the curves to give him a wider angle of view. It has a focal length of -1.54 meters. Determine the magnification of an oncoming car located 35.8 m from the mirror.
In many convenience stores, a mirror is placed in a top corner of the store to allow the clerk to have a full view of the store. Is this mirror spherical concave or convex? Explain your answer.
Chapter 24 Solutions
COLLEGE PHYSICS
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- Use the law of reflection to prove that the focal length of a mirror is hall its radius of curvature. That is, prove that f = R/2. Note this is true for a spherical mirror only if its diameter is small compared with its radius of curvature.arrow_forwardConsider a spherical concave mirror with the object located to the left of the mirror beyond the focal point. Using ray diagrams, show that the image moves to the left as the object approaches the focal point.arrow_forwardWhat is the focal length of a makeup mirror that produces a magnification of 1.50 when a person’s face is 12.0 cm away? Explicitly show how you follow the steps in the Problem-Solving Strategy: Spherical Mirrors.arrow_forward
- 2. In most applications of concave spherical mirrors (including this activity) it is assumed that all light rays travelling parallel to the mirror's optical axis are reflected through the mirror's focal point; however, this is an approximation that applies only to light rays traveling near the mirror's optical axis. Explain why a concave spherical mirror does not reflect all light rays travelling parallel to its optical axis through its focal point.arrow_forwardw9-19 physics An object is placed 20.0 cm from a converging lens with focal length 15.0 cm (see the figure, not drawn to scale). A concave mirror with focal length 10.0 cm is located 76.0 cm to the right of the lens. Light goes through the lens, reflects from the mirror, and passes through the lens again, forming a final image. d=76.0 What is the location of the final image? ______cm to the left of the lensarrow_forwardDoes the law of reflection apply in plane mirror and spherical mirrors? Explainarrow_forward
- identify what properties/concepts of mirrors are applied on an eyeglasses please explain thoroughlyarrow_forwardObtaining a large spherical mirror with a focal length of 0.654 m from the Physics Storeroom, Mr. H takes his last period class outside for a fascinating demo. A student volunteer holds the mirror at an angle such that the face of the mirror is directed towards the Sun - roughly 1.46x1011 m away. Mr. H then uses a piece of paper with George Washington's picture on it to focus the image of the sun on the sheet of paper. Before the paper engulfs in flames, a bright image of the sun can be seen on the paper. Use the mirror equation to calculate the distance from the mirror to the image of the sun.arrow_forwardFind a flashlight and identify the curved mirror used in it. Find another flashlight and shine the first flashlight onto the second one, which is turned off. Estimate the focal length of the mirror. You might try shining a flashlight on the curved mirror behind the headlight of a car, keeping the headlight switched off, and determine its focal length.arrow_forward
- 1. You may have noticed a small convex mirror next to your bank’s ATM. Why is this mirror convex, as opposed to flat or concave? What considerations determine its radius of curvature?arrow_forwardImagine that you travel by car on the General Cañas highway, towards San José-Alajuela and the car turns right towards the entrance of Barreal. When you get to the top, in front of you there is a convex mirror on a pole so that you can see the cars coming towards you from the left. The mirror has a radius of curvature of 427.2 mm and the car is positioned 7.5 m away from the mirror, how to calculate the mirror distance - an image that is formed due to the reflection of the car in which you are traveling.arrow_forwardChapter 25: Problem 1: Suppose a man stands in front of a mirror as shown in the figure. His eyes are 1.85 m above the floor, and the top of his head is 0.11 m higher. a) Find the height above the floor of the bottom of the smallest mirror in which he can see both the top of his head and his feet. b) Find the height above the floor of the top of the smallest mirror in which he can see both the top of his head and his feet.arrow_forward
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AP Physics 2 - Geometric Optics: Mirrors and Lenses - Intro Lesson; Author: N. German;https://www.youtube.com/watch?v=unT297HdZC0;License: Standard YouTube License, CC-BY