Fundamentals Of Physics
11th Edition
ISBN: 9781119286240
Author: David Halliday, Robert Resnick, Jearl Walker
Publisher: WILEY
expand_more
expand_more
format_list_bulleted
Concept explainers
Textbook Question
Chapter 34, Problem 105P
In Fig. 34-51, a box is somewhere at the left, on the central axis of the thin converging lens. The image Im of the box produced by the plane mirror is 4.00 cm “inside” the mirror. The lens–mirror separation is 10.0 cm, and the focal length of the lens is 2.00 cm. (a) What is the distance between the box and the lens? Light reflected by the mirror travels back through the lens, which produces a final image of the box. (b) What is the distance between the lens and that final image?
Figure 34-51 Problem 105.
Expert Solution & Answer
Trending nowThis is a popular solution!
Students have asked these similar questions
a box is somewhere at the left, on the central axis of the thin converging lens. The image Im of the box produced by the plane mirror is 4.00 cm “inside” the mirror. The lens–mirror separation is 10.0 cm, and the focal length of the lens is 2.00 cm. (a) What is the distance between the box and the lens? Light reflected by the mirror travels back through the lens, which produces a final image of the box. (b) What is the distance between the lens and that final image?
106 In Fig. 34-52, an object is placed in front of a converging lens
at a distance equal to twice the focal length fi of the lens. On the
other side of the lens is a concave mirror of focal length f2 sepa-
rated from the lens by a distance 2(f + f). Light from the object
passes rightward through the lens, reflects from the mirror, passes
leftward through the lens, and forms a final image of the object.
What are (a) the distance between the lens and that final image
and (b) the overall lateral magnification M of the object? Is the im-
age (c) real or virtual (if it is virtual, it requires someone looking
through the lens toward the mirror), (d) to the left or right of the
lens, and (e) inverted or noninverted relative to the object?
to
E26 2i + f)-
Figure 34-52 Problem 106.
A point object is 10 cm awy from a plane mirror while the eye of an observer (with pupil diameter 5 mm) is 20 cm awy.Assuming both the eye and the point to be on the same line perpendicular to mirror surface. Find the area of the mirror used in observing the reflecction of the point.
Chapter 34 Solutions
Fundamentals Of Physics
Ch. 34 - Figure 34-25 shows a fish and a fish stalker in...Ch. 34 - In Fig. 34-26, stick figure O stands in front of a...Ch. 34 - Figure 34-27 is an overhead view of a mirror maze...Ch. 34 - A penguin waddles along the central axis of a...Ch. 34 - When a T. rex pursues a jeep in the movie Jurassic...Ch. 34 - An object is placed against the center of a...Ch. 34 - The table details six variations of the basic...Ch. 34 - An object is placed against the center of a...Ch. 34 - Figure 34-30 shows four thin lenses, all of the...Ch. 34 - In Fig. 34-26, stick figure O stands in front of a...
Ch. 34 - Figure 34-31 shows a coordinate system in front of...Ch. 34 - You look through a camera towards an image of a...Ch. 34 - ILW A moth at about eye level is 10 cm in front of...Ch. 34 - In Fig. 34-32, an isotropic point source of light...Ch. 34 - Figure 34-33 shows an overhead view of a corridor...Ch. 34 - SSM WWW Figure 34-34 shows a small lightbulb...Ch. 34 - An object is moved along the central axis of a...Ch. 34 - A concave shaving mirror has a radius of curvature...Ch. 34 - An object is placed against the center of a...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 9 through 16 GO 12 SSM 9, 11, 13 Spherical...Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - 17 through 29 GO 22SSM 23, 29 More mirrors. Object...Ch. 34 - 17 through 29 GO 22 SSM 23, 29 More mirrors....Ch. 34 - GO Figure 34-37 gives the lateral magnification m...Ch. 34 - a A luminous point is moving at speed vo towards a...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - 32 through 38 GO 37, 38 SSM 33, 35 Spherical...Ch. 34 - In Fig. 34-38, a beam of parallel light rays from...Ch. 34 - A glass sphere has radius R = 5.0 cm and index of...Ch. 34 - A lens is made of glass having an index of...Ch. 34 - Figure 34-40 gives the lateral magnification m of...Ch. 34 - A movie camera with a single lens of focal length...Ch. 34 - An object is placed against the center of a thin...Ch. 34 - You produce an image of the Sun on a screen, using...Ch. 34 - An object is placed against the center of a thin...Ch. 34 - SSM WWW A double-convex lens is to be made of...Ch. 34 - An object is moved along the central axis of a...Ch. 34 - SSM An illuminated slide is held 44 cm from a...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 50 through 57 GO 55, 57 SSM 53 Thin lenses. Object...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - 58 through 67 GO 61 SSM 59 Lenses with given...Ch. 34 - In Fig. 34-44, a real inverted image I of an...Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 69 through 79 GO 76, 78 SSM 75, 77 More lenses....Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - 80 through 87 GO 80, 87 SSM WWW 83 Two-lens...Ch. 34 - If the angular magnification of an astronomical...Ch. 34 - SSM In a microscope of the type shown in the Fig....Ch. 34 - Figure 34-46a shows the basic structure of an old...Ch. 34 - SSM Figure 34-47a shows the basic structure of a...Ch. 34 - An object is 10.0 mm from the objective of a...Ch. 34 - Someone with a near point Pn of 25 cm views a...Ch. 34 - An object is placed against the center of a...Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - 95 through 100 GO 95, 96, 99 Three-lens systems....Ch. 34 - SSM The formula 1/p 1/i = 1/f is called the...Ch. 34 - Figure 34-50a is an overhead view of two vertical...Ch. 34 - SSM Two thin lenses of focal lengths f1 and f2 are...Ch. 34 - Two plane mirrors are placed parallel to each...Ch. 34 - In Fig. 34-51, a box is somewhere at the left, on...Ch. 34 - In Fig. 34-52, an object is placed in front of a...Ch. 34 - SSM A fruit fly of height H sits in front of lens...Ch. 34 - You grind the lenses shown in Fig. 34-53 from flat...Ch. 34 - In Fig. 34-54, a fish watcher at point P watches a...Ch. 34 - A goldfish in a spherical fish bowl of radius R is...Ch. 34 - Figure 34-56 shows a beam expander made with two...Ch. 34 - You look down at a coin that lies at the bottom of...Ch. 34 - A pinhole camera has the hole a distance 12 cm...Ch. 34 - Light travels from point A to point B via...Ch. 34 - A point object is 10 cm away from a plane mirror,...Ch. 34 - Show that the distance between an object and its...Ch. 34 - A luminous object and a screen are a fixed...Ch. 34 - An eraser of height 1.0 cm is placed 10.0 cm in...Ch. 34 - A peanut is placed 40 cm in front of a two-lens...Ch. 34 - A coin is placed 20 cm in front of a two-lens...Ch. 34 - An object is 20 cm to the left of a thin diverging...Ch. 34 - In Fig 34-58 a pinecone is at distance p1 = 1.0 m...Ch. 34 - One end of a long glass rod n = 1.5 is a convex...Ch. 34 - A short straight object of length L lies along the...Ch. 34 - Prove that if a plane mirror is rotated through an...Ch. 34 - An object is 30.0 cm from a spherical mirror,...Ch. 34 - A concave mirror has a radius of curvature of 24...Ch. 34 - A pepper seed is placed in front of a lens. The...Ch. 34 - The equation 1/p 1/i = 2/r for spherical mirrors...Ch. 34 - A small cup of green tea is positioned on the...Ch. 34 - A 20-mm-thick layer of water n = 1.33 floats on a...Ch. 34 - A millipede sits 1.0 m in front of the nearest...Ch. 34 - a Show that if the object O in Fig. 34-19c is...Ch. 34 - Isaac Newton, having convinced himself erroneously...Ch. 34 - A narrow beam of parallel light rays is incident...Ch. 34 - A corner reflector, much used in optical,...Ch. 34 - A cheese enchilada is 4.00 cm in front of a...Ch. 34 - A grasshopper hops to a point on the central axis...Ch. 34 - In Fig. 34-60, a sand grain is 3.00 cm from thin...Ch. 34 - Suppose the farthest distance a person can see...Ch. 34 - A simple magnifier of focal length f is placed...
Additional Science Textbook Solutions
Find more solutions based on key concepts
The total angular speed at the time. t2 .
Physics (5th Edition)
Give an example of a damped harmonic oscillator. (They are more common than undamped or simple harmonic oscilla...
University Physics Volume 1
Whether the series ∑n=0∞en n! is convergent or divergent by using ratio test.
Mathematical Methods in the Physical Sciences
* Flywheel energy Engineers at the University of Texas at Austin are developing an Advanced Locomotive Propulsi...
College Physics
A tank contains l0ft3 of air at 15psia,540R . A pipe of flowing air at l50psia,540R is connected to the tank an...
Fundamentals Of Thermodynamics
The magnitude of drag force, FD and its point of action above the centre of mass.
Physics: Principles with Applications
Knowledge Booster
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.Similar questions
- A lamp of height S cm is placed 40 cm in front of a converging lens of focal length 20 cm. There is a plane mirror 15 cm behind the lens. Where would you find the image when you look in the mirror?arrow_forwardThe disk of the Sun subtends an angle of 0.533 at the Earth. What are (a) the position and (b) the diameter of the solar image formed by a concave spherical mirror with a radius of curvature of magnitude 3.00 m?arrow_forwardA convex mirror with a radius of curvature of 25.0 cm is used to form an image of an arrow that is 10.0 cm away from the mirror. If the arrow is 2.00 cm tall and inverted (pointing below the optical axis), what is the height of the arrows image?arrow_forward
- Au object of height 3.0 cm is placed at 25 cm in front of a diverging lens of focal length 20 cm. Behind the diverging lens, there is a converging lens of focal length 20 cm. The distance between the lenses is 5.0 cm. Fluid the location and size of the final image.arrow_forwardAn object of height 3 cm is placed at 25 cm in front of a converging lens of focal length 20 cm. Behind the lens there is a concave mirror of focal length 20 cm. The distance between the lens and the mirror is 5 cm. Find the location, orientation and size of the final image.arrow_forwardAn object is located in water 30 cm from the vertex of a convex surface made of Plexiglas with a radius of curvature of 80 cm. Where does the image form by refraction and what is its magnification? nwater=4/3 and nPlexiglas=1.65.arrow_forward
- What is the magnification of a magnifying lens with a focal length of 10 cm if it is held 3.0 cm from the eye and the object is 12 cm from the eye?arrow_forwardIn the figure, a box is somewhere at the left, on the central axis of the thin converging lens. The image Im of the box produced by the plane mirror is 4.60 cm “inside” the mirror. The lens–mirror separation is 12.9 cm, and the focal length of the lens is 2.10 cm. (a) What is the distance between the box and the lens? Light reflected by the mirror travels back through the lens, which produces a final image of the box. (b) What is the distance between the lens and that final image?arrow_forwardA ray of light strikes a flat block of glass at an incidence angle of 01 = 35.0°. The glass is 2.00 cm thick and has an index of refraction that equals n = 1.75. 'g 2.00 cm (a) What is the angle of refraction, 2, that describes the light ray after it enters the glass from above? (Enter your answer in degrees to at least 2 decimal places.) (b) with what angle of incidence, 03, does the ray approach the interface at the bottom of the glass? (Enter your answer in degrees to at least 2 decimal places.) ° (c) with what angle of refraction, 84, does the ray emerge from the bottom of the glass? (Enter your answer in degrees to at least 1 decimal place.) о (d) The distance d separates the twice-bent ray from the path it would have taken without the glass in the way. What is this distance (in cm)? cm (e) At what speed (in m/s) does the light travel within the glass? m/s (f) How many nanoseconds does the light take to pass through the glass along the angled path shown here? ns (g) Is the travel…arrow_forward
- A thick-walled wine goblet can be considered to be a hollow glasssphere with an outer radius of 4.00 cm and an inner radius of 3.40 cm.The index of refraction of the goblet glass is 1.50. (a) A beam of parallellight rays enters the side of the empty goblet along a horizontal radius.Where, if anywhere, will an image be formed? (b) The goblet is filledwith white wine (n = 1.37). Where is the image formed?arrow_forwardA thick-walled wine goblet can be considered to be a hollow glass sphere with an outer radius of 4.10 cmcm and an inner radius of 3.60 cmcm. The index of refraction of the goblet glass is 1.50. (a) A beam of parallel light rays enters the side of the empty goblet along a horizontal radius. Where, if anywhere, will an image be formed? (b) The goblet is filled with white wine (nn = 1.37). Where is the image formed? Use the image from the previous part as the object for the second surface (the inner wall of the same side of the goblet) and find the position of the second image. Express your answer with the appropriate units.arrow_forwardThe radii of curvature of both sides of a thin converging lens are equal, R. The index of refraction of the lens is n. If we place an object at a distance of 1 m from the lens on its optical axis, the formed image is real, and its height is 1/4 of the height of the object. If the image formation is done in water with the same lens and object distance, the image is real again, but its height is four times larger than that of the object. The refractive index of water and air is 4/3 and 1, respectively.a) Find the refractive index of the lens, and its radius of curvature.Then we examine the lens when one of its sides is in water, the other is in the air.b) Find the focal length of the lens if parallel rays come from water or air to the lens, respectively.arrow_forward
arrow_back_ios
SEE MORE QUESTIONS
arrow_forward_ios
Recommended textbooks for you
- University Physics Volume 3PhysicsISBN:9781938168185Author:William Moebs, Jeff SannyPublisher:OpenStaxPhysics for Scientists and Engineers: Foundations...PhysicsISBN:9781133939146Author:Katz, Debora M.Publisher:Cengage LearningPrinciples of Physics: A Calculus-Based TextPhysicsISBN:9781133104261Author:Raymond A. Serway, John W. JewettPublisher:Cengage Learning
University Physics Volume 3
Physics
ISBN:9781938168185
Author:William Moebs, Jeff Sanny
Publisher:OpenStax
Physics for Scientists and Engineers: Foundations...
Physics
ISBN:9781133939146
Author:Katz, Debora M.
Publisher:Cengage Learning
Principles of Physics: A Calculus-Based Text
Physics
ISBN:9781133104261
Author:Raymond A. Serway, John W. Jewett
Publisher:Cengage Learning
Convex and Concave Lenses; Author: Manocha Academy;https://www.youtube.com/watch?v=CJ6aB5ULqa0;License: Standard YouTube License, CC-BY