Textbook Question
A dentist wants a small mirror that, when 2.00 cm from a tooth, will produce a 3.0 x upright image. What kind of mirror must be used and what must its radius of curvature be?
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Ch. 32 - Light: Reflection and Refraction
Giancoli Douglas5th editionPhysics for Scientists and EngineersISBN: 9780137488179
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Table of contents
- Ch. 01 - Introduction, Measurement, Estimating10
- Ch. 02 - Describing Motion: Kinematics in One Dimension30
- Ch. 03 - Kinematics in Two or Three Dimensions; Vectors15
- Ch. 04 - Dynamics: Newton's Laws of Motion16
- Ch. 05 - Using Newton's Laws: Friction, Circular Motion, Drag Forces22
- Ch. 06 - Gravitation and Newton's Synthesis10
- Ch. 07 - Work and Energy21
- Ch. 08 - Conservation of Energy33
- Ch. 09 - Linear Momentum26
- Ch. 10 - Rotational Motion41
- Ch. 11 - Angular Momentum; General Rotation27
- Ch. 12 - Static Equilibrium; Elasticity and Fracture27
- Ch. 13 - Fluids28
- Ch. 14 - Oscillations14
- Ch. 15 - Wave Motion35
- Ch. 16 - Sound5
- Ch. 17 - Temperature, Thermal Expansion, and the Ideal Gas Law40
- Ch. 18 - Kinetic Theory of Gases18
- Ch. 19 - Heat and the First Law of Thermodynamics31
- Ch. 20 - Second Law of Thermodynamics32
- Ch. 21 - Electric Charge and Electric Field7
- Ch. 23 - Electric Potential20
- Ch. 24 - Capacitance, Dielectrics, Electric Energy, Storage15
- Ch. 25 - Electric Current and Resistance32
- Ch. 26 - DC Circuits22
- Ch. 27 - Magnetism21
- Ch. 28 - Sources of Magnetic Field24
- Ch. 29 - Electromagnetic Induction and Faraday's Law21
- Ch. 30 - Inductance, Electromagnetic Oscillations, and AC Circuits42
- Ch. 31 - Maxwell's Equations and Electromagnetic Waves25
- Ch. 32 - Light: Reflection and Refraction42
- Ch. 33 - Lenses and Optical Instruments21
- Ch. 34 - The Wave Nature of Light: Interference and Polarization26
- Ch. 35 - Diffraction24
- Ch. 36 - The Special Theory of Relativity29
- Ch. 38 - Quantum Mechanics1
- Ch. 40 - Molecules and Solids6
- Ch. 43 - Elementary Particles3
- Ch. 44 - Astrophysics and Cosmology9
Giancoli Douglas5th editionPhysics for Scientists and EngineersISBN: 9780137488179Not the one you use?Change textbook
Chapter 31, Problem 19a
An object 4.0 mm high is placed 18 cm from a convex mirror of radius of curvature 18 cm. Show by ray tracing that the image is virtual, and estimate the image distance.
Verified step by step guidance1
Understand the problem: A convex mirror is given with a radius of curvature \( R = 18 \; \text{cm} \). The object height is \( h_o = 4.0 \; \text{mm} \) and the object distance is \( d_o = 18 \; \text{cm} \). We need to determine the image distance \( d_i \) and show that the image is virtual using ray tracing.
Recall the mirror equation: \( \frac{1}{f} = \frac{1}{d_o} + \frac{1}{d_i} \), where \( f \) is the focal length. For a convex mirror, the focal length is related to the radius of curvature by \( f = \frac{R}{2} \). Since the mirror is convex, the focal length is positive, so \( f = +9 \; \text{cm} \).
Substitute the known values into the mirror equation: \( \frac{1}{9} = \frac{1}{18} + \frac{1}{d_i} \). Rearrange to solve for \( \frac{1}{d_i} \): \( \frac{1}{d_i} = \frac{1}{9} - \frac{1}{18} \). Simplify the fractions to find \( d_i \).
Interpret the result: The calculated \( d_i \) will be positive, indicating that the image is virtual and located on the same side as the object. Virtual images in convex mirrors are always upright and reduced in size.
To confirm this visually, perform ray tracing: Draw a convex mirror and an object in front of it. Trace at least two rays: (1) A ray parallel to the principal axis reflects as if it came from the focal point, and (2) a ray directed toward the center of curvature reflects back on itself. The reflected rays appear to diverge, and their extensions meet behind the mirror, forming a virtual image.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Convex Mirror Properties
A convex mirror is a curved mirror that bulges outward, causing light rays to diverge. This type of mirror always produces virtual images, which are upright and smaller than the object. The focal point of a convex mirror is located behind the mirror, and its radius of curvature is positive, affecting how images are formed.
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Ray Diagrams for Convex Mirrors
Ray Tracing Technique
Ray tracing is a method used to determine the position and characteristics of an image formed by a mirror or lens. For convex mirrors, two principal rays are typically drawn: one parallel to the principal axis that reflects through the focal point, and another directed towards the focal point that reflects parallel to the axis. The intersection of these reflected rays indicates the location of the virtual image.
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06:12Ray Diagrams for Diverging Lenses
Image Distance and Magnification
Image distance refers to the distance from the mirror to the image formed. In the case of convex mirrors, this distance is considered negative, as virtual images appear behind the mirror. Magnification is the ratio of the height of the image to the height of the object, which helps in understanding how the size of the image relates to the object, typically resulting in a smaller, upright image for convex mirrors.
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Guided course
06:13Displacement vs. Distance
Related Practice
Textbook Question
The lateral magnification of a convex mirror is +0.75 for objects 3.2 m from the mirror. What is the focal length of this mirror?
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Textbook Question
An object 4.0 mm high is placed 18 cm from a convex mirror of radius of curvature 18 cm. Compute the image size, using Eq. 32–3.
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Textbook Question
An object 4.0 mm high is placed 18 cm from a convex mirror of radius of curvature 18 cm. Show that the (negative) image distance can be computed from Eq. 32–2 using a focal length of -9.0 cm.
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Textbook Question
You look at yourself in a shiny 8.4-cm-diameter Christmas tree ball. If your face is 25.0 cm away from the ball’s front surface, where is your image? Is it real or virtual? Is it upright or inverted?
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Textbook Question
(II) Show, using a ray diagram, that the lateral magnification m of a convex mirror is m = -dᵢ/dₒ , just as for a concave mirror. [Hint: Consider a ray from the top of the object that reflects at the center of the mirror.]
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