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0. Math Review31m
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1. Intro to Physics Units1h 29m
2. 1D Motion / Kinematics3h 56m
3. Vectors2h 43m
4. 2D Kinematics1h 42m
5. Projectile Motion3h 6m
6. Intro to Forces (Dynamics)3h 22m
7. Friction, Inclines, Systems2h 44m
8. Centripetal Forces & Gravitation7h 26m
9. Work & Energy1h 59m
10. Conservation of Energy2h 54m
11. Momentum & Impulse3h 40m
12. Rotational Kinematics2h 59m
13. Rotational Inertia & Energy7h 4m
14. Torque & Rotational Dynamics2h 5m
15. Rotational Equilibrium3h 39m
16. Angular Momentum3h 6m
17. Periodic Motion2h 9m
18. Waves & Sound3h 40m
19. Fluid Mechanics4h 27m
20. Heat and Temperature3h 7m
21. Kinetic Theory of Ideal Gases1h 50m
22. The First Law of Thermodynamics1h 26m
23. The Second Law of Thermodynamics3h 11m
24. Electric Force & Field; Gauss' Law3h 42m
25. Electric Potential1h 51m
26. Capacitors & Dielectrics2h 2m
27. Resistors & DC Circuits3h 8m
28. Magnetic Fields and Forces2h 23m
29. Sources of Magnetic Field2h 30m
30. Induction and Inductance3h 38m
31. Alternating Current2h 37m
32. Electromagnetic Waves2h 14m
33. Geometric Optics2h 57m
34. Wave Optics1h 15m
35. Special Relativity2h 10m

33. Geometric Optics

Reflection of Light

Physics

33. Geometric Optics

Reflection of Light

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Problem 9

Textbook Question

It is 165 cm from your eyes to your toes. You're standing 200 cm in front of a tall mirror. How far is it from your eyes to the image of your toes?

Verified step by step guidance

Step 1: Understand the problem. The distance from your eyes to your toes is 165 cm, and you are standing 200 cm in front of a mirror. The goal is to determine the distance from your eyes to the image of your toes formed in the mirror.

Step 2: Recall the principle of image formation in a plane mirror. The image of an object in a plane mirror appears to be the same distance behind the mirror as the object is in front of it. This means the image of your toes will be 200 cm behind the mirror.

Step 3: Calculate the total distance from your eyes to the image of your toes. This distance is the sum of the distance from your eyes to the mirror (200 cm) and the distance from the mirror to the image of your toes (200 cm), plus the distance from your eyes to your toes (165 cm).

Step 4: Write the total distance mathematically as: \( \text{Total Distance} = 200 \text{ cm} + 200 \text{ cm} + 165 \text{ cm} \).

Step 5: Add the distances together to find the total distance. This will give you the distance from your eyes to the image of your toes.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Reflection in Mirrors

When light rays hit a mirror, they reflect off the surface according to the law of reflection, which states that the angle of incidence equals the angle of reflection. This means that the image formed in a mirror appears to be the same distance behind the mirror as the object is in front of it. Understanding this principle is crucial for determining the distance from your eyes to the image of your toes.

Distance Measurement

In this scenario, distance is measured from your eyes to the mirror and from the mirror to the image of your toes. The total distance from your eyes to the image can be calculated by adding the distance from your eyes to the mirror and the distance from the mirror to the image, which is equal to the distance from the mirror to your toes. This concept is fundamental for solving the problem accurately.

Geometry of Images

The geometry of images in mirrors involves understanding how the position of an object relates to its image. In a flat mirror, the image appears to be the same size as the object and is located directly behind the mirror at an equal distance. This geometric relationship helps in visualizing and calculating the distance from your eyes to the image of your toes in the given scenario.

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Related Practice

Textbook Question

The indexes of refraction for violet light (λ = 400 nm) and red light (λ= 700 nm) in diamond are 2.46 and 2.41, respectively. A ray of light traveling through air strikes the diamond surface at an angle of 53.5° to the normal. Calculate the angular separation between these two colors of light in the refracted ray.

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Textbook Question

A beam of light strikes a sheet of glass at an angle of 57.0° with the normal in air. You observe that red light makes an angle of 38.1° with the normal in the glass, while violet light makes a 36.7° angle. What are the speeds of red and violet light in the glass?

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Textbook Question

A helium-neon laser beam has a wavelength in air of 633 nm. It takes 1.38 ns for the light to travel through 30 cm of an unknown liquid. What is the wavelength of the laser beam in the liquid?

Some modern optical devices are made with glass whose index of refraction changes with distance from the front surface. FIGURE P16.72 shows the index of refraction as a function of the distance into a slab of glass of thickness L. The index of refraction increases linearly from n₁ at the front surface to n₂ at the rear surface. Evaluate your expression for a 1.0-cm-thick piece of glass for which n₁ = 1.50 and n₂ = 1.60.

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Textbook Question

A camera takes a properly exposed photo at F5.6 and 1/125 s. What shutter speed should be used if the lens is changed to F4.0?

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Textbook Question

The Hubble Space Telescope has a mirror diameter of 2.4 m. Suppose the telescope is used to photograph stars near the center of our galaxy, 30,000 light years away, using red light with a wavelength of 650 nm. For comparison, what is this distance as a multiple of the distance of Jupiter from the sun?

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Textbook Question

Alpha Centauri, the nearest star to our solar system, is 4.3 light years away. Assume that Alpha Centauri has a planet with an advanced civilization. Professor Dhg, at the planet’s Astronomical Institute, wants to build a telescope with which he can find out whether any planets are orbiting our sun. Building a telescope of the necessary size does not appear to be a major problem. What practical difficulties might prevent Professor Dhg’s experiment from succeeding?

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Textbook Question

The cornea, a boundary between the air and the aqueous humor, has a 3.0 cm focal length when acting alone. What is its radius of curvature?

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