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Chapter 25: Problem 25

A student's far point is at \(17.0 \mathrm{cm},\) and she needs glasses to view her computer screen comfortably at a distance of 45.0 \(\mathrm{cm} .\) What should be the power of the lenses for her glasses?

Short Answer

Expert verified
The lens power should be -0.81 diopters.

Step by step solution

01

Understand the Problem

The student's far point is 17 cm, which means she cannot see objects clearly beyond this distance. The goal is to calculate the power of the lenses needed so that she can see clearly at 45 cm, which is the desired distance to the computer screen.
02

Use the Lens Formula

To find the required lens power, we use the formula for lens power: \[ P = \frac{1}{f} = \frac{1}{d_o} + \frac{1}{d_i} \]where \(f\) is the focal length, \(d_o\) is the distance of the object (computer screen), and \(d_i\) is the distance to the image (the student’s far point).
03

Substitute the Values

Assign the values \(d_o = -45.0\, \mathrm{cm}\) (it's taken as negative because the object is virtual with respect to the lens), and \(d_i = -17.0\, \mathrm{cm}\) (negative because the far point is beyond the eye indicating virtual image for myopic correction): \[ \frac{1}{f} = \frac{1}{-45.0} + \frac{1}{-17.0} \]
04

Calculate the Inverse Focal Length

Calculate the result of the fractions: \[ \frac{1}{f} = \frac{-1}{45.0} + \frac{-1}{17.0} = \frac{-1 \times 17 + -1 \times 45}{45 \times 17} = \frac{-17 - 45}{765} = \frac{-62}{765} \]
05

Solve for Lens Power (P)

The power of the lens \(P\) is the inverse of the focal length (in meters): \[ P = \frac{1}{f} = \frac{-62}{765} \, \text{cm}^{-1} = -0.081 \, \text{cm}^{-1} \]Convert to diopters (1 D = 100 cm):\[ P = -0.081 \, \text{cm}^{-1} \times 100 = -0.81 \, \text{D} \]
06

Final Answer

The power needed for the lenses is \(-0.81\) diopters, meaning the lenses should be diverging (negative power) to correct the myopia.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Lens Formula
The lens formula is a key concept in physics, specifically in optics, which deals with the bending of light as it passes through lenses to form images. The formula is expressed as:\[ P = \frac{1}{f} = \frac{1}{d_o} + \frac{1}{d_i} \]Here's what each variable means:
  • \(P\) is the power of the lens, measured in diopters (D). It tells us how effectively a lens can converge (positive power) or diverge (negative power) light.
  • \(f\) is the focal length of the lens, the distance from the lens to the point where it focuses light. The focal length is in centimeters or meters.
  • \(d_o\) stands for the distance between the object and the lens.
  • \(d_i\) represents the distance between the image and the lens.
The power of the lens is a real-world application that helps correct vision problems like myopia.To solve problems using the lens formula, substituting known values and solving for the unknown is key. Negative signs indicate virtual images or diverging lenses, which are crucial concepts to understand when dealing with myopia correction.
Myopia Correction
Myopia, or nearsightedness, is a common vision condition where distant objects appear blurry, while close ones remain clear. This occurs when the eyeball is too long, or the cornea is too curved. Light focuses in front of the retina instead of directly on it. Fortunately, optical lenses can correct this condition effectively. The most common method of correction involves the use of diverging lenses, which have a negative power. These lenses spread out light rays before they reach the eye, moving the focal point back onto the retina, thus allowing clear vision of distant objects. In the exercise, the student must see the computer screen clearly from 45 cm. We calculated that the required lens power is -0.81 D, indicating that diverging lenses are necessary. These lenses will adjust the light path to meet the distant point of vision with clarity. Thus, proper lens calculation is crucial for effective vision correction.
Optical Lenses
Optical lenses are transparent objects, often made of glass or plastic, that refract light. We have two main types of lenses used for different purposes in optics:
  • Converging Lenses: Also known as convex lenses, they focus incoming light rays to a point. These are used in the correction of hypermetropia (farsightedness), where distant objects are clear, but close ones are not.
  • Diverging Lenses: Also known as concave lenses, they spread out light rays, making them appear to originate from a point behind the lens. These lenses help correct myopia (nearsightedness).
To choose the right lens for vision correction, understanding its properties is essential. Diverging lenses' ability to spread light makes them ideal for correcting myopic vision problems. Calculating the correct power, as we have done, ensures that the light is correctly focused onto the retina, allowing for clear vision at requisite distances. Good comprehension of optical lenses and their applications can lead to significant improvements in problem-solving with respect to vision correction.

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Most popular questions from this chapter

\(\cdot\) A person can see clearly up close, but cannot focus on objects beyond 75.0 \(\mathrm{cm}\) . She opts for contact lenses to correct her vision. (a) Is she nearsighted or farsighted? (b) What type of lens (converging or diverging) is needed? (b) What type vision? (c) What focal-length contact lens is needed, and what is its power in diopters?

Your digital camera has a lens with a 50 \(\mathrm{mm}\) focal length and a sensor array that measures 4.82 \(\mathrm{mm} \times 3.64 \mathrm{mm}\) . Suppose you're at the zoo, and want to take a picture of a \(4.50-\mathrm{m}-\) tall giraffe. If you want the giraffe to exactly fit the longer dimension of your sensor array, how far away from the animal will you have to stand?

\(\bullet\) You are examining a flea with a converging lens that has a focal length of 4.00 \(\mathrm{cm}\) . If the image of the flea is 6.50 times the size of the flea, how far is the flea from the lens? Where, relative to the lens, is the image?

An An LCD projector (see Sec. 25.2\()\) has a projection lens with \(f\) -number of 1.8 and a diameter of 46 \(\mathrm{mm}\) . The LCD array measures 3.30 \(\mathrm{cm} \times 3.30 \mathrm{cm}\) and will be projected on a screen 8.00 m from the lens. If the array is \(800 \times 600\) pixels, what will be the dimensions of a single pixel on the screen?

Water drop magnifier. You can make a pretty good magnifying lens by putting a small drop of water on a piece of transparent kitchen wrap. Suppose your drop has an upper surface with a radius of curvature of 1.6 \(\mathrm{cm}\) and the side on the kitchen wrap is essentially flat. (a) Calculate the focal length of your water lens. (b) What's the angular magnification of the lens? (c) Suppose you place this planoconvex water lens directly onto the surface of a table, so that the tabletop is in effect about half the thickness of the drop. or 1.0 \(\mathrm{mm}_{\text { a away }}\) from the lens. Where does the image of the tabletop form, what type is it, and what is its magnification? (Use the thin lens equation here, even though the small object distance relative to the thickness of the lens makes it a poor approximation in this case.) What does this result tell you about how a simple magnifier works?
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