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Chapter 25: Problem 15

.. In a museum devoted to the history of photography, you are setting up a projection system to view some historical 4.0 inch \(\times 5.0\) inch color slides. Your screen is 6.0 \(\mathrm{m}\) from the projector lens, and you want the image to be 4.0 ft \(\times 5.0\) ft on the screen. (a) What focal-length lens do you need? (b) How far from the lens should you put the slide?

Short Answer

Expert verified
Focal length = 455 mm, slide distance = 500 mm from lens.

Step by step solution

01

Understand the Problem

We need to project an image from a slide with dimensions 4.0 inches by 5.0 inches onto a screen, where the image needs to be 4.0 ft by 5.0 ft. The distance from the projector to the screen is 6.0 m. We're asked to find the focal length of the lens required and the distance the slide should be placed from the lens.
02

Convert Units

Convert the dimensions of the image on the screen from feet to inches, because the slide dimensions are in inches: 1 ft is 12 inches, so 4.0 ft is 48 inches and 5.0 ft is 60 inches.
03

Calculate Magnification

The magnification, \( M \), is the ratio of the image dimensions to the object dimensions. Calculate \( M \) using either the width or height. Here, using width: \( M = \frac{48}{4} = 12 \).
04

Use the Lens Formula

Use the lens formula, \( \frac{1}{f} = \frac{1}{d_o} + \frac{1}{d_i} \), where \( f \) is the focal length, \( d_o \) is the object distance (distance from slide to lens), and \( d_i \) is the image distance (distance from lens to screen, 6.0 m or 6000 mm).
05

Relate Magnification to Distances

The magnification also relates the distances: \( M = \frac{d_i}{d_o} \). Thus, \( d_o = \frac{d_i}{M} = \frac{6000 \text{ mm}}{12} = 500 \text{ mm} \).
06

Solve for Focal Length

Substitute \( d_o = 500 \text{ mm} \) and \( d_i = 6000 \text{ mm} \) into the lens formula: \( \frac{1}{f} = \frac{1}{500} + \frac{1}{6000} \). Calculate \( \frac{1}{f} = \frac{1}{500} + \frac{1}{6000} \approx 0.0022 \), so \( f \approx \frac{1}{0.0022} \approx 455 \text{ mm} \).
07

Conclusion

The focal length needed for the lens is approximately 455 mm, and the slide should be placed 500 mm from the lens.

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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 fundamental equation in optics that relates the focal length of a lens to the object and image distances. The formula is: \[ \frac{1}{f} = \frac{1}{d_o} + \frac{1}{d_i} \]Where:
  • \(f\) is the focal length of the lens,
  • \(d_o\) is the distance from the object (here, the slide) to the lens,
  • \(d_i\) is the distance from the lens to the image (distance to the screen in this exercise).
In this exercise, the image distance, \(d_i\), is given as 6000 mm (6.0 m). Finding \(d_o\) requires using the magnification, as both these distances tie together with it.By plugging \(d_o\) and \(d_i\) into the lens formula, you can solve for the focal length \(f\) which ends up governing how focused or sharp the image will be on the screen.The closer the object distance to the required focal point, the clearer the image will appear.
Magnification
Magnification is the process of enlarging the appearance of an object through an optical system. In our scenario, the magnification, \(M\), is the ratio of the image size on the screen to the size of the actual slide. This can be calculated using:\[ M = \frac{h_i}{h_o} = \frac{d_i}{d_o} \]Where:
  • \(h_i\) is the image height on the screen,
  • \(h_o\) is the original slide height,
  • \(d_i\) is the image (or screen) distance,
  • \(d_o\) is the object (or slide) distance.
For our projection system problem, the magnification is found by comparing the width (or height) of the projected image and the original slide. Here it is calculated as 12. This magnification factor scales up the dimensions of the slide proportionally to the final image on the screen. Once known, it also informs how to position the slide relative to the lens for the desired outcome.
Focal Length
The focal length of a lens is a critical factor in determining how it will focus light and create an image. It is defined as the distance between the lens and the point where parallel rays of light converge to a single point. In this exercise, the focal length necessary to project the slide clearly onto the screen is approximately 455 mm. This value indicates the strength and precision of the lens needed to ensure the final image is well-focused and reaches the desired size. The choice of focal length depends on:
  • The distance between the object and the image,
  • The required image size on the screen,
  • And the physical space available for the projection setup.
A lens with the right focal length ensures that each part of your slide is accurately magnified and displayed on the screen, creating a crisp and proportional image.
Projection System
A projection system is crucial for enlarging small images or slides onto bigger screens. It consists of three main components: the object (slide), the lens, and the screen. In this setup, the objective is to convert a small picture into a much larger one that maintains fidelity to the original. The process works as follows:
  • Light travels through the lens from the slide, bending and altering the path to enhance size and visibility.
  • The focal length of the lens determines how light rays are focused onto the screen.
  • The distance between each part (slide to lens, and lens to screen) plays a key role in clarity and size.
Achieving the desired image size, as seen in this exercise, involves adjusting the slide's placement and selecting a lens with the correct focal length. A meticulous alignment of these factors results in a well-projected image. The system must also account for potential distortion or focus issues, ensuring the lens selected can accommodate all requirements for the intended display.

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Most popular questions from this chapter

Crystalline lens of the eye. The crystalline lens of the eye is double convex and has a typical index of refraction of \(1.43 .\) At minimum power, the front surface has a radius of 10.0 \(\mathrm{mm}\) and the back surface has a radius of 6.0 \(\mathrm{mm}\) ; at maximum power, these radii are 6.0 \(\mathrm{mm}\) and 5.5 \(\mathrm{mm}\) , respectively (although the values do vary from person to person). (a) Find the maximum and minimum power (in diopters) of the crystalline lens if it were in air. (b) What is the range of focal lengths the eye can achieve? (c) At minimum power, where does it focus the image of a very distant object? (d) At maximum power, where does it focus the image of an object at the near point of 25 \(\mathrm{cm} ?\)

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 A microscope with an objective of focal length 8.00 \(\mathrm{mm}\) and an eyepiece of focal length 7.50 \(\mathrm{cm}\) is used to project an image on a screen 2.00 \(\mathrm{m}\) from the eyepiece. Let the image distance of the objective be 18.0 \(\mathrm{cm} .\) (a) What is the lateral magnification of the image? (b) What is the distance between the objective and the eyepiece?

\(\cdot\) A certain digital camera having a lens with focal length 7.50 \(\mathrm{cm}\) focuses on an object 1.85 m tall that is 4.25 \(\mathrm{m}\) from the lens. (a) How far must the lens be from the sensor array? (b) How tall is the image on the sensor array? Is it erect or inverted? Real or virtual? (c) A SLR digital camera often has pixels measuring 8.0\(\mu \mathrm{m} \times 8.0 \mu \mathrm{m} .\) How many such pixels does the height of this image cover?

\(\cdot\) A compound microscope has an objective lens of focal length 10.0 \(\mathrm{mm}\) with an eyepiece of focal length \(15.0 \mathrm{mm},\) and it produces its final image at infinity. The object to be viewed is placed 2.0 \(\mathrm{mm}\) beyond the focal point of the objective lens. (a) How far from the objective lens is the first image formed? (b) What is the overall magnification of this microscope?
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