Table of contents

0. Math Review31m
- Math Review
  31m
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

Thin Lens And Lens Maker Equations

Physics

33. Geometric Optics

Thin Lens And Lens Maker Equations

Previous problemNext problem

3:50 minutes

Problem 108

Textbook Question

An astronomical telescope, Fig. 33–36, produces an inverted image. One way to make a telescope that produces an upright image is to insert a third lens between the objective and the eyepiece, Fig. 33–39b. To have the same magnification, the non-inverting telescope will be longer. Suppose lenses of focal length 150 cm, 1.5 cm, and 10 cm are available. Where should these three lenses be placed to make a non-inverting telescope with magnification 100x?

Verified step by step guidance

Step 1: Understand the problem. A non-inverting telescope requires three lenses: an objective lens, an eyepiece lens, and an additional lens (erecting lens) to make the image upright. The magnification of the telescope is given as 100x, and the focal lengths of the lenses are provided: 150 cm (objective), 1.5 cm (eyepiece), and 10 cm (erecting lens). The task is to determine the placement of these lenses to achieve the desired magnification and upright image.

Step 2: Recall the formula for magnification in a telescope. The magnification (M) is given by the ratio of the focal length of the objective lens (fₒ) to the focal length of the eyepiece lens (fₑ):

M = \frac{f_{o}}{f_{e}}

. Substitute the given magnification (M = 100) and the focal lengths of the objective and eyepiece lenses to verify the relationship:

100 = \frac{150}{1.5}

. This confirms the magnification is correct with these lenses.

Step 3: Determine the placement of the erecting lens. The erecting lens is placed between the objective and the eyepiece to invert the inverted image produced by the objective lens, making the final image upright. The erecting lens should be positioned such that its focal length (10 cm) allows it to re-invert the image. The exact placement depends on the intermediate image formed by the objective lens, which is at its focal length (150 cm) from the objective. The erecting lens should be placed slightly beyond this intermediate image to ensure proper inversion.

Step 4: Calculate the total length of the telescope. The total length of the telescope is the sum of the distances between the objective lens, the erecting lens, and the eyepiece lens. The distance between the objective and the erecting lens is approximately 150 cm (focal length of the objective), and the distance between the erecting lens and the eyepiece lens is adjusted to ensure the final image is at infinity. This distance is approximately the sum of the focal lengths of the erecting lens (10 cm) and the eyepiece lens (1.5 cm).

Step 5: Summarize the lens placements. Place the objective lens at the starting point. Position the erecting lens approximately 150 cm from the objective lens. Finally, place the eyepiece lens approximately 11.5 cm (10 cm + 1.5 cm) from the erecting lens. This configuration ensures a non-inverting telescope with a magnification of 100x.

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above

Video duration:

Play a video:

Was this helpful?

Key Concepts

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

Magnification in Telescopes

Magnification in telescopes refers to the ratio of the angular size of the image produced by the telescope to the angular size of the object being observed. It is determined by the focal lengths of the objective and eyepiece lenses. For a non-inverting telescope, the magnification can be calculated using the formula M = f_objective / f_eyepiece, where f represents the focal length. Achieving a specific magnification, such as 100x, requires careful selection and arrangement of the lenses.

Lens Arrangement and Focal Lengths

The arrangement of lenses in a telescope is crucial for achieving the desired image characteristics, including orientation and magnification. The focal lengths of the lenses determine how they interact with incoming light. Inserting a third lens can help correct the image orientation while maintaining the overall magnification. The placement of each lens affects the total length of the telescope and the final image produced.

Inverted vs. Upright Images

In telescopes, the image produced by the objective lens is typically inverted due to the way light converges. To create an upright image, additional optical elements, such as a third lens, can be introduced. This lens can invert the image again, resulting in an upright final image. Understanding how lenses manipulate light and image orientation is essential for designing telescopes that meet specific observational needs.

Watch next

Master Thin Lens Equation with a bite sized video explanation from Patrick

Start learning

Related Videos

Related Practice

Textbook Question

(II) A diverging lens is placed next to a converging lens of focal length ƒ_C , as in Fig. 33–14. If ƒ_T represents the focal length of the combination, show that the focal length of the diverging lens, ƒ_D , is given by

1/ƒ_D = (1/ƒ_T) - (1/ƒ_C)

731

views

Textbook Question

(II) In a film projector, the film acts as the object whose image is projected on a screen (Fig. 33–46). If a 105-mm-focal-length lens is to project an image on a screen 22.5 m away, how far from the lens should the film be? If the film is 24 mm wide, how wide will the picture be on the screen?

604

views

Textbook Question

Figure 33–51 was taken from the NIST Laboratory (National Institute of Standards and Technology) in Boulder, CO, 2.0 km from the hiker in the photo. The Sun’s image was 15 mm across on the film. Estimate the focal length of the camera lens (actually a telescope). The Sun has diameter 1.4 x 10⁶ km, and it is 1.5 x 10⁸ km away.

<IMAGE>

286

views

Textbook Question

(II) A planoconvex lens (Fig. 33–2a) has one flat surface and the other has R = 15.3 cm. This lens is used to view a red and yellow object which is 62.0 cm away from the lens. The index of refraction of the glass is 1.5106 for red light and 1.5226 for yellow light. What are the locations of the red and yellow images formed by the lens?

467

views

Textbook Question

The focal length f of a converging lens can be found by placing an object of known size at various locations in front of the lens and measuring the resulting real-image distances dᵢ and their associated magnifications m (minus sign indicates that image is inverted). The data taken in such an experiment are given here:

(a) Show algebraically that a graph of m vs. dᵢ should produce a straight line. What are the theoretically expected values for the slope and the y-intercept of this line? [Hint: dₒ is not constant.] (b) Using the data above, graph m vs. dᵢ and show that a straight line does indeed result. Use the slope of this line to determine the focal length of the lens. Does the y-intercept of your plot have the expected value?

230

views

Textbook Question

BIO The Lens of the Eye. The crystalline lens of the human eye is a double-convex lens made of material having an index of refraction of 1.44 (although this varies). Its focal length in air is about 8.0 mm, which also varies. We shall assume that the radii of curvature of its two surfaces have the same magnitude. Find the radii of curvature of this lens.

162

views

Textbook Question

A 1.0-cm-tall object is 110 cm from a screen. A diverging lens with focal length -20 cm is 20 cm in front of the object. What are the focal length and distance from the screen of a second lens that will produce a well-focused, 2.0-cm-tall on the screen?

views

Textbook Question

A 15-cm-focal-length converging lens is 20 cm to the right of a 7.0-cm-focal-length converging lens. A 1.0-cm-tall object is distance L to the left of the 7.0-cm-focal-length lens. What are the height and orientation of the final image?

views

Show more practices

Download the Mobile app

Privacy

Do not sell my personal information

Accessibility

Patent notice

Sitemap