(5) A real object is located 7.00cm to the left of a thin diverging lens. The image is a distance of 3.33cm away from the lens. (a) Use the thin lens equation to predict the focal length of the lens. (b) Identify the image as real/virtual, upright/inverted, and enlarged/reduced. (c) A thin converging lens (f = 8.26cm) is placed 9.19cm to the right of the diverging lens. Use the thin lens equation to predict the distance between the location of the final image of the two lens system and the original real object. (d) If we removed the converging lens from part (c) and replaced the diverging lens from this problem with a mirror with the exact same focal length as the diverging lens, how (if at all) would your answer to part (b) change?

(5) A real object is located 7.00cm to the left of a thin diverging lens. The image is a distance of 3.33cm away from the lens. (a) Use the thin lens equation to predict the focal length of the lens. (b) Identify the image as real/virtual, upright/inverted, and enlarged/reduced. (c) A thin converging lens (f = 8.26cm) is placed 9.19cm to the right of the diverging lens. Use the thin lens equation to predict the distance between the location of the final image of the two lens system and the original real object. (d) If we removed the converging lens from part (c) and replaced the diverging lens from this problem with a mirror with the exact same focal length as the diverging lens, how (if at all) would your answer to part (b) change?

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter26: Image Formation By Mirrors And Lenses

Section: Chapter Questions

Problem 70P

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