You are imaging a pencil through a thin, converging lens as shown in the image below. If p (the distance from the object to the center of the thin lens) is 6.86m and the focal length of the thin lens is 1.4m, how far away (in meters) from the center of the thin lens is the real image located (the real image will be on the right-side of the lens in this particular example illustrated below)? Converging lens Ray 1 Ray 1 focal point Ray 2 ਨੂੰ Secondary Ray 3 focal point Ray 3 Object Principal Real image

You are imaging a pencil through a thin, converging lens as shown in the image below. If p (the distance from the object to the center of the thin lens) is 6.86m and the focal length of the thin lens is 1.4m, how far away (in meters) from the center of the thin lens is the real image located (the real image will be on the right-side of the lens in this particular example illustrated below)? Converging lens Ray 1 Ray 1 focal point Ray 2 ਨੂੰ Secondary Ray 3 focal point Ray 3 Object Principal Real image

University Physics Volume 3

17th Edition

ISBN:9781938168185

Author:William Moebs, Jeff Sanny

Publisher:William Moebs, Jeff Sanny

Chapter2: Geometric Optics And Image Formation

Section: Chapter Questions

Problem 64P: Two convex lenses of focal lengths 20 cm and 10 cm are placed 30 cm apart, with the lens with the...

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You are imaging a pencil through a thin, converging lens as shown in the image below. If p (the distance from the object to the center of the thin lens) is 10m and the focal length of the thin lens is 1.26m, how far away (in meters) from the center of the thin lens is the real image located (the real image will be on the right side of the lens in this particular example illustrated below)?
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