In the figure below, a diverging lens and concave spherical mirror are positioned along an optical axis, with an object half way between the two. The distance between the lens and mirror is d = 23.7 cm. The magnitude of the mirror's radius of curvature is 20.5 cm, and the lens has a focal length of fiens-18.4 cm. Lens Object Mirror O (a) Considering only the light that leaves the object and travels first toward the mirror, locate the final image formed by this system. (Give the magnitude of the image distance in cm, and select its location with respect to the lens.) image distance x Apply the mirror equation to find the image formed by the mirror, which serves as an object for the lens. Then apply the thin-lens equation. cm image location to the right of the lens ✔✔✔✔ (b) Is this image real or virtual? O real Ⓒ virtual (c) Is it upright or inverted? Ⓒupright O inverted (d) What is the overall magnification?

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Chapter1: Units, Trigonometry. And Vectors
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In the figure below, a diverging lens and concave spherical mirror are positioned along an optical axis, with an object half way between the two. The distance between the lens and mirror is d = 23.7 cm. The magnitude of the mirror's radius of curvature is 20.5 cm, and the
lens has a focal length of flens = -18.4 cm.
Lens Object Mirror
I
(a) Considering only the light that leaves the object and travels first toward the mirror, locate the final image formed by this system. (Give the magnitude of the image distance in cm, and select its location with respect to the lens.)
image distance
image location
Apply the mirror equation to find the image formed by the mirror, which serves as an object for the lens. Then apply the thin-lens equation. cm
to the right of the lens
(b) Is this image real or virtual?
O real
O virtual
(c) Is it upright or inverted?
Ⓒupright
O inverted
(d) What is the overall magnification?
X
Transcribed Image Text:In the figure below, a diverging lens and concave spherical mirror are positioned along an optical axis, with an object half way between the two. The distance between the lens and mirror is d = 23.7 cm. The magnitude of the mirror's radius of curvature is 20.5 cm, and the lens has a focal length of flens = -18.4 cm. Lens Object Mirror I (a) Considering only the light that leaves the object and travels first toward the mirror, locate the final image formed by this system. (Give the magnitude of the image distance in cm, and select its location with respect to the lens.) image distance image location Apply the mirror equation to find the image formed by the mirror, which serves as an object for the lens. Then apply the thin-lens equation. cm to the right of the lens (b) Is this image real or virtual? O real O virtual (c) Is it upright or inverted? Ⓒupright O inverted (d) What is the overall magnification? X
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