3. A system is formed from a diverging and converging lens as show in the figure. Thepoint labeled Feomerying is the focal point of the converging lens. An object is placed at adistance of 9 cm to the left of the diverging lens. The distance between the lenses is 24cm. The focal lengths of the diverging and converging lenses are -18 cm and 14 cm,respectively.#31Object#2converginga. Find the image distance d (relative to lens 1) of the image produced by lens I.Find the object distance daz relative to lens 2. (Include proper algebraic sign)Image distance du6 cmObject distance dat30 cmb. Find the final image distance dz (relative to lens 2). Include the proper algebraicsign.26.25 cmc. Find the overall magnification.-0.5833

Answered: Image /qna-images/answer/684e6dfe-b521-4c15-a3b0-1076c7e88522.jpg

A system is formed from a diverging and converging lens as shown in the figure. The point labeled Feonenging is the focal point of the converging lens. An object is placed at a distance of 9 cm to the left of the diverging lens. The distance between the lenses is 24 cm. The focal lengths of the diverging and converging lenses are -18 cm and 14 cm, respectively. Object conging a. Find the image distance d (relative to lens 1) of the image produced by lens I. Find the object distance daa relative to lens 2. (Include proper algebraic sign) Image distance dy 6 cm Object distance das 30 cm b. Find the final image distance dz (relative to lens 2). Include the proper algebraic sign. 26.25 cm c. Find the overall magnification.

A system is formed from a diverging and converging lens as shown in the figure. The point labeled Feonenging is the focal point of the converging lens. An object is placed at a distance of 9 cm to the left of the diverging lens. The distance between the lenses is 24 cm. The focal lengths of the diverging and converging lenses are -18 cm and 14 cm, respectively. Object conging a. Find the image distance d (relative to lens 1) of the image produced by lens I. Find the object distance daa relative to lens 2. (Include proper algebraic sign) Image distance dy 6 cm Object distance das 30 cm b. Find the final image distance dz (relative to lens 2). Include the proper algebraic sign. 26.25 cm c. Find the overall magnification.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter25: Optical Instruments

Section: Chapter Questions

Problem 17P

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Similar questions

A particular nearsighted patient cant see objects clearly beyond 15.0 cm from their eye. Determine (a) the lens power required to correct the patients vision and (b) the type of lens required (converging or diverging). Neglect the distance between the eye and the corrective lens.
The near point of an eye is 75.0 cm. (a) What should be the power of a corrective lens prescribed to enable the eye to see an object clearly at 25.0 cm? (b) If, using the corrective lens, the person can see an object clearly at 26 0 cm but not at 25.0 cm, by how many diopters did the lens grinder miss the prescription?
A converging lens has a focal length of 10.0 cm. Locate the object if a real image is located at a distance from the lens of (a) 20.0 cm and (b) 50.0 cm. What If? Redo the calculations if the images are virtual and located at a distance from the lens of (c) 20.0 cm and (d) 50.0 cm.
If the lens of a person’s eye is removed because of cataracts (as has been done since ancient times), why would you expect a spectacle lens of about 16 D to be prescribed?
A microscope has an objective lens with a focal length of 16.22 mm and an eyepiece with a focal length of 9.50 mm. With the length of the barrel set at 29.0 cm, the diameter of a red blood cells image subtends an angle of 1.43 mrad with the eye. It the final image distance is 29.0 cm from the eyepiece, what is the actual diameter of the red blood cell? Hint: To solve this question, go back to basics and use the thin-lens equation.
A microscope has an objective lens with a focal length of 16.22 mm and an eyepiece with a focal length of 9.50 mm. With the length of the barrel set at 29.0 cm, the diameter of a red blood cells image subtends an angle of 1.43 mrad with the eye. It the final image distance is 29.0 cm from the eyepiece, what is the actual diameter of the red blood cell? Hint: To solve this question, go back to basics and use the thin-lens equation.
Show that the magnification of a thin lens is given by M = di/do (Eq. 38.6). Hint: Follow the derivation of the lens makers equation (page 1233) and start with a thick lens.
A converging lens made of crown glass has a focal length of 15.0 cm when used in air. If the lens is immersed in water, what is its focal length? (a) negative (b) less than 15.0 cm (c) equal to 15.0 cm (d) greater than 15.0 cm (e) none of those answers