Lenses Q1 Goal: Understand the lens and how it produces images.-35.0 cm-2.50 mmOptic St20cmaxisObjectLens15.0cm ImageThe figure shows an object and its image formed by a thin lens.8.6cm(a) What is the focal length of the lens? What type of lens is it?Check matht'+=dodift20.0 15.0f8.6cm-fdo: 20.0cm di=15.0cm f= ?The Lens is convex lensbecause the focal lengthIs Positive.bow pay 11 (d(b) What is the height of the image? Is it a real or virtual image?siq ad ens! od blode Hawdi=150mm The image is on the opposite sidedo 200mm of the object so it's a real image.=ho=2.50mmm = -dihidohohi-150mm200mmhi2.50mm6.250ma fullImageWhy?-375mm-hi 200mm200mm-1, 87mm hi206 mmto the cavex(c) The top half of the lens is covered with a notecard. Describe the image that is formed. If noimage is formed, state so explicitly. Explain your reasoning.A full image would be formed. This is because

Answered: Image /qna-images/answer/5bb44643-ae27-4d1e-b981-8bd7aa5faf8a.jpg

Goal: Understand the lens and how it produces images. -35.0 cm- A 2.50 mm Optic sunt дост axis Object Lens 15.0 cm Image ст - The figure shows an object and its image formed by a thin lens. (a) What is the focal length of the lens? What type of lens is it? atht 41-0 do: 20.0cm di=15.0cm f= ? = do di f = 1 20.0 15.0 F 8.6cm-f The Lens is convex lens because the focal length Is Positive. (b) What is the height of the image? Is it a real or virtual image? m = -di -150mm - 200mm do = hi ho hi 2.50mm hi2comm bow w asiq od eno od bliroda Hawa di=150mm The image is on the opposite side do: 200mm of the object So it's a real image. ho=2.60mm hi- 6:25 cm

Goal: Understand the lens and how it produces images. -35.0 cm- A 2.50 mm Optic sunt дост axis Object Lens 15.0 cm Image ст - The figure shows an object and its image formed by a thin lens. (a) What is the focal length of the lens? What type of lens is it? atht 41-0 do: 20.0cm di=15.0cm f= ? = do di f = 1 20.0 15.0 F 8.6cm-f The Lens is convex lens because the focal length Is Positive. (b) What is the height of the image? Is it a real or virtual image? m = -di -150mm - 200mm do = hi ho hi 2.50mm hi2comm bow w asiq od eno od bliroda Hawa di=150mm The image is on the opposite side do: 200mm of the object So it's a real image. ho=2.60mm hi- 6:25 cm

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 99P: An amoeba is 0.305 cm away from the 0.300 cm- focal length objective lens of a microscope. (a) Where...

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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.
In Figures CQ36.11a and CQ36.11b, which glasses correct nearsightedness and which correct farsightedness?
A particular patients eyes are unable to focus on objects closer than 35.0 cm and corrective lenses are to be prescribed so that the patient can focus on objects 20.0 cm from their eyes. (a) Is the patient nearsighted or farsighted? (b) If contact lenses are to lie prescribed, determine the required lens power. (c) If eyeglasses are to be prescribed instead and the distance between the eyes and the lenses is 2.00 cm, determine the power of the required corrective lenses. (d) Are the required lenses converging or diverging?
A person sees clearly wearing eyeglasses that have a power of 4.00 diopters when the lenses are 2.00 cm in front of the eyes. (a) What is the focal length of the lens? (b) Is the person nearsighted or farsighted? (c) If the person wants to switch to contact lenses placed directly on the eyes, what lens power should be prescribed?
An amoeba is 0.305 cm away from the 0.300 cm- focal length objective lens of a microscope. (a) Where is the image formed by the objective lens? (b) What is this image’s magnification? (C) An eyepiece with a 2.00-cm focal length is placed 20.0 cm from the objective. Where is the final image? (d) What angular magnification is produced by the eyepiece? (e) What is the overall magnification? (See Figure 2.39.)
An individual is nearsighted; his near point is 18.0 cm and his far point is 50.0 cm. (a) What lens power is needed to correct his nearsightedness? (b) When the lenses are in use, what is this persons near point?
(a) What is the maximum angular magnification of an eyeglass lens having a focal length of 18.0 cm when used as a simple magnifier? (b) What is the magnification of this lens when the eye is relaxed?
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.
A diverging lens has a focal length of magnitude 20.0 cm (a) Locate the images for object distances of (i) 40.0 cm. (ii) 20.0 cm, and (iii) 10.0 cm. For each case, state whether the image is (b) real or virtual and (c) upright or inverted. (d) For each case, Find the magnification.
(a) Where does an object need to be placed relative to a microscope for its 0.500 cm focal leng1h objective to produce a magnification of 400? (b) Where should the 5.00 cm focal length eyepiece be placed to produce a further fourfold (4.00) magnification?
(a) What is the maximum angular magnification of an eyeglass lens having a focal length of 18.0 cm when used as a simple magnifier? (b) What is the magnification of this lens when the eye is relaxed?
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