Object plane (specimen) Tens BACK FOCAL PLANE (SAD) incident e S 20 STRONG PREFIELD REGION Objective Image Plane (Intermediate Object Plane) B OPTIC B AXIS I Question 2. Using the geometric optics ray diagram for an objective lens above, derive: a) The lateral image magnification (ML= I/S) in terms of the object distance, A, and the image distance, B. A and B are distances from the lens plane to the object and image planes, respectively. (2) b) On what plane does the first diffraction pattern appear? (1) c) On what plane does the first image appear? (1) d) Is the image inverted relative to the object? (1)

Object plane (specimen) Tens BACK FOCAL PLANE (SAD) incident e S 20 STRONG PREFIELD REGION Objective Image Plane (Intermediate Object Plane) B OPTIC B AXIS I Question 2. Using the geometric optics ray diagram for an objective lens above, derive: a) The lateral image magnification (ML= I/S) in terms of the object distance, A, and the image distance, B. A and B are distances from the lens plane to the object and image planes, respectively. (2) b) On what plane does the first diffraction pattern appear? (1) c) On what plane does the first image appear? (1) d) Is the image inverted relative to the object? (1)

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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consider a blue ball A which hits a green ball B of the same mass as shown in the figure. The velocity of the blue ball A just before the collision is vA1 = 20 m/s with the direction as shown. The velocity of the green ball B just before the collision is vB1 = 30 m/s with direction as shown in the figure. The coefficient of restitution between the balls is 0.78. Which of the following best approximates the speed vB2 (in m/s) of the green ball just after collision? a. 25.98b. 29.40c. 15.00d. 30.00
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Concept Simulation 26.3 reviews the concepts that play a role in this problem. A converging lens has a focal length of 84.00 cm. A 10.0-cm-tall object is located 123.0 cm in front of this lens. (a) What is the image distance? (b) Is the image real or virtual? (c) What is the image height? Be sure to include the proper algebraic sign. (a) Number i (b) The image is (c) Number i Units Units
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Constants Part A The thin glass shel shown in (Figure 1) has a spherical shape with a radius of curvature of 11.0 cm, and both of its surtaces can act as mirrors, A seed 3.30 mm high is placed 15.0 cm trom the center of the mrror along the optic axis, as shown in the fgure Calculate the location of the image of this soed. Express your answer in centimeters. Submit Reougs Answer Hequtst Anw • Part 8 Calculate the height of the image of this seed. Express your anewer in milimeters. Figure 1 of 1 Subrit hequest Anewer 3.30 mm T50 cm Part C