130) A converging lens has a focal length of 10.0 cm. Locate the object if a real image islocated at a distance from the lens of (a) 20.0 cm and (b) 50.0 cm. What If? Redo thecalculations if the images are virtual and located at a distance from the lens of (c) 20.0cm and (d) 50.0 cm.131) A diverging lens has a focal length of magnitude 20.0 cm. (a) Locate the image forobject distances of (i) 40.0 cm, (ii) 20.0 cm, and (ii) 10.0 cm. For each case, statewhether the image is (b) real or virtual and (c) upright or inverted. (d) For each case,find the magnification.132) (a) Three resistors are connected in parallel as shown in Figure 6. A potential differenceof 18.0 V is maintained between points a and b. (1 ) Find the current in each resistor. (2)Calculate the power delivered to each resistor and the total power delivered to thecombination of resistors.18.0 VT3.00 0 6.00 0 9.00 aFigure 6(b) Find the currents I, l2 , and la in the circuit shown in Figure 7 following the steps belows:1) Consider the arbitrary directions of the currents as labeled in Figure 2.2) Apply Kirchhoff's junction rule to junction c;3) Apply Kirchhoff's loop rule to loops abcda and befcb and travers these loops clockwise.14.0 V1.0210.0v 6.00142.0 0Figure 7133) For the circuit shown in Figure 8, we wish to find the currents I1, 12, and 13. Use Kirchhoff'srules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on theleft side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve thejunction equation for l3. (e) Using the equation found in part (d), eliminate la from the equationfound in part (b). () Solve the equations found in parts (a) and (e) simultaneously for the twounknowns I, and 12. (g) Substitute the answers found in part (A into the junction equationfound in part (d), solving for l3. (h) What is the significance of the negative answer for l2?18.0 V5.00 08.00 01100 12.0 V11.007.00 15.00 0 560VFigure 8134) In the circuit of Figure 9, determine (a) the current in each resistor and (b) the potentialdifference across the 200-V resistor.40.0 V360 V.80.0 V200 nEs0.0 n20.0n70.0 nFigure 9

Answered: 130) A converging lens has a focal…

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)...

See similar textbooks

Similar questions

Problem 96. Indicate the single lens type (converging or diverging) and object position that will lead to the following kind of images. If no single lens system can produce the particular image indicate that this is so. A) real, upright, enlarged image. B) huge image at "infinity". C) real, enlarged, inverted image. D) tiny inverted image very near the focal point. E) real, reduced in size, inverted image. F) virtual, reduced in size, upright image. G) virtual, enlarged, upright image. H) real, inverted image that is the same size as the object. I) virtual, enlarged, inverted image. Problem 97. You are handed a converging lens and you have a ruler. Describe two different simple ways to determine the focal length of this lens. Each way should involve making only one measurement.
A) How far from a 59.0- mm -focal-length lens must an object be placed if its image is to be magnified 3.50× and be real? B)
2.1)
A tree 20m high is located 40m from the converging lens of focal length 8.00cm. a) Calculate the distance from lens to the image. B) Calculate the magnification
Problem 5: Two converging lenses, one with a focal length of 22.0 cm and the other with a focal length of 10.0 cm, are placed 25.0 cm apart with an object placed 50.0 cm in front of the converging lens. Determine (a) the position and (b) the magnification of the final image formed. (c) Show by ray tracing that the image is virtual or real, and determine the image distance and magnification. You must draw the ray diagram to scale to you may also use drawing/drafting software to draw the diagram.
2) A person whose eyes are1.5 m above ground approaches a pool of water of depth 2m and length 1.5 m. At what distance from the edge of the pool will she first see a point at the bottom of the pool?
19) A doctor examines a mole with a 15-cm focal length magnifying glass held 12.5 cm from the mole. Randomized Variables do = 12.5 cm a) What is the image distance for this configuration in meters? b) What is its magnification? c) How big is the image of a 5.00 mm diameter mole in millimeters?
In sports photography, one often needs a long telephoto lens with a large aperture. As a designer, you will work with engineers to design some new lens.“ (i) Suppose you want to have an 500mm lens with aperture f/4. Calculate the required iris diameter. Round your answer to the nearest integer and state its unit. “ |(ii) Suppose you want to have a 700mm lens with a surface area of 12271.8463mm². Calculate the f-number. Correct your answer to 2_decimal places.
2) A light bulb is 50 cm to the left of a convex lens of focal length 25 cm. The lens is placed 75 cm to the left of a convex mirror of focal length 20 cm. Light will travel from the bulb, through the convex lens to create an image. This image will then become the object for the concave mirror. The concave mirror will form the final image of the lightbulb. a) Where does the convex lens form an image of the lightbulb (relative to the lens)? b) What is the distance from the mirror to the image from the lens (hint: this will be the object distance in part c)? c) Where is the final image formed with respect to the mirror? d) Is the final image real or virtual? note: please answer all question i will definitely upvote.
2,2
24) A transparent photographic slide is placed in front of a converging lens with a focal length of 2.60 cm . The lens forms an image of the slide 14.0 cm from the lens. How far is the lens from the slide if the image is a) real, and b) virtual?
5) An object is placed in front of a circular mirror with a radius of curvature of 8 cm. A virtual image is formed 10 cm from the mirror. If the object and mirror are kept at the same location, but the radius of curvature is changed such that after is it is changed, the image formed is the opposite orientation as the image of the first radius and the magnification is 2.6 times smaller (the second image is 2.6 times smaller than the first image), what does the radius of curvature need to be in cm?

Recommended textbooks for you

College Physics

Physics

ISBN:

9781305952300

Author:

Raymond A. Serway, Chris Vuille

Publisher:

Cengage Learning

University Physics (14th Edition)

Physics

ISBN:

9780133969290

Author:

Hugh D. Young, Roger A. Freedman

Publisher:

PEARSON

Introduction To Quantum Mechanics

Physics

ISBN:

9781107189638

Author:

Griffiths, David J., Schroeter, Darrell F.

Publisher:

Cambridge University Press

College Physics

Physics

ISBN:

9781305952300

Author:

Raymond A. Serway, Chris Vuille

Publisher:

Cengage Learning

University Physics (14th Edition)

Physics

ISBN:

9780133969290

Author:

Hugh D. Young, Roger A. Freedman

Publisher:

PEARSON

Introduction To Quantum Mechanics

Physics

ISBN:

9781107189638

Author:

Griffiths, David J., Schroeter, Darrell F.

Publisher:

Cambridge University Press

Physics for Scientists and Engineers

Physics

ISBN:

9781337553278

Author:

Raymond A. Serway, John W. Jewett

Publisher:

Cengage Learning

Lecture- Tutorials for Introductory Astronomy

Physics

ISBN:

9780321820464

Author:

Edward E. Prather, Tim P. Slater, Jeff P. Adams, Gina Brissenden

Publisher:

Addison-Wesley

College Physics: A Strategic Approach (4th Editio…

Physics

ISBN:

9780134609034

Author:

Randall D. Knight (Professor Emeritus), Brian Jones, Stuart Field

Publisher:

PEARSON

SEE MORE TEXTBOOKS

130) 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 and (0) 50.0 cm.