please answer question ASAP Correctly only if d. + d=d is larger than 4 times the...
Need help ALL REVIEW VIEW Help Problem 4: Convex mirror (4 points) Use the ray diagram to predict the appearance and the position of the image of the arrow shown below. Clearly show the images of numbers and then connect them to complete the full image 3 F OF 5
A concave spherical mirror forms an inverted image 4.00 times larger than the object. Assuming the distance between object and image is 0.500 m, find the focal length of the mirror. The magnification gives a relationship between p and q. If you know the distance between the object and image, how do you determine the individual values of p and q? m Suppose the mirror is convex. The distance between the image and the object is the same as in...
(a) A concave spherical mirror forms an inverted image 4.00 times larger than the object. Assuming the distance between object and image is 0.500 m, find the focal length of the mirror. (b) Suppose the mirror is convex. The distance between the image and the object is the same as in part (a), but the image is 0.500 the size of the object. Determine the focal length of the mirror.
Could someone please help complet Table 1 and Table 2 Lab 12 Concave and Convex Lenses PHYS 1110L Conceptual Physics Lab Name: Date: Results:-- -(90 pts max) OBJECTIVES To demonstrate the formation of images from convex and concave lenses. To identify the type of image formed by convex and concave lenses. - To confirm the lens equations. PART 1 CONVEX LENS 1. Open GOOGLE CHROME or other compatible browser and DISABLE all BROWSER POP-UP BLOCKERS 2. Go to PhET Simulations...
please answer correctly asap 1 1 Problem 2: Two lens system (3 points) When two thin lenses are in contact, the combination may still be considered as a thin lens. The focal distance of the combination, fc, is given by 1 ==+ eq. (1) fc fi 12 where f and 12 are the focal distances of the two lenses in contact. Assume two converging lenses (10 cm and 20 cm focal distances) are in contact and do -15 cm. a)...
webassign.net Active Figure 26.25 Thin Lenses The animation below shows a thin lens, an object (blue arrow) and an image (tan arrow). Three rays are shown that locate the positic orientation, and size of the image. Readouts are provided for object distance, object height, image distance and image height. Instructions: Click and drag the blue object. Click the button in the lower left of the applet window to toggle between a conc convex lens. Explore Images formed by thin lenses...
Explain answers thoroughly, and ignore air resistance and gravity. I dont expect an answer for number 2 or 3. I just am wanting an answer for the extra credit question, number 4. Thanks! 2. A convex mirror has a radius of curvature of 4 m. A boy stands in front of the mirror so that he appears 3 times shorter than his actual height. If the image is upright, how far is he standing from the mirror? Explain if the...
d d h h; f m 12 6 I 2 -1 4 -0.5 11 6.29 2 -1.14 4 -0.57 10 6.67 2 -1.33 4. -0.66 9 7.2 2 -1.6 4. -0.8 8 8 2 -2 4 - 1 7 9.33 2 -2.67 4 -1.33 6 12 2 -4 4 average 7.9 2 -2 4 5. Was the average of the experimental focal lengths close to the true value of 4? If not, then go back and re-check your measurements and...
the A constant electric current to bote the recircular loop of wire as shown vention that the arrow indicating the direction of current is drawn in the loround of the dico). A smaller powe r ed through the center of the larger loop Based on this diagram answer Question 6 below. draw ascow on this loce Bind Question 6: As the small wire loop approaches the larger loop, which direction will the induced current flow in the small wireloop? Please...
Please help with number 4 please I'm so lost Use a ray diagram to determine the location of the image for the following problem: an object is placed 15 mm away from a concave mirror with a focal length of 10 mm. Use the mirror formula to check your diagram Use a ray diagram to determine the location of the image for the following problem: an object is placed 15 mm in front of a convex mirror and an image...