a 2.5cm high object is located 5cm in front of a diverging lens of focal length 7cm.
Using a scaled diagram sketch the image formation
Calculate image distance and height
Calculate magnification
State the reason for a real or virtual image
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A 2.5cm high object is located 5cm in front of a diverging lens of focal length 7cm. Sketch the image formed using a scaled drawing of a ray diagram. Determine image height and distance. Calculate the magnification. State the reason, for a vitual or real
1.) An object is placed in front of a diverging lens with a focal length of 17.7 cm. For each object distance, find the image distance and the magnification. Describe each image. (a) 35.4 cm location _____cm magnification _____ nature real virtual upright inverted (b) 17.7 cm location _____ cm magnification _____ nature real virtual upright inverted (c) 8.85 cm location _____ cm magnification _____ nature real virtual upright inverted 2.) An object is placed in front of a converging lens...
A 20 cm tall object is located 70 cm away from a diverging lens
that has a focal length of 20 cm. Use a scaled ray tracing to
answer parts a-d.
a. Is the image real or virtual?
b. Is the image upright or inverted?
c. How far from the lens is the image?
d. What is the height of the image?
e. Now use the thin lens equation to calculate the image
distance and the magnification equation to determine...
A converging lens L_1 has a focal length of 10 cm. A 5cm tall object is located 15cm to the left of L_1. Construct a ray diagram indicating the position and vertical orientation of the image produced by lens L_1. Calculate this position and see that it matches your diagram. A diverging lens L_2 with a focal length of -20 cm is placed 40cm on the right of lens L_1. The image in (a) above now serves as the object...
An object is placed in front of a diverging lens with focal length of −70 cm. Find the location of the image and the characteristics of the image (real or virtual, enlarged or reduced, and upright or inverted) for each object distance. Also draw the ray diagram for each object distance. a) 100 cm b) 40 cm
A diverging lens with a focal length of -3.5cm is 15cm from a 2.5cm-tall small lightbulb. A. Predict the location and height of the resulting image. Is it real or virtual? inverted or upright? B. Now a converging lens with focal length of 3cm is placed halfway between the diverging lens and the light. Predict the location, whether it is real or virtual, and the height produced by the combined lenses. C. Draw a ray diagram for the combination in...
A 4.0 cm tall object is 5.0 cm in front of a diverging lens with a focal length of -6.0 cm. A converging lens with a focal length of 6.0 cm is located 8.0 cm behind the diverging lens. (As viewed from the side, from left to right, the sequence is object - diverging lens - converging lens - observer. Rays then travel from left to right through the system.) (a) Use ray tracing to draw image 1 and image...
A diverging lens has a focal length of 65 cm. It is located 90 cm from an object. a. Draw the ray tracing diagram to locate the image. Is the image real or virtual? b. Calculate the image location and the magnification for the image. Compare your results with part a.
A real object is 13.6 cm to the left of a thin, diverging lens having a focal length of magnitude 24.5 cm. (a) is the sign of the focal length negative or positive? negative positive (b) Find the image distance. (c) Find the magnification. (d) State whether the image is real or virtual. real virtual (e) State whether the image is upright or inverted. upright inverted
a) Suppose an object is placed 7.50cm from a converging lens with a 5cm focal length. Use ray tracing to get the image and measure image distance. Describe the image: (upright or inverted, real or virtual, bigger or smaller). b) Use the lens equations to calculate the location of the image and its magnification. Describe the image: (upright or inverted, real or virtual, bigger or smaller).
A diverging lens has a focal length of magnitude 22.6 cm. (a) Locate the images for each of the following object distances. 45.2 cm distance cm location (behind or in front of lens) 22.6 cm distance cm location (behind or in front of lens) 11.3 cm distance cm location (behind or in front of lens) (b) Is the image for the object at distance 45.2 real or virtual? Is the image for the object at distance 22.6 real or virtual?...