A convex mirror with a focal length of -3m is sitting 5m from a bookshelf.
a. Draw a ray tracing diagram to find where the image is. b. Use the mirror equation to check your result and to find where the image will be if the bookshelf is 2m away. c. Repeat a and b with a converging lens with a focal length of 4m.A convex mirror with a focal length of -3m is sitting 5m from a bookshelf. a. Draw a ray tracing diagram to find where...
To practice Tactics Box 18.5 Ray tracing for a convex mirror. The procedure known as ray tracing is a pictorial method for understanding image formation when lenses or mirrors are used. It consists in locating the image by the use of just three "special rays." The following Tactics Box explains this procedure for the case of a convex mirror. The diagram below shows the situation described in the problem. The focal length of the mirror is labeled f the scale...
Draw a ray diagram to scale for a convex lens with a focal length of +15 cm and an object 45 cm away.
2. An object is 30 cm in front of a convex mirror with a focal length of 20 cm. Using ray tracing and thin lens equation, determine whether the image is real/virtual, upright/inverted, reduced/magnified.
2. An object is 30 cm in front of a convex mirror with a focal length of 20 cm. Using ray tracing and thin lens equation, determine whether the image is real/virtual, upright/inverted, reduced/magnified.
PHYS 203 Name: Ray Tracing Name: Work in pairs. Turn in one copy per pair Part A: Ray Tracing (18 pts) For each of the following situations, draw the three principle rays and find the image. Measure, f.p. q. h and h and label them below (1 "large box" 1.0 cm). Indicate whether the image is: - real or virtual upright or inverted - enlarged or reduced - in front or behind the mirrorlens No pens allowed. Draw this in...
A convex mirror has a focal length of 70 cm. An object is placed 40 cm from the mirror. 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.
Part A: A diverging lens has of focal length of 15.0 cm. An object is placed 21 cm to the left of the lens. a) draw a ray diagram showing the situation. b) find the location of the image produced by the lens (mind the signs). Part B: A converging lens is located 30 cm to the right of the previously mentioned diverging lens (part A). As a result, the image you found in part (a) is now instead located...
An object is 16 cm in front of a convex mirror. The mirror creates an image that is 55 % as tall as the object. Use ray tracing to find the distance of the focal point from the mirror. Express your answer to two significant figures and include the appropriate units. f =
draw a ray diagram for this A concave mirror with a focal length of 10.0 cm creates a real image 30.0 cm away on its principal axis; the corresponding object is located how far from the mirror? Use the mirror equation: 1/di + 1/do = 1/f where di = +30 cm and f = +10 cm. Substitute and solve for do. 1/do + 1/(30 cm) = 1/(10 cm) 1/do = 1/(10 cm) - 1/(30 cm) = 2/(30 cm) do =...
A speherical mirror has a focal length of -20cm. Find the location and describe the image for an object with a distance of 30 cm, suppose the object begins to slide toward the mirror at velocity V=5m/s. Where is the image located? How fast does the image of the object moves? Draw ray diagram. (please draw ray diagram)