Tutorials in Introductory Physics
1st Edition
ISBN: 9780130970695
Author: Peter S. Shaffer, Lillian C. McDermott
Publisher: Addison Wesley
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Chapter 10.5, Problem 2fT
To determine
To Draw: Continuation of the ray and describe the path of the ray.
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Chapter 10 Solutions
Tutorials in Introductory Physics
Ch. 10.1 - Prob. 1aTCh. 10.1 - Predict how each of the following changes would...Ch. 10.1 - A mask with a circular hole is placed between a...Ch. 10.1 - What do your observations suggest about the path...Ch. 10.1 - Imagine that you held a string of closely spaced...Ch. 10.1 - The mask used in parts C-E is replaced by one that...Ch. 10.1 - Prob. 1gTCh. 10.1 - Predict what you would see on the screen when an...Ch. 10.1 - Predict the size of the lit region on the screen...Ch. 10.1 - Suppose that the bulb were replaced by a long...
Ch. 10.1 - Prob. 2cTCh. 10.1 - Predict what you would see on the screen at the...Ch. 10.1 - Suppose that the light from the top bulb in the...Ch. 10.1 - Predict what you would see on the screen in the...Ch. 10.2 - Close one eye and lean down so that your open eye...Ch. 10.2 - Suppose that you placed your finger behind the...Ch. 10.2 - Prob. 1cTCh. 10.2 - Prob. 1dTCh. 10.2 - Place your head so that you can see the image of...Ch. 10.2 - Move the nail off w the right side of the mirror...Ch. 10.2 - Prob. 3aTCh. 10.2 - Turn the large sheet of paper over (or obtain a...Ch. 10.2 - Remove the mirror and the object nail. For each...Ch. 10.2 - On the diagram at right, draw one ray from the pin...Ch. 10.2 - Prob. 4bTCh. 10.2 - Determine the image location using the method of...Ch. 10.3 - A pin is placed In front of a cylindrical mirror...Ch. 10.3 - Could you use any two rays (even those that do not...Ch. 10.3 - Observers at M and N arc looking at an image of...Ch. 10.3 - Stick a pin into a piece of cardboard and place...Ch. 10.3 - Gradually decrease the angle between the mirrors...Ch. 10.4 - Prob. 1bTCh. 10.4 - Three students are discussing their results from...Ch. 10.4 - For each case shown below, determine and label the...Ch. 10.4 - In each of the previous cases, predict what would...Ch. 10.4 - Prob. 2cTCh. 10.4 - Explain how you can use a screen to determine the...Ch. 10.5 - Look at very distant object through a convex lens....Ch. 10.5 - Consider a point on the distant object that is...Ch. 10.5 - Suppose that you placed a very small bulb at the...Ch. 10.5 - Consider the ray chai is parallel to the principal...Ch. 10.5 - Consider the ray that goes through the focal point...Ch. 10.5 - How can you use these two rays to determine the...Ch. 10.5 - Consider the ray from the easer that strikes the...Ch. 10.5 - Draw the continuation of the two remaining rays...Ch. 10.5 - Prob. 2fTCh. 10.5 - The diagram below shows a small object placed near...Ch. 10.5 - A lens, a bulb, and a screen are arranged as shown...Ch. 10.5 - Obtain the necessary equipment and check your...Ch. 10.5 - Prob. 3cTCh. 10.6 - The diagram at right illustrates what an observer...Ch. 10.6 - Obtain two soda cans and a cardboard tube that has...Ch. 10.6 - Could an observer at each of the labeled points...Ch. 10.6 - Use the above diagram to answer the following...Ch. 10.6 - Obtain convex lens. Use the lens as a magnifying...Ch. 10.6 - Draw a ray diagram that shows how to determine the...Ch. 10.6 - The lateral magnification, m1 , is defined as...Ch. 10.6 - The angular magnification, m , is defined as m= ,...
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Similar questions
- You are imaging a pencil through a thin, converging lens as shown in the image below. If p (the distance from the object to the center of the thin lens) is 6.86m and the focal length of the thin lens is 1.4m, how far away (in meters) from the center of the thin lens is the real image located (the real image will be on the right-side of the lens in this particular example illustrated below)? Ray 1 Page Object focal point Converging lens Ray 2 Secondary Ray 3 Ray 1 Ray 3 Principal focal point Real imagearrow_forwardYou are imaging a pencil through a thin, converging lens as shown in the image below. If p (the distance from the object to the center of the thin lens) is 8.15m and the focal length of the thin lens is 0.42m, how far away (in meters) from the center of the thin lens is the real image located (the real image will be on the right-side of the lens in this particular example illustrated below)? Ray 1 Ray 1 focal point Ray 2 Sis Secondary Ray 3 Ray 3 Object Converging lens focal point Principal Real image Note: Do not explicitly include units in your answer (it is understood the unit is meter). Enter only a number. If you do enter a unit, your answer will be counted wrong.arrow_forwardUsing a ruler or any straight edge and a scale of your choice and applying the steps in ray diagramming, complete the ray diagramming for Cases 2 to 5 in order to prove the correctness of the image characteristics of the objects in the specified positions as indicated in Table 1.arrow_forward
- Construct ray diagrams to determine the location, orientation, size, and type of images formed by a curved mirror. Using the protractor and the ruler, copy each of the diagrams (A – F) below on a separate sheet of paper. As much as possible, use the four principal rays to locate the image formed in a curved mirror.arrow_forwardThe diagram below shows the situation described in the problem. The focal length of the lens is labeled f; the scale on the optical axis is in centimeters. Draw the three special rays, Ray1, Ray2, and Ray3 as described in the Tactics Box above, and label each ray accordingly. Draw the rays from the tip of the object to the center vertical axis of the lens. Do not draw the refracted rays. Draw the vectors for the incident rays starting at the tip of the object to the center vertical axis of the lens. The location and orientation of the vectors will be graded. Vectors: Ray3 Ray though center of lens Ray2 Ray through near focal point Rayl Ray parallel to axis Unlabeled vector Objectarrow_forwardIn the figure below (not to scale), the focal lengths of the thin converging lenses, L1 and L2, are 20.0 cm and 10.0 cm, respectively. L1 L2 When object O is placed 30.0 cm to the left of L1, its image forms 7.0 cm to the right of L2. What is the distance between the two lenses? Express your answer to the nearest cm.arrow_forward
- An image seen through a convex mirror cut from a sphere of radius 20cm is exactly half size of the object. Where must the object and image be located? Support your work with a ray diagram. Hint: Remember that virtual distances are negative when using the mirror equation. Follow grading rubric. Explain answer.arrow_forwardPlease show formula and units The light beam in the figure below strikes surface 2 at the critical angle. The medium outside the prism is air n1=1. a) The index of refraction n2 inside the prism. b) The angle of incidence θ1 for surface 1.arrow_forwardDetermine the image distance d, for an object d. = 6.100 cm from a diverging lens with radius of curvature R = 4,880 cm and index of refraction 1.650. Express your answer as a positive quantity. object %3D cm = I'pl What is the magnification m of the object? Be sure to insert the proper sign if needed. m = What is the nature of the image? inverted and smaller upright and smaller inverted and larger upright and largerarrow_forward
- You hold a spherical salad bowl 50 cm in front of your face with the bottom of the bowl facing you. The salad bowl is made of polished metal with a 48 cm radius of curvature. Part A Where is the image of your 5.0-cm-tall nose located? Follow the sign rules. Enter the magnitude of the distance from the salad bowl. Express your answer with the appropriate units. s' Submit Part B Value y' = Request Answer What is the image's size? Express your answer with the appropriate units. μА Units Value Units ? ?arrow_forwardAn object, pointing upwards, is placed outside the focal point F2 of a thin diverging lens. A student is using the diagram shown above and the graphical method to predict the image of the arrow. To draw a principal ray, which direction should the student follow? O Draw a ray from point Q through F, to the lens, then bend it so it is horizontal. O Draw a horizontal ray from point Q to the lens, then bend it so it appears to diverge from F2. O Draw a ray from point P to any position on the lens, then bend it so it is horizontal. Draw a ray from point Q to the center of the lens, then bend it so it is horizontal.arrow_forwardThe Block shown is 40cm thick. (d) The block is shown below. A 25° line is displayed by a diagonal dashed line. The incident light is directed at the block along the 25° line. The light enters the front surface and exits the second side back into air some time later. i. Print or redraw the diagram below, sketch the light path as the ray enters and passes through to the air on the backside of the block. Please use a ruler or make relatively straight lines. ii. When the light exits the block back into the air, will the ray travel parallel to the 25° line or at an angle to it? Determine the angle between the exiting ray and the 25° line or the distance between the two lines if they are parallel. iii.arrow_forward
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