2. The refraction of light between air and glass is the basis of the corrective lenses. The surface of the glass can be curved more or less to bring rays of light into focus at any distance from the lens. So, a lens can be thought of as a piece of a glass sphere with a certain radius as shown in figure 1 below. The bigger the radius, the less curved the lens is. In figure 2, I've zoomed in on the lens. I've drawn two parallel light rays entering the lens from the upper and lower half. If the incident angle of the light rays is 5°, at what distance from the back side of the lens will the light rays come into focus (answering in millimeters will likely be most convenient). Remember that refraction will occur when the light passes from the air to the glass, then again when it passes from the glass to the air. The indices of refraction of air and glass are 1 and 1.52, respectively. Lens R Figure 1 Oi x=4mm h = 2mm Figure 2 d=?

2. The refraction of light between air and glass is the basis of the corrective lenses. The surface of the glass can be curved more or less to bring rays of light into focus at any distance from the lens. So, a lens can be thought of as a piece of a glass sphere with a certain radius as shown in figure 1 below. The bigger the radius, the less curved the lens is. In figure 2, I've zoomed in on the lens. I've drawn two parallel light rays entering the lens from the upper and lower half. If the incident angle of the light rays is 5°, at what distance from the back side of the lens will the light rays come into focus (answering in millimeters will likely be most convenient). Remember that refraction will occur when the light passes from the air to the glass, then again when it passes from the glass to the air. The indices of refraction of air and glass are 1 and 1.52, respectively. Lens R Figure 1 Oi x=4mm h = 2mm Figure 2 d=?

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

A magnifying glass makes objects look bigger. Describe how a magnifying glass works. Where is the object? Where is the image? Is the image upright or inverted? Real or virtual? Briefly explain your answers in terms of what you know about lenses and ray tracing.
Fast.
1. Assume that a camera has a bi-convex lens. Should you move the lens toward or away from the sensor in order to zoom in (magnify)? 2. A camera has a bi-convex lens whose focal length is 50mm. The lens’s range of motion is 5.56mm starting from 50mm from the sensor and moving away. What are the minimum and maximum possible object positions for which the image is in focus? 3. For the camera in the previous question, when a 300mm tall object is at the minimum distance, will it fit on a Canon APS-C sensor? Hint: Look up the size of this camera sensor. 4. See Figure 10.7! A circular piece of glass (n=1.5) has been cut in half as shown and is being used as a lens for a set of five parallel rays. The angles at which the rays are incident on the circular side of the lens are shown, and the image is drawn to scale. First, calculate the 5 angles of refraction for each of the 5 angles of incidence, respectively. Second, use a protractor to draw the refracted rays such that they intersect the…
The NTT telescope has a 3.58 m primary mirror and a focal ratio of f/2.2. a. Calculate the focal length of the primary mirror of the NTT telescope. b. What is the value of the plate scale of the NTT? c. Bootes is a double star system whose components are separated by 2.9". Calculate the linear separation of the images on the primary mirror focal pane of the NTT.
Hello, I need help with questions #6 and #7. Thank you!
You have a source light that is 0.5 cm in size. You use a convex lens with a focal length of 4 cm for collimation. What focal length would you need to focus the source light onto a detector with a sensing area in 1 mm size? Answer in mm with the nearest whole number. The question continues from the above. What is the distance between the source and the adjacent lens in the system described above? Answer in mm. i got -8 for the first one but i got it wrong
c.) real or virtual d.) inverted or noninverted e.) same or opposite
9
1. The diagram below shows two light rays emanating from the top of the object and incident towards the mirror. Describe how the reflected rays for these light rays can be drawn without actually using a protractor and the law of reflection.
Q: You hold up a piece of paper by a lens and see the image of a candle projected on the paper. Is this image real or virtual? Q: Will the projected image show the candle right-side-up or upside-down? Q: You look through a concave (diverging) lens at a candle. Will the image you see be smaller or larger in size than the actual candle?