124-07_Reflection_and_Refraction
... for at least two different angles θinc. There is a picture below of what you should draw in your lab book. The yellow line is the light beam and the black line is perpendicular to the side of the prism. ...
... for at least two different angles θinc. There is a picture below of what you should draw in your lab book. The yellow line is the light beam and the black line is perpendicular to the side of the prism. ...
Introduction to Optical Engineering and Design ENSC 376
... optics, and less on the physics behind the behaviour. It starts with a basic explanation of the concepts of light, as electromagnetic radiation. Then it looks how light is generated, at both the atomic and black body level. Next optical interaction with materials is discussed beginning with reflecti ...
... optics, and less on the physics behind the behaviour. It starts with a basic explanation of the concepts of light, as electromagnetic radiation. Then it looks how light is generated, at both the atomic and black body level. Next optical interaction with materials is discussed beginning with reflecti ...
![Scalar Diffraction Theory and Basic Fourier Optics [Hecht 10.2.410.2.6, 10.2.8, 11.211.3 or Fowles Ch. 5]](http://s1.studyres.com/store/data/008906603_1-55857b6efe7c28604e1ff5a68faa71b2-300x300.png)
Optics Review
... be 3 cm tall? How tall is the object? (tough question!) 14. A 19-cm tall object is placed 21 cm from a converging lens that has a focal length of 14 cm. How far from the lens will the image be formed? How tall is the image? Describe the characteristics of the image. (tough question!) 15. Determine t ...
... be 3 cm tall? How tall is the object? (tough question!) 14. A 19-cm tall object is placed 21 cm from a converging lens that has a focal length of 14 cm. How far from the lens will the image be formed? How tall is the image? Describe the characteristics of the image. (tough question!) 15. Determine t ...
Inleiding Optica 2010
... Starting from object point P: (1) parallel—focal point (2) focal point—parallel (3) center of curavature—same Image at point of intersection P′ Concave: real (for objects outside focal point) Convex: virtual ...
... Starting from object point P: (1) parallel—focal point (2) focal point—parallel (3) center of curavature—same Image at point of intersection P′ Concave: real (for objects outside focal point) Convex: virtual ...
Generalizations of the Brachistochrone Problem
... Advisor, Dr. Nolan Consider a frictionless surface in a gravitational field that need not be uniform. Given two points A and B on the surface, what curve is traced out by a particle that starts at A and reaches B in the shortest time? This paper discusses studies this problem for simple surfaces suc ...
... Advisor, Dr. Nolan Consider a frictionless surface in a gravitational field that need not be uniform. Given two points A and B on the surface, what curve is traced out by a particle that starts at A and reaches B in the shortest time? This paper discusses studies this problem for simple surfaces suc ...
The Very Basics of Geometric Optics 5.1.2 Basic Geometric Optics
... The NA for a single lens is roughly the quotient of (possibly aperture defined) diameter / focal length; i.e. a crude measure of the size of the lens; see the picture below. Of course, lenses with small NA will not suffer much from spherical aberration but will also not transmit much light and thus ...
... The NA for a single lens is roughly the quotient of (possibly aperture defined) diameter / focal length; i.e. a crude measure of the size of the lens; see the picture below. Of course, lenses with small NA will not suffer much from spherical aberration but will also not transmit much light and thus ...
Lecture 16 - Purdue Physics
... Reflection of Light • When viewed from above, light from a laser pointer reflects off a vertical mirror: ...
... Reflection of Light • When viewed from above, light from a laser pointer reflects off a vertical mirror: ...
Image formation with broad bundles of rays
... The change in phase along different rays between points of intersection with two given wave surfaces is the same. The total change in phase between the points O and O’ is the same for the different rays. The optical path length y is the same for all these rays. ...
... The change in phase along different rays between points of intersection with two given wave surfaces is the same. The total change in phase between the points O and O’ is the same for the different rays. The optical path length y is the same for all these rays. ...
Physics 263 Experiment 6 Geometric Optics 1 Refraction
... In this laboratory, we will perform several experiments on “geometric” optics. A pictorial diagram of the various components to be used is shown in Figure 5. ...
... In this laboratory, we will perform several experiments on “geometric” optics. A pictorial diagram of the various components to be used is shown in Figure 5. ...
RAY OPTICS notes
... The image is real if the rays actually converge to the point; it is virtual if the rays do not actually meet but appear to diverge from the point when produced backwards. ...
... The image is real if the rays actually converge to the point; it is virtual if the rays do not actually meet but appear to diverge from the point when produced backwards. ...
PHYS 1111 Mechanics, Waves, & Thermodynamics
... close enough together that we can neglect the distance between the surfaces (i.e., thin) Consider two spherical surfaces (with radii of curvature R1 and R2), separating three materials of index of refraction n1, n2, and n3 For the first surface, we can use the refracting surface equation to relate t ...
... close enough together that we can neglect the distance between the surfaces (i.e., thin) Consider two spherical surfaces (with radii of curvature R1 and R2), separating three materials of index of refraction n1, n2, and n3 For the first surface, we can use the refracting surface equation to relate t ...
ECE 4362: Modern Optics for Engineers Credit / Contact hours: Course coordinator:
... Course coordinator: Ayrton Bernussi Textbook(s) and/or other required material: Introduction to Optics, Frank L. Pedrotti, S.J., Leno S. Pedrotti, and Leno M. Pedrotti, Pearson-Prentice Hall, 3rd Ed., 2007, ISBN: 0-13149933-5 Catalog description: Modern concepts in optics related to engineering appl ...
... Course coordinator: Ayrton Bernussi Textbook(s) and/or other required material: Introduction to Optics, Frank L. Pedrotti, S.J., Leno S. Pedrotti, and Leno M. Pedrotti, Pearson-Prentice Hall, 3rd Ed., 2007, ISBN: 0-13149933-5 Catalog description: Modern concepts in optics related to engineering appl ...
Science Olympiad 2011 Practice Optics C
... to highest frequency. Label which end of the spectrum has the highest energy, and which has the longest wavelength. 20. What are the two types of photoreceptor cells in the human eye? What is the specific function of each? 21. Explain why a screen, like a TV or a computer monitor, is able to trick t ...
... to highest frequency. Label which end of the spectrum has the highest energy, and which has the longest wavelength. 20. What are the two types of photoreceptor cells in the human eye? What is the specific function of each? 21. Explain why a screen, like a TV or a computer monitor, is able to trick t ...
LENSES and MIRRORS
... parallel to the optical axis pass through a convex lens, they are bent toward the center of the lens. Examples: Magnifying glass and corrective lenses for farsightedness. A concave lens is thinner in the center than on its edges. When light rays traveling parallel to the optical axis pass through a ...
... parallel to the optical axis pass through a convex lens, they are bent toward the center of the lens. Examples: Magnifying glass and corrective lenses for farsightedness. A concave lens is thinner in the center than on its edges. When light rays traveling parallel to the optical axis pass through a ...