Midway High School Science TAKS Review
Midway High School Science TAKS Review

... Actually, it is. This is an example of resonance – two objects vibrating at the same natural frequency. Almost all objects have a natural frequency at which they vibrate (glasses, loose wheels on grocery carts, stadium ...
D - Purdue Physics
D - Purdue Physics

... Catadioptric systems: Aplanatic reflectors: Both primary and secondary mirrors are hyperbolic Example: Hubble telescope ...
Get PDF - OSA Publishing
Get PDF - OSA Publishing

... wave vector ki = k0 ẑ + ∇φ of the AiB and that corresponding to the reference plane wave, kPW = k0 ẑ + ∇ψ . Note that kPW approaches k0 ẑ + (k/w0 ) x̂ to order k, and that kPW dr over the contour C. This is of relevance since many physical processes, like the generation of curved plasma ch ...
fourier optics - The Institute of Optics
fourier optics - The Institute of Optics

... ∇ × ∇ × E(r; ν) − ω 2 µεE(r; ν) = −iω µJ(r; ν) (∇2 + k2 )E(x, y, z) = 0 ...
Optics Observations
Optics Observations

Waves and Radiation
Waves and Radiation

... Longitudinal waves are when the displacement is parallel to the direction of the wave… ...
Chapter 2 System Evaluation
Chapter 2 System Evaluation

... position incorrect (caused by coma, distortion) → dislocation of the image points → dislodged with respect to the ideal position Phase shift:  (spatial phase)  is a function of spatial frequency =f(R) Optical transfer function: ...
Physical Optics and Diffraction
Physical Optics and Diffraction

... comes from a distant wave source. Characterize aperture by a complex function , such that the wave just after passing through it On the aperture have ...
Fraunhofer Diffraction
Fraunhofer Diffraction

Convolution in Imaging and the Optical Transfer Function Process
Convolution in Imaging and the Optical Transfer Function Process

... image. It is the corresponding irradiance distribution in the image plane. If the optical system is perfect, then the image plane function for single point (delta point object) would also be a delta function (make sense? A single point is a spike – the irradiance is a spike). Cartesian surfaces only ...
Second Year Problem sheet 3 +answers
Second Year Problem sheet 3 +answers

Introduction to Optics Frank L. Pedrotti Leno M. Pedrotti Leno S
Introduction to Optics Frank L. Pedrotti Leno M. Pedrotti Leno S

04-Waves shorter
04-Waves shorter

Class07
Class07

The Physics 431 Final Exam Ÿ W DECEMBER 16 2009
The Physics 431 Final Exam Ÿ W DECEMBER 16 2009

INTRODUCTION
INTRODUCTION

... The optical transmission medium is the best in a sense that it has ultra wide bandwidth and very low attenuation. The attenuation history is given in the following Figure. Initially in early 1970s due to technology limitation, the optical fiber had a low loss window around 800nm. Also the semiconduc ...
00 Fourier optics – 4f Arrangement – Filtering and reconstruction
00 Fourier optics – 4f Arrangement – Filtering and reconstruction

... upwards) as the first diffracting structure in plate holder P1 [2,1] in the object plane and shifted laterally in such a manner that the light from the mirror M2 strikes the arrow head. An arrow also appears on the observation screen (compare with theory!). The arrow is now turned 90 ° so that it po ...
Microsoft Word Format - McMaster University > ECE
Microsoft Word Format - McMaster University > ECE

... homogenous) is a plane traveling wave having its wave vector with the value of    ( / c)n  (2 /  )n and with its direction pointing right at the direction of wave propagation, having the electric and magnetic field both polarized in a plane perpendicular to the wave propagation direction, ha ...
Optical Scientist - Corning
Optical Scientist - Corning

TRIPURA UNIVERSITY Physics SYLLABUS OF
TRIPURA UNIVERSITY Physics SYLLABUS OF

... applications to simple problems. Orthogonal curvilinear coordinate systems, unit vectors in such systems, gradient, divergence, curl and Laplacian in orthogonal curvilinear coordinates, illustration by spherical polar and cylindrical polar coordinate systems as special case. Matrices: Hermitian matr ...
Chapter 9. Computer vision
Chapter 9. Computer vision

... There are several points to be taken into account that are important. The linearity of the response in the case of coherent illumination corresponds to the electrical field expressed in V/m. In the case of incoherent illumination the linearity applies to the irradiance expressed in W/m 2. This is an ...
Engineering Optics and Optical Techniques
Engineering Optics and Optical Techniques

... LN#1. Electromagnetic Basics and Maxwell’s Equations (Sections 3-1, 3-2, Appendix 1) Propagation of Waves (Chapter 2, Sections 3-3, 3-4) ...
Interference
Interference

... Wave Superposition and Interference • What happens when waves meet? • Path Difference - Phase Difference: illustrate this with the following applet ...
Chapter 33. Electromagnetic Waves
Chapter 33. Electromagnetic Waves

Acknowledgments
Acknowledgments

Fourier optics

Fourier optics is the study of classical optics using Fourier transforms, in which the wave is regarded as a superposition of plane waves that are not related to any identifiable sources; instead they are the natural modes of the propagation medium itself. Fourier optics can be seen as the dual of the Huygens–Fresnel principle, in which the wave is regarded as a superposition of expanding spherical waves which radiate outward from actual (physically identifiable) current sources via a Green's function relationship (see Double-slit experiment)A curved phasefront may be synthesized from an infinite number of these ""natural modes"" i.e., from plane wave phasefronts oriented in different directions in space. Far from its sources, an expanding spherical wave is locally tangent to a planar phase front (a single plane wave out of the infinite spectrum), which is transverse to the radial direction of propagation. In this case, a Fraunhofer diffraction pattern is created, which emanates from a single spherical wave phase center. In the near field, no single well-defined spherical wave phase center exists, so the wavefront isn't locally tangent to a spherical ball. In this case, a Fresnel diffraction pattern would be created, which emanates from an extended source, consisting of a distribution of (physically identifiable) spherical wave sources in space. In the near field, a full spectrum of plane waves is necessary to represent the Fresnel near-field wave, even locally. A ""wide"" wave moving forward (like an expanding ocean wave coming toward the shore) can be regarded as an infinite number of ""plane wave modes"", all of which could (when they collide with something in the way) scatter independently of one other. These mathematical simplifications and calculations are the realm of Fourier analysis and synthesis – together, they can describe what happens when light passes through various slits, lenses or mirrors curved one way or the other, or is fully or partially reflected. Fourier optics forms much of the theory behind image processing techniques, as well as finding applications where information needs to be extracted from optical sources such as in quantum optics. To put it in a slightly more complex way, similar to the concept of frequency and time used in traditional Fourier transform theory, Fourier optics makes use of the spatial frequency domain (kx, ky) as the conjugate of the spatial (x,y) domain. Terms and concepts such as transform theory, spectrum, bandwidth, window functions and sampling from one-dimensional signal processing are commonly used.