Section_23_Special_W..
... 23. WAVES IN A UNIFORM MEDIUM: SPECIAL CASES We consider the special case of an infinite, uniform medium with B0 B0 êz and J 0 0 . In that case we can expand an arbitrary displacement in plane wave solutions as ...
... 23. WAVES IN A UNIFORM MEDIUM: SPECIAL CASES We consider the special case of an infinite, uniform medium with B0 B0 êz and J 0 0 . In that case we can expand an arbitrary displacement in plane wave solutions as ...
Part5-Electromagneti..
... Pirate and Ninja Bunnies from “Bunny” (http://www.frozenreality.co.uk/comic/bunny/) ...
... Pirate and Ninja Bunnies from “Bunny” (http://www.frozenreality.co.uk/comic/bunny/) ...
optics - einstein classes
... If a person of height h wants to see his full image in a plane mirror, the minimum height of the mirror should be h/2, whatever be the distance of the person from the mirror. The mirror should be placed such that its upper edge is midway between the head and the eye of the person and the lower edge ...
... If a person of height h wants to see his full image in a plane mirror, the minimum height of the mirror should be h/2, whatever be the distance of the person from the mirror. The mirror should be placed such that its upper edge is midway between the head and the eye of the person and the lower edge ...
Ch 33 Electromagnetic Waves I
... The current i(t) in the antenna associated with this movement of q also varies sinusoidally, in magnitude and direction, at angular frequency ω. The antenna has the effect of an electric dipole whose electric dipole moment p(t)=q0dcosωt along the antenna. Because p(t) varies in magnitude and direct ...
... The current i(t) in the antenna associated with this movement of q also varies sinusoidally, in magnitude and direction, at angular frequency ω. The antenna has the effect of an electric dipole whose electric dipole moment p(t)=q0dcosωt along the antenna. Because p(t) varies in magnitude and direct ...
Phase distortions in sum- and difference
... nonzero intensity, its input phase cannot be adjusted to make its output phase intensity independent if Dk fi 0. Clearly, when Dk fi 0, the intensity independence of the output phase of one wave is satisfied only in the special circumstance that the wave starts with zero intensity. It is also necess ...
... nonzero intensity, its input phase cannot be adjusted to make its output phase intensity independent if Dk fi 0. Clearly, when Dk fi 0, the intensity independence of the output phase of one wave is satisfied only in the special circumstance that the wave starts with zero intensity. It is also necess ...
on one possibility of making a medium transparent by
... form. The result is particularly simple in the case of strict resonance, ...
... form. The result is particularly simple in the case of strict resonance, ...
Electromagnetic Waves
... (green) and drops off quickly away from that wavelength ! Other wavelengths of electromagnetic waves are invisible ! However, we can still detect the electromagnetic waves ! For example, we can feel electromagnetic waves in the infrared (wavelengths just longer than visible up to around 0.1 mm) as ...
... (green) and drops off quickly away from that wavelength ! Other wavelengths of electromagnetic waves are invisible ! However, we can still detect the electromagnetic waves ! For example, we can feel electromagnetic waves in the infrared (wavelengths just longer than visible up to around 0.1 mm) as ...
Quanta and Waves - Calderglen High School
... ability to calculate probabilities but not make specific, definite, predictions. Quantum mechanics has enjoyed unprecedented practical success. Theoretical calculations agree with experimental observations to very high precision. Quantum mechanics also reminds us that there is discreteness in nature ...
... ability to calculate probabilities but not make specific, definite, predictions. Quantum mechanics has enjoyed unprecedented practical success. Theoretical calculations agree with experimental observations to very high precision. Quantum mechanics also reminds us that there is discreteness in nature ...
Historical burdens on physics 96 Permeability
... Also in this case B is independent of μr. Now, which of these two approximations correspond to the situation that we meet at school? Suppose we have a ring magnet of a total length of 50 cm, that would result if constructed from typical school material. Further suppose that we provide the magnet wit ...
... Also in this case B is independent of μr. Now, which of these two approximations correspond to the situation that we meet at school? Suppose we have a ring magnet of a total length of 50 cm, that would result if constructed from typical school material. Further suppose that we provide the magnet wit ...
Real-Time Multicolor DNA Detection with Chemoresponsive
... itself or of the grating. For example, chloroform can be readout preferentially by ca. 3500-fold relative to methanol when these are taken up by a nonchemically selective grating composed of a mildly vapochromic charge-transfer salt.9 Implied by the preferential readout is a very substantial amplifi ...
... itself or of the grating. For example, chloroform can be readout preferentially by ca. 3500-fold relative to methanol when these are taken up by a nonchemically selective grating composed of a mildly vapochromic charge-transfer salt.9 Implied by the preferential readout is a very substantial amplifi ...
spatial filtering
... the different beams of light striking a particular point on the screen should all be coming from the same spot on the subject image. It is important to place the screen in the right place so that this will happen. Oddly enough, in this lab, you can get a very focusedlooking image even when equation ...
... the different beams of light striking a particular point on the screen should all be coming from the same spot on the subject image. It is important to place the screen in the right place so that this will happen. Oddly enough, in this lab, you can get a very focusedlooking image even when equation ...
Blank Jeopardy - prettygoodphysics
... (A) Its speed in a vacuum is 3 x 10^8 m/s. (B) It has a charge equal and opposite to that of an alpha particle. (C) It is more penetrating than a gamma ray of the same energy. (D) It has a mass of about 1,840 times that of a proton. (E) It can exhibit wave properties. ...
... (A) Its speed in a vacuum is 3 x 10^8 m/s. (B) It has a charge equal and opposite to that of an alpha particle. (C) It is more penetrating than a gamma ray of the same energy. (D) It has a mass of about 1,840 times that of a proton. (E) It can exhibit wave properties. ...
تکلیف سری اول درس آنتن1 موعد تحویل : 3/12/84
... ? Find the maximum directivity using the given approximations and compare it with its exact value! Another approximation has been published by Tai and Pereira in 1976: ...
... ? Find the maximum directivity using the given approximations and compare it with its exact value! Another approximation has been published by Tai and Pereira in 1976: ...
Extension worksheet – Topic 6
... that is larger by 1600 nm. Then the radius of each spiral (circle) is part of an arithmetic series with first term zero and common difference 1600 nm. From mathematics, rn r1 (n 1)d . The nth circle has radius 6 cm and so the number n of spirals is found from 6 10 2 (n 1) 1600 10 9 ...
... that is larger by 1600 nm. Then the radius of each spiral (circle) is part of an arithmetic series with first term zero and common difference 1600 nm. From mathematics, rn r1 (n 1)d . The nth circle has radius 6 cm and so the number n of spirals is found from 6 10 2 (n 1) 1600 10 9 ...
Diffraction
Diffraction refers to various phenomena which occur when a wave encounters an obstacle or a slit. In classical physics, the diffraction phenomenon is described as the interference of waves according to the Huygens–Fresnel principle. These characteristic behaviors are exhibited when a wave encounters an obstacle or a slit that is comparable in size to its wavelength. Similar effects occur when a light wave travels through a medium with a varying refractive index, or when a sound wave travels through a medium with varying acoustic impedance. Diffraction occurs with all waves, including sound waves, water waves, and electromagnetic waves such as visible light, X-rays and radio waves.Since physical objects have wave-like properties (at the atomic level), diffraction also occurs with matter and can be studied according to the principles of quantum mechanics. Italian scientist Francesco Maria Grimaldi coined the word ""diffraction"" and was the first to record accurate observations of the phenomenon in 1660.While diffraction occurs whenever propagating waves encounter such changes, its effects are generally most pronounced for waves whose wavelength is roughly comparable to the dimensions of the diffracting object or slit. If the obstructing object provides multiple, closely spaced openings, a complex pattern of varying intensity can result. This is due to the addition, or interference, of different parts of a wave that travels to the observer by different paths, where different path lengths result in different phases (see diffraction grating and wave superposition). The formalism of diffraction can also describe the way in which waves of finite extent propagate in free space. For example, the expanding profile of a laser beam, the beam shape of a radar antenna and the field of view of an ultrasonic transducer can all be analyzed using diffraction equations.