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| ng amenities: a full range stove and oven, a | microwave, a dishwasher, a garbage disposal, a refrige |
| tion's demise, but later acquired by Eastern | Microwave, a cable-TV distribution service known today |
| ually extends through a small wood with a BT | microwave aerial prominent. |
| on in 1940 and began work on their magnetron | microwave amplifier products. |
| The development of solid-state | microwave amplifiers, JFETs and MESFETs, allowed the s |
| The top of it is covered with many | microwave and telecommunication antennas. |
| s day and is festooned with a large array of | microwave and radio antennas. |
| and processing technology with re‐engineered | microwave and antenna components that are able to fit |
| t even lower frequency, the wave is called a | microwave, and at still lower frequencies it is called |
| Background Explorer (COBE) and the Wilkinson | Microwave Anisotropy Probe (WMAP), which was named in |
| upon observations made by the NASA Wilkinson | Microwave Anisotropy Probe (WMAP), which has measured |
| spacetime has been measured by the Wilkinson | Microwave Anisotropy Probe (WMAP) to be nearly flat. |
| nd Explorer (COBE) in 1989 and the Wilkinson | Microwave Anisotropy Probe (WMAP) in 2001, which have |
| re more fully characterized by the Wilkinson | Microwave Anisotropy Probe. |
| "Three-Year Wilkinson | Microwave Anisotropy Probe (WMAP1) Observations: Tempe |
| fall Measuring Mission (TRMM), the Wilkinson | Microwave Anisotropy Probe (WMAP) and the Earth Observ |
| ll in place are used as radio transmission & | microwave antenna stations. |
| w to 416 feet (127 m) with the addition of a | microwave antenna "crown" in 1958. |
| Observatory and its forest of radio, TV, and | microwave antennas being blocked by trees. |
| orld War II he researched VHF, UHF radar and | microwave antennas for military purposes at the Nation |
| ntributions to the theory and application of | microwave antennas. |
| pansion into large projects, rolling out the | microwave backbone of MTN, one of South Africa's first |
| would observe 80% of the sky for the Cosmic | microwave background radiation in the frequency range |
| easurements of the Temperature of the Cosmic | Microwave Background Radiation", Lawrence Berkeley Nat |
| th Igor Novikov on the recognition of Cosmic | microwave background radiation as a detectable phenome |
| f galaxy clusters with respect to the cosmic | microwave background should be randomly distributed in |
| n the mid-1960s with the discovery of cosmic | microwave background (CMB) by Bell Labs. |
| rt the discovery of anisotropy in the cosmic | microwave background at the Moscow astrophysical semin |
| arted operations in 1999 to study the cosmic | microwave background radiation until 2008. |
| The cosmic | microwave background was predicted in 1948 by George G |
| known especially for his work on the cosmic | microwave background (CMB). |
| iscovered the blackbody nature of the cosmic | microwave background radiation.) |
| oot (discovered the anisotropy of the cosmic | microwave background radiation), |
| Laboratory in the US explain how the Cosmic | Microwave Background (CMB) radiation spectrum - an all |
| ergy cosmic rays interacting with the Cosmic | Microwave Background and the universe becoming opaque |
| gas in galaxy clusters scattering the cosmic | microwave background radiation. |
| ions on the reduction of magnitude of cosmic | microwave background radiation in the direction of clu |
| arning about astrophysics in general and the | microwave background radiation in particular. |
| enzias and Robert Wilson discover the cosmic | microwave background radiation, |
| ly universe by measuring polarization in the | microwave background radiation. |
| d for computing the anisotropy of the cosmic | microwave background radiation for an arbitrary set of |
| articularly known for his research on cosmic | microwave background radiation, galaxy clustering and |
| er, and, when compared with the results from | microwave background anisotropy missions, will test th |
| BICEP2 is a cosmic | microwave background polarization experiment located a |
| cept for the so-called B-modes of the cosmic | microwave background polarization. |
| as a three-element interferometer for cosmic | microwave background radiation (CMB/R) observations at |
| cale clustering spectrum, account for cosmic | microwave background anisotropies on large and interme |
| The | microwave background radiation as measured by the COBE |
| point the photons in that compose the cosmic | microwave background radiation were last scattered, is |
| The light which constitutes the cosmic | microwave background comes from the surface of last sc |
| It was used to map the cosmic | microwave background radiation (CMBR). |
| -1 from Russian: РЕЛИКТ-1) - a Soviet cosmic | microwave background anisotropy experiment on board th |
| ogy, specializing in the study of the cosmic | microwave background radiation (CMB) left over from th |
| m observations of anisotropies in the cosmic | microwave background and from measurements of the dist |
| 1960s - Robert Dicke re-estimates a | microwave background radiation temperature of 40K |
| ation released is still observable as cosmic | microwave background radiation. |
| ect is notable in measurements of the cosmic | microwave background radiation, due to the motion of e |
| ith astronomical instrumentation, the Cosmic | Microwave Background and Star-formation in Galaxies. |
| be identified with that in which the Cosmic | microwave background radiation is globally isotropic. |
| Aside from Hubble's law, the cosmic | microwave background radiation is used as empirical ev |
| the cosmic | microwave background - although physically it is not a |
| strength of the present day residual cosmic | microwave background radiation (CMB) was made. |
| n of the opaque early Universe seen today as | microwave background radiation. |
| trillionth of a second (although the cosmic | microwave background radiation observed by WMAP origin |
| d by several independent sources: the cosmic | microwave background radiation and large scale structu |
| and polarization anisotropies in the Cosmic | Microwave Background at multipoles between 800 and 8,0 |
| of hydrogen and the formation of the cosmic | microwave background radiation. |
| ravitational blueshift contributes to cosmic | microwave background (CMB) anisotropy via the Sachs-Wo |
| tal cosmology, measuring polarization in the | microwave background radiation whose properties date b |
| act that, as measured from Earth, the cosmic | microwave background is indeed highly isotropic-the te |
| ry models include polarization of the cosmic | microwave background radiation and frequency distribut |
| blackbody form and anisotropy of the cosmic | microwave background radiation. |
| component) of the polarization of the cosmic | microwave background radiation. |
| rlocking scan of the skies to produce cosmic | microwave background (CMB) maps. |
| WMAP cosmic | microwave background map |
| y confirmed with the discovery of the cosmic | microwave background radiation, which has a measured t |
| Timeline of cosmic | microwave background astronomy |
| Arno Allan Penzias (discovered the cosmic | microwave background radiation), |
| Robert Woodrow Wilson (discovered the Cosmic | microwave background radiation), |
| and the well-resolved mapping of the cosmic | microwave background) have led to speculation that the |
| om specializes in measurements of the Cosmic | Microwave Background, and has led several experiments |
| d to the thermal perturbations of the Cosmic | Microwave Background. |
| ment to measure the anisotropy of the Cosmic | microwave background. |
| ict specific non-Gaussianities of the cosmic | microwave background. |
| ment to measure the anisotropy of the Cosmic | microwave background. |
| ty to measure the polarization of the Cosmic | microwave background. |
| measure small-scale structure in the cosmic | microwave background. |
| drogen atoms and interaction with the cosmic | microwave background. |
| n of polarization anisotropies in the Cosmic | Microwave Background. |
| leosynthesis, and observations of the cosmic | microwave background. |
| a manufacturer of point-to-multipoint packet | microwave backhaul solutions. |
| me the market leader for point-to-multipoint | microwave backhaul solutions. |
| for QUEST at DASI, is a ground based cosmic | microwave backrground (CMB) polarization experiment lo |
| his apple baking dishes, chicken cookers and | microwave bacon cookers. |
| n heats dust and re-emits radiation into the | microwave band, which may distort the cosmic microwave |
| arrow range of frequencies, generally in the | microwave band. |
| which dielectric lenses are used to focus a | microwave beam into and out of ae solid-state circuit |
| aper, Forward proposed pushing a sail with a | microwave beam. |
| ed, the power being transmitted to Earth via | microwave beams. |
| nal Frontier", "Helicopter Tealeaf", "Prince | Microwave Bollard", "Take Me To The Earth", "McManus O |
| bursts (158 d) above 30 keV, Hα flare data, | microwave bursts (152 d) for the period 1966-1983, but |
| RF | microwave CAE CAD is computer-aided design (CAD) using |
| However, in advanced | microwave cavity made out of silver-plated ceramic, th |
| resonator can take the form of a waveguide, | microwave cavity or YIG sphere. |
| The ODC use milimeteric | microwave cavity that include photonic crystal that pr |
| A small fraction of the signal in the | microwave cavity is coupled into a coaxial cable and t |
| Inside the magnet's bore is a tunable | microwave cavity . |
| ical lasers propel the atoms upward inside a | microwave chamber. |
| tions included equipment to down convert the | microwave channels for viewing on standard television |
| Microwave chemistry sensor or Surface acoustic wave (S | |
| RF and | microwave circuit design and simulation software for t |
| His work on | microwave circuits has been important for various adva |
| and applications, including antenna design, | microwave circuits, radio frequency, photonics, optics |
| ven by a continuous frequency clock, will as | microwave comb generators, having output frequency com |
| otton-under-Edge BT Tower formed part of the | microwave communication network. |
| with cloaking devices, and a short-range GPS | microwave communication system. |
| In | microwave communication, overshoot refers to reception |
| e.g. for medical diagnosis), and optical and | microwave communication. |
| 8, he served with the U.S. Army Reserve as a | microwave communications repairman. |
| Its main use is | microwave communications for the Deutsche Telekom also |
| ed for satellite communications, terrestrial | microwave communications and for radio astronomy studi |
| nsmission facilities for UHR radio services, | microwave communications, and omnidirectional radio se |
| oth physics and engineering research, and in | microwave communications, engineering applications wer |
| in Nashua, New Hampshire, a manufacturer of | microwave components used in commercial wireless and d |
| toclavable medical and laboratory equipment, | microwave components, and cookware. |
| toclavable medical and laboratory equipment, | microwave components, and cookware. |
| sactions on Electronic Computers proposing a | microwave computer that used travelling-wave tubes as |
| Frankel, Stanley P, “A Logic Design for a | Microwave Computer,” IRE Transactions on Electronic Co |
| The Astrid package sold by British firm MM | Microwave, consisting of a fixed frequency VHF receive |
| a fixed frequency visible laser to produce a | microwave created by a wave mixing process. |
| A tunable | microwave device is a device that works at radio frequ |
| This frequency is used for | microwave devices, WLAN, most modern radars. |
| edit in the areas of color-television tubes, | microwave devices, robotics and instrumentation. |
| Short-wave or | microwave diathermy uses high-frequency, high-intensit |
| Its origins are in | microwave discharge light sources used for ultraviolet |
| helium along with oxygen atoms generated by | microwave discharge, molecular SiO2 is produced which |
| RF and | microwave discretes |
| he spurline is a type of radio-frequency and | microwave distributed element filter with band-stop (n |
| Non-thermal | microwave effects have been posited in order to explai |
| tion, the Tellurometer, the first successful | microwave electronic distance measurement equipment (E |
| n WMAP cause the effect (ii) that unexpected | microwave emission from within the solar system is con |
| "Spinning dust" or more formally Anomalous | Microwave Emission (AME) is a galactic emission mechan |
| ro Scanning Radiometer (MSR)" which measures | microwave emission in the 23GHz and 31GHz bands. |
| s at Austin with a thesis entitled Anomalous | Microwave Emission from Bulk Semiconductors. |
| Instead, the | microwave energy itself directly couples to energy mod |
| The metal film absorbs | microwave energy efficiently and consequently becomes |
| erometers operate by transmitting a pulse of | microwave energy towards the Earth's surface and measu |
| are supposed not to require the transfer of | microwave energy into thermal energy. |
| 61 Brown published the first paper proposing | microwave energy for power transmission, and in 1964 h |
| The SSMIS instrument measures | microwave energy at 24 discrete frequencies from 19 to |
| Synthetic Aperture Radar (SAR), which sends | microwave energy to the ocean surface and records the |
| device that produces high-power, long-pulse | microwave energy. |
| Its technologies use | microwave energy. |
| n of his many distinguished contributions to | microwave engineering, both theoretical and experiment |
| l-free Sonogashira coupling, with or without | microwave enhancement. |
| Since 2004, WHSV has purchased additional | microwave equipment for use by its news department. |
| The dual frequency radar may be considered a | microwave equivalent of the high frequency (HF) radar |
| SMOSOMAS is a circular scanning astronomical | microwave experiment to investigate the Cosmic Microwa |
| magnetization in the xy-plane, but since the | microwave field (and therefore the rotating frame) do |
| t important and most widely used book in the | microwave field. |
| B; Wadhawan, A; Ye, Z; Tour, JM Nanotubes in | Microwave Fields: Light Emission, Intense Heat, Outgas |
| Levy, R. Cohn, S.B., "A History of | microwave filter research, design, and development", I |
| this type include tunable varators, tunable | microwave filters, tunable phase shifters, and tunable |
| In 1984 he founded Star | Microwave for the purpose of developing and manufactur |
| as the extrapolated infrared dust signal to | microwave frequencies should have been at least an ord |
| The BRS band uses | microwave frequencies at 2.1 GHz and from 2.5 GHz to 2 |
| It has low dielectric loss, especially at | microwave frequencies and is therefore used as dielect |
| laser, that is 100,000 times higher than the | microwave frequencies used in NIST-F1 and other simila |
| 2 µm, and its dielectric constant is 10.9 at | microwave frequencies . |
| r, first measurement of nanodevice motion at | microwave frequencies, discovery of the giant planar H |
| netically tunable filters and resonators for | microwave frequencies. |
| unable patch antenna structures operating at | microwave frequencies. |
| The | microwave frequency which produces maximum fluorescenc |
| roximately 45 GHz, and are commonly used for | microwave frequency communications and radar. |
| telescope for solar observation in radio and | microwave frequency range. |
| PR where the lineshape is observed at fixed ( | microwave) frequency and in a magnetic field range. |
| ure celestial polarisation in the unexplored | microwave frequency range of 20-90 GHz. |
| lian and military radars that operate in the | microwave frequency band. |
| n which the Larmor frequency is equal to the | microwave frequency. |
| ed VHF channel 7 to seek UPN programming via | microwave from UPN owned-and-operated station WTOG in |
| Donald J. Sullivan, "High Power | Microwave Generation From a Virtual Cathode scillator |
| Thomas J. T. Kwan, "High-Power Coherent | Microwave Generation from Oscillating Virtual Cathodes |
| A vircator (VIRtual CAthode oscillaTOR) is a | microwave generator that is capable of generating brie |
| U.S. Patent 4,730,170, "Virtual cathode | microwave generator having annular anode slit," Thomas |
| U.S. Patent 4,345,220, High power | microwave generator using relativistic electron beam i |
| laser diodes, solar cells, and components of | microwave generators. |
| sics PDE problems such as flame propagation, | microwave heating, two-phase flow, heat transfer, ther |
| The | Microwave Humidity Sounder (MHS) is an instrument laun |
| The | Microwave Humidity Sounder has been designed and devel |
| MHS - | Microwave Humidity Sounder |
| such as high-energy laser ignition systems, | microwave hybrid microcircuit production, and miniatur |
| such as high-energy laser ignition systems, | microwave hybrid microcircuit production, and miniatur |
| The Special Sensor | Microwave Imager / Sounder (SSMI/S) is an eleven-chann |
| Its successor, the Special Sensor | Microwave Imager / Sounder (SSMIS), is an enhanced ele |
| d, deep convection diminished, and satellite | microwave imagery early on October 12 suggested that t |
| Bertha began to strengthen on July 6 as | microwave images showed a developing eye-like feature. |
| development of a small eye feature noted on | microwave images. |
| The | Microwave Imaging Radiometer with Aperture Synthesis i |
| ge the development and implementation of the | microwave instruments for the NASA SEASAT mission, inc |
| The receivers are based on Monolithic | Microwave Integrated Circuit (MMIC) technology, with l |
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