Введите слово или словосочетание на любом языке 👆
Язык:
Перевод и анализ слов искусственным интеллектом ChatGPT
На этой странице Вы можете получить подробный анализ слова или словосочетания, произведенный с помощью лучшей на сегодняшний день технологии искусственного интеллекта:
- как употребляется слово
- частота употребления
- используется оно чаще в устной или письменной речи
- варианты перевода слова
- примеры употребления (несколько фраз с переводом)
- этимология
Что (кто) такое infrared lighting - определение
CRAFT OF LIGHTING AT PERFORMANCES
Theatrical Lighting; Stage Lighting 101; Theatrical lighting; Theater lighting; Theatre lighting; Lighting instruments; Rig (stage lighting); Stage lights; Lighting rig; Lighting effects; History of stage lighting
![Dazzling light effects during a [[Kanye West]] show in 2011](https://commons.wikimedia.org/wiki/Special:FilePath/Call of Duty XP 2011 - Kanye West performs (6125806122).jpg?width=200 "Dazzling light effects during a [[Kanye West]] show in 2011")
![WWE SmackDown Live]]'' televised [[professional wrestling]] show.](https://commons.wikimedia.org/wiki/Special:FilePath/Shakedown 01 (31797512165).jpg?width=200 "WWE SmackDown Live]]'' televised [[professional wrestling]] show.")
Найдено результатов: 452
infrared
![Active-infrared night vision: the camera illuminates the scene at infrared wavelengths invisible to the [[human eye]]. Despite a dark back-lit scene, active-infrared night vision delivers identifying details, as seen on the display monitor.](https://commons.wikimedia.org/wiki/Special:FilePath/Active-Infrared-Night-Vision.jpg?width=200 "Active-infrared night vision: the camera illuminates the scene at infrared wavelengths invisible to the [[human eye]]. Despite a dark back-lit scene, active-infrared night vision delivers identifying details, as seen on the display monitor.")
![Infrared light from the [[LED]] of a [[remote control]] as recorded by a digital camera](https://commons.wikimedia.org/wiki/Special:FilePath/Blue infrared light.jpg?width=200 "Infrared light from the [[LED]] of a [[remote control]] as recorded by a digital camera")
![[[Beta Pictoris]] with its planet Beta Pictoris b, the light-blue dot off-center, as seen in infrared. It combines two images, the inner disc is at 3.6 μm.](https://commons.wikimedia.org/wiki/Special:FilePath/ESO - Beta Pictoris planet finally imaged (by).jpg?width=200 "[[Beta Pictoris]] with its planet Beta Pictoris b, the light-blue dot off-center, as seen in infrared. It combines two images, the inner disc is at 3.6 μm.")
![Materials with higher [[emissivity]] appear closer to their true temperature than materials that reflect more of their different-temperature surroundings. In this thermal image, the more reflective ceramic cylinder, reflecting the cooler surroundings, appears to be colder than its cubic container (made of more emissive silicon carbide), while in fact, they have the same temperature.](https://commons.wikimedia.org/wiki/Special:FilePath/Effect of emissivity on apparent temperature.jpg?width=200 "Materials with higher [[emissivity]] appear closer to their true temperature than materials that reflect more of their different-temperature surroundings. In this thermal image, the more reflective ceramic cylinder, reflecting the cooler surroundings, appears to be colder than its cubic container (made of more emissive silicon carbide), while in fact, they have the same temperature.")
![The [[greenhouse effect]] with molecules of methane, water, and carbon dioxide re-radiating solar heat](https://commons.wikimedia.org/wiki/Special:FilePath/Greenhouse-effect-t2.svg?width=200 "The [[greenhouse effect]] with molecules of methane, water, and carbon dioxide re-radiating solar heat")
![hair salons]], c. 2010s](https://commons.wikimedia.org/wiki/Special:FilePath/Hooded dryer for infrared hair drying at hair salon - shown from three perspectives.jpg?width=200 "hair salons]], c. 2010s")
![An infrared reflectogram of ''[[Mona Lisa]]'' by [[Leonardo da Vinci]]](https://commons.wikimedia.org/wiki/Special:FilePath/Infrared reflectograms of Mona Lisa.jpg?width=200 "An infrared reflectogram of ''[[Mona Lisa]]'' by [[Leonardo da Vinci]]")
![IR satellite picture of cumulonimbus clouds over the [[Great Plains]] of the United States.](https://commons.wikimedia.org/wiki/Special:FilePath/NOAA Shares First Infrared Imagery from GOES-17 (43904870711).gif?width=200 "IR satellite picture of cumulonimbus clouds over the [[Great Plains]] of the United States.")
![Thermography helped to determine the temperature profile of the [[Space Shuttle thermal protection system]] during re-entry.](https://commons.wikimedia.org/wiki/Special:FilePath/STS-3 infrared on reentry.jpg?width=200 "Thermography helped to determine the temperature profile of the [[Space Shuttle thermal protection system]] during re-entry.")
![false-color]] infrared space telescope image has blue, green and red corresponding to 3.4, 4.6, and 12 [[μm]] wavelengths, respectively.](https://commons.wikimedia.org/wiki/Special:FilePath/Wide-field Infrared Survey Explorer first-light image.jpg?width=200 "false-color]] infrared space telescope image has blue, green and red corresponding to 3.4, 4.6, and 12 [[μm]] wavelengths, respectively.")
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
<electronics> (IR) Electromagnetic waves in the frequency
range just below visible light corresponding to radiated heat.
IR waves can be generated by a kind of LED and are often
used for remote controls for televisions etc. and in some
docking stations.
(1997-01-30)
infrared
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
also infra-red
1.
Infrared radiation is similar to light but has a longer wavelength, so we cannot see it without special equipment.
ADJ: ADJ n
2.
Infrared equipment detects infrared radiation.
...searching with infra-red scanners for weapons and artillery.
ADJ: ADJ n
infra-red
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
see infrared
Infrared
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
Infrared (IR), sometimes called infrared light, is electromagnetic radiation (EMR) with wavelengths longer than those of visible light. It is therefore invisible to the human eye.
Infra-red
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
·add. ·adj Lying outside the visible spectrum at its red end;
- said of rays less refrangible than the extreme red rays.
infrared
ELECTROMAGNETIC RADIATION WITH LONGER WAVELENGTHS THAN THOSE OF VISIBLE LIGHT
Infra-red radiation; Infra-red; Infrared radiation; Near-infrared; Infrared Radiation; Infrared light; Near infrared; Infra-red light; Near Infrared; 1550 nm; LWIR; MWIR; Infra red; Infared; 1300 nm; Infrared spectrum; Infra Red; Infra-Red; InfraRed; Infrared sources; Long-wave infrared; Line of light; Infrared communication; Calorific rays; Calorific Rays; Mid-infrared; Infrared rays; Thermal infrared; Infra-red reflectography; Infrared reflectography; Infrared Rays; Infrared Ray; IR-A; IR-B; IR-C; IR radiation; NIR Photons; MIR photons; Short-wavelength infrared; Infrared bands; Short-wave infrared; Mid-wave infrared; Near-infrared light; Mid infrared; 830 nm; 850 nm; Thermal infrared radiation; Applications of infrared radiation; History of infrared science; Infrared source
¦ noun electromagnetic radiation having a wavelength just greater than that of red light but less than that of microwaves, emitted particularly by heated objects.
¦ adjective of or denoting such radiation.
Infrared Physics and Technology
JOURNAL
Infrared Phys Technol; Infrared Phys. Technol.; Infrared Physics & Technology
Infrared Physics and Technology is a peer-reviewed scientific journal published by Elsevier devoted to the publication of new experimental and theoretical papers about applications of physics to the field of infrared physics and technology.
Infrared spectroscopy
![3D animation of the symmetric stretch-compress mode of the C–H bonds of [[bromomethane]]](https://commons.wikimedia.org/wiki/Special:FilePath/Bromomethane.gif?width=200 "3D animation of the symmetric stretch-compress mode of the C–H bonds of [[bromomethane]]")
![Sample of an IR spec. reading; this one is from [[bromomethane]] (CH<sub>3</sub>Br), showing peaks around 3000, 1300, and 1000 cm<sup>−1</sup> (on the horizontal axis).](https://commons.wikimedia.org/wiki/Special:FilePath/Bromomethane IR spectroscopy.svg?width=200 "Sample of an IR spec. reading; this one is from [[bromomethane]] (CH<sub>3</sub>Br), showing peaks around 3000, 1300, and 1000 cm<sup>−1</sup> (on the horizontal axis).")
![Stretching and bending oscillations]] of the CO<sub>2</sub> carbon dioxide molecule. Upper left: symmetric stretching. Upper right: antisymmetric stretching. Lower line: degenerate pair of bending modes.](https://commons.wikimedia.org/wiki/Special:FilePath/Co2 vibrations.svg?width=200 "Stretching and bending oscillations]] of the CO<sub>2</sub> carbon dioxide molecule. Upper left: symmetric stretching. Upper right: antisymmetric stretching. Lower line: degenerate pair of bending modes.")
![An interferogram from an [[FTIR]] measurement. The horizontal axis is the position of the mirror, and the vertical axis is the amount of light detected. This is the "raw data" which can be [[Fourier transform]]ed to get the actual spectrum.](https://commons.wikimedia.org/wiki/Special:FilePath/FTIR-interferogram.svg?width=200 "An interferogram from an [[FTIR]] measurement. The horizontal axis is the position of the mirror, and the vertical axis is the amount of light detected. This is the \"raw data\" which can be [[Fourier transform]]ed to get the actual spectrum.")
![cm<sup>−1</sup>]].](https://commons.wikimedia.org/wiki/Special:FilePath/IR-spectroscopy-sample.svg?width=200 "cm<sup>−1</sup>]].")
![Schematics of a two-beam absorption spectrometer. A beam of infrared light is produced, passed through an [[interferometer]] (not shown), and then split into two separate beams. One is passed through the sample, the other passed through a reference. The beams are both reflected back towards a detector, however first they pass through a splitter, which quickly alternates which of the two beams enters the detector. The two signals are then compared and a printout is obtained. This "two-beam" setup gives accurate spectra even if the intensity of the light source drifts over time.](https://commons.wikimedia.org/wiki/Special:FilePath/IR spectroscopy apparatus.svg?width=200 "Schematics of a two-beam absorption spectrometer. A beam of infrared light is produced, passed through an [[interferometer]] (not shown), and then split into two separate beams. One is passed through the sample, the other passed through a reference. The beams are both reflected back towards a detector, however first they pass through a splitter, which quickly alternates which of the two beams enters the detector. The two signals are then compared and a printout is obtained. This \"two-beam\" setup gives accurate spectra even if the intensity of the light source drifts over time.")
![US [[Food and Drug Administration]] scientist uses portable near infrared spectroscopy device to detect potentially illegal substances](https://commons.wikimedia.org/wiki/Special:FilePath/Portable Screening Devices (1435) (8225044148).jpg?width=200 "US [[Food and Drug Administration]] scientist uses portable near infrared spectroscopy device to detect potentially illegal substances")
![CaF<sub>2</sub>]].](https://commons.wikimedia.org/wiki/Special:FilePath/SolnIRcell.jpg?width=200 "CaF<sub>2</sub>]].")
INVOLVES THE INTERACTION OF INFRARED RADIATION WITH MATTER
Vibrational spectroscopy; Infra-red spectroscopy; Infared spectroscopy; Quantum vibrations; IR spectroscopy; Infrared spectrometry; Infrared Spectroscopy; IR spectrum; Spectrophotometry, infrared; IR Spectroscopy; Infrared spectrometer; Fingerprint region; IR spectra; IR spec; IR Spec; Infrared Spectrometer; Scissoring, wagging, twisting, and rocking; Infrared spectrophotometry; Ir spec; Ir Spectroscopy; Ir spectroscopy; Infra-red (IR) spectroscopy; IR-spectrum; Badger's rule; Infrared spectra; Vibrational spectroscopies; IR-spectroscopy; Infrared absorption spectrum
Infrared spectroscopy (IR spectroscopy or vibrational spectroscopy) is the measurement of the interaction of infrared radiation with matter by absorption, emission, or reflection. It is used to study and identify chemical substances or functional groups in solid, liquid, or gaseous forms.
Lighting Research & Technology
JOURNAL
User:AntonV/Lighting Research & Technology; Lighting Res Technol; Lighting Res. Technol.; Lighting Research and Technology; Light. Res. Technol.; Light Res Technol
Lighting Research & Technology is a peer-reviewed scientific journal covering all aspects of light and lighting. Its editor-in-chief is Steve Fotios (University of Sheffield).
Lighting for the elderly
![A 230-volt [[incandescent light bulb]], which gives strong, steady light ideal for illumination.](https://commons.wikimedia.org/wiki/Special:FilePath/Gluehlampe 01 KMJ.png?width=200 "A 230-volt [[incandescent light bulb]], which gives strong, steady light ideal for illumination.")
![Bright [[light therapy]] is a common treatment for [[seasonal affective disorder]] and for [[circadian rhythm sleep disorder]]s](https://commons.wikimedia.org/wiki/Special:FilePath/Light Therapy for SAD.jpg?width=200 "Bright [[light therapy]] is a common treatment for [[seasonal affective disorder]] and for [[circadian rhythm sleep disorder]]s")
![commuter train]] catering for mainly seated passengers](https://commons.wikimedia.org/wiki/Special:FilePath/Passenger compartment Class 440.jpg?width=200 "commuter train]] catering for mainly seated passengers")
User:Sherazade96/Lighting for the elderly
Designing lighting for the elderly requires special consideration and care from architects and lighting designers. As people age, they experience neurodegeneration in the retina and in the suprachiasmatic nucleus (SCN).
Википедия
Stage lighting
Stage lighting is the craft of lighting as it applies to the production of theater, dance, opera, and other performance arts. Several different types of stage lighting instruments are used in this discipline. In addition to basic lighting, modern stage lighting can also include special effects, such as lasers and fog machines. People who work on stage lighting are commonly referred to as lighting technicians or lighting designers.
The equipment used for stage lighting (e.g. cabling, dimmers, lighting instruments, controllers) are also used in other lighting applications, including corporate events, concerts, trade shows, broadcast television, film production, photographic studios, and other types of live events. The personnel needed to install, operate, and control the equipment also cross over into these different areas of "stage lighting" applications.
