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			{{Short description\|Property of light sources related to black-body radiation}}
	] ''x,y'' chromaticity space, also showing the chromaticities of black-body light sources of various temperatures (]), and lines of constant '']''.]]
			{{Use American English\|date=March 2021}}
			{{Use mdy dates\|date=March 2021}}
			{{more citations needed\|date=June 2012}}
			] ''x,y'' chromaticity space, also showing the chromaticities of black-body light sources of various temperatures (]), and lines of constant ]]]

			'''Color temperature''' is a parameter describing the ] of a ] source by comparing it to the color of ] by an ]. The ] of the ideal emitter that matches the color most closely is defined as the color temperature of the original visible light source. The color temperature scale describes only the ''color'' of light emitted by a light source, which may actually be at a different (and often much lower) temperature.<ref>{{Cite web \|title=Colour temperature explained {{!}} Adobe \|url=https://www.adobe.com/hk_en/creativecloud/video/discover/color-temperature.html \|access-date=2024-06-17 \|website=www.adobe.com \|language=en-HK}}</ref><ref>{{Cite web \|title=What is Color Temperature? How Does it Affect Color Performance of the Monitor? \|url=https://www.benq.com/en-us/knowledge-center/knowledge/color-temperature.html \|access-date=2024-06-17 \|website=BenQ \|language=en}}</ref>
	'''Color temperature''' is a characteristic of ] that has important applications in lighting, photography, videography, publishing, and other fields. The color temperature of a light source is determined by comparing its ] with that of an ideal ]. The temperature (usually measured in ] (K)) at which the heated black-body radiator matches the color of the light source is that source's color temperature; for a black body source, it is directly related to ] and ].

			Color temperature has applications in ],<ref>{{Cite web \|date=2022-02-22 \|title=Kelvin Color Temperature Chart {{!}} Lighting Color Scale at Lumens \|url=https://www.lumens.com/the-edit/the-guides/understanding-kelvin-color-temperature/ \|access-date=2024-06-17 \|website=www.lumens.com \|language=en-US}}</ref> ],<ref>{{Cite web \|last=IoP \|date=2023-04-17 \|title=Colour Temperature and Its Importance in Photography \|url=https://www.institute-of-photography.com/colour-temperature-and-its-importance-in-photography/ \|access-date=2024-06-17 \|website=Institute of Photography \|language=en}}</ref> ],<ref>{{Cite web \|last=Redding \|first=Kevin \|date=2023-02-10 \|title=Why Color Temperature Is Important in Filmmaking and Editing \|url=https://www.backstage.com/magazine/article/what-is-color-temperature-75608/ \|access-date=2024-06-17 \|website=Backstage}}</ref> ],<ref>{{Cite web \|last= \|date=2020-12-23 \|title=Correct Color Temperature When Lighting Prints \|url=https://gintchinfineart.com/blog/lighting-prints-color-temperature/ \|access-date=2024-06-17 \|website=Gintchin Fine Art \|language=en-US}}</ref> ],<ref>{{Cite web \|last=de Varona \|first=Ray \|date=2020-01-24 \|title=Ideal Color Temperature for Office and Industrial Spaces \|url=https://relightdepot.com/blog/ideal-color-temperature-for-office-and-industrial-spaces/ \|access-date=2024-06-17 \|website=RelightDepot \|language=en}}</ref> ],<ref>{{Cite web \|title=Colors of Stars {{!}} Astronomy \|url=https://courses.lumenlearning.com/suny-astronomy/chapter/colors-of-stars/ \|access-date=2024-06-17 \|website=courses.lumenlearning.com}}</ref> and other fields. In practice, color temperature is most meaningful for light sources that correspond somewhat closely to the color of some black body, i.e., light in a range going from red to orange to yellow to ] to bluish white. Although the concept of correlated color temperature extends the definition to any visible light, the color temperature of a green or a purple light rarely is useful information. Color temperature is conventionally expressed in ]s<!-- pluralized – see Kelvin#Usage conventions -->, using the symbol K, a ] for absolute temperature.
	Counterintuitively, higher Kelvin temperatures (5000 K or more) are "cool" (green–blue) colors, and lower color temperatures (2700–3000 K) "warm" (yellow–red) colors. Cool-colored light is considered better for visual tasks.{{Fact\|date=October 2008}} Warm-colored light is preferred for living spaces because it is considered more flattering to skin tones and clothing.{{Fact\|date=October 2008}} Color temperatures in the 2700–3600 K range are recommended for most general indoor and task lighting.{{Fact\|date=August 2008}}

			Color temperatures over 5000 K are called "cool colors" (bluish), while lower color temperatures (2700–3000 K) are called "warm colors" (yellowish). "Warm" in this context is with respect to a traditional categorization of colors, not a reference to black body temperature. The ] states that low color temperatures will feel warmer while higher color temperatures will feel cooler. The spectral peak of warm-colored light is closer to infrared, and most natural warm-colored light sources emit significant infrared radiation. The fact that "warm" lighting in this sense actually has a "cooler" color temperature often leads to confusion.<ref>See the comments section of this LightNowBlog.com {{webarchive\|url=https://web.archive.org/web/20170307123725/http://www.lightnowblog.com/2016/07/ama-issues-led-streetlighting-guidance-controversy-ensues/ \|date=2017-03-07 }} on the recommendations of the ] to prefer LED-lighting with ''cooler'' color temperatures (i.e. ''warmer'' color).</ref>
	== Categorizing different lighting ==

			==Categorizing different lighting==
	{\| class="wikitable" align="right" style="margin:15px;"
			{{Stack\|{{Color temperature scale}}}}
	\|-
			] radiance (B{{sub\|λ}}) vs. wavelength (λ) curves for the ]. The vertical axes of ] plots building this animation were proportionally transformed to keep equal areas between functions and horizontal axis for wavelengths 380–780 nm. K indicates the color temperature in ]s, and M indicates the color temperature in micro reciprocal degrees.\|right]]
	! Temperature
	! Source
	\|-
	\| 1700 K
	\| Match flame
	\|-
	\| 1850 K
	\| Candle flame
	\|-
	\| 2800–3300 K
	\| Incandescent light bulb
	\|-
	\| 3350 K
	\| Studio "CP" light
	\|-
	\| 3400 K
	\| Studio lamps, photofloods, etc.
	\|-
	\| 4100 K
	\| Moonlight, xenon arc lamp
	\|-
	\| 5000 K
	\| Horizon daylight
	\|-
	\| 5500–6000 K
	\| Typical daylight, electronic flash
	\|-
	\| 6500 K
	\| Daylight, overcast
	\|-
	\| 9300 K
	\| CRT screen
	\|-
	\| colspan="2" style="font-size:x-small;" \| ''Note'': These temperatures are merely approximations;<br/>considerable variation may be present.
	\|}

	~~Because it is the standard against which other light sources are compared, the~~ color temperature of the ~~thermal~~ radiation from an ideal ] ~~radiator~~ is defined as ~~equal to~~ its surface temperature in kelvin, or alternatively in '']'' (~~micro-reciprocal degrees kelvin~~).<ref>{{cite book		The color temperature of the ] emitted from an ideal ] is defined as its surface temperature in ]s, or alternatively in ]s (mired).<ref>{{cite book
	\| title = Principles of Lighting		\| title = Principles of Lighting
	\| author = Wallace Roberts Stevens		\| author = Wallace Roberts Stevens
	\| publisher = Constable		\| publisher = Constable
	\| year = 1951		\| year = 1951
	\| url = ~~http~~://books.google.com/books?id=gH5RAAAAMAAJ&q=micro-reciprocal-degree+date:0-1960~~&dq=micro-reciprocal-degree+date:0-1960&lr=&as_brr=0&ei=D4u8R7ecD4vAiwGZ3N3JBQ&pgis=1~~ }}		\| url = https://books.google.com/books?id=gH5RAAAAMAAJ&q=micro-reciprocal-degree+date:0-1960 }}
			</ref> This permits the definition of a standard by which light sources are compared.
	</ref>
	For source other than ideal black bodies, the color temperature of the ] emitted from it may differ from its actual surface temperature. In an ] the light is of thermal origin and is very close to that of an ideal black-body radiator.

			To the extent that a hot surface emits ] but is not an ideal black-body radiator, the color temperature of the light is not the actual temperature of the surface. An ]'s light is thermal radiation, and the bulb approximates an ideal black-body radiator, so its color temperature is essentially the temperature of the filament. Thus a relatively low temperature emits a dull red and a high temperature emits the almost white of the traditional incandescent light bulb. Metal workers are able to judge the temperature of hot metals by their color, from dark red to orange-white and then white (see ]).
	However, many other light sources, such as ]s, emit light primarily by processes other than raising the temperature of a body. This means the emitted radiation does not follow the form of a ]. These sources are assigned what is known as a ] (CCT). CCT is the color temperature of a black body radiator which to ] most closely matches the light from the lamp. Because such an approximation is not required for incandescent light, the CCT for an incandescent light is simply its unadjusted temperature, derived from the comparison to a black body radiator.

			Many other light sources, such as ]s, or light emitting diodes (]s) emit light primarily by processes other than thermal radiation. This means that the emitted radiation does not follow the form of a ]. These sources are assigned what is known as a ] (CCT). CCT is the color temperature of a black-body radiator which to ] most closely matches the light from the lamp. Because such an approximation is not required for incandescent light, the CCT for an incandescent light is simply its unadjusted temperature, derived from comparison to a black-body radiator.
	===The sun===

			===The Sun===
	As the ] crosses the sky, it may appear to be red, orange, yellow or white depending on its position. The changing color of the sun over the course of the day is mainly a result of ] and, to a lesser extent, ] of light, and is unrelated to black body radiation. The blue color of the sky is not due to black-body radiation, but rather to ] of the sunlight from the atmosphere, which tends to scatter blue light more than red. This phenomenon has nothing to do with the properties of a black body.
			The ] closely approximates a black-body radiator. The effective temperature, defined by the total radiative power per square unit, is 5772 K.<ref>{{cite web \|last=Williams \|first=David R. \|year=2022 \|title=Sun Fact Sheet \|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/sunfact.html \|publisher=] \|access-date=2023-03-24 \|url-status=live \|archive-url=https://web.archive.org/web/20230316150908/https://nssdc.gsfc.nasa.gov/planetary/factsheet/sunfact.html \|archive-date=2023-03-16 }}</ref> The color temperature of ] above the atmosphere is about 5900 K.<ref>{{cite web \|url=http://www.crisp.nus.edu.sg/~research/tutorial/optical.htm \|title=Principles of Remote Sensing \|publisher=] \|access-date=2012-06-18 \|url-status=live \|archive-url=https://web.archive.org/web/20120702174159/http://www.crisp.nus.edu.sg/~research/tutorial/optical.htm \|archive-date=2012-07-02 }}</ref>

			The Sun may appear red, orange, yellow, or white from Earth, depending on ] in the sky. The changing color of the Sun over the course of the day is mainly a result of the ] of sunlight and is not due to changes in black-body radiation. ] of sunlight by ] causes the blue color of the sky, which tends to scatter blue light more than red light.
	Daylight has a spectrum similar to that of a black body. In professions involving color reproduction, such as photography and publishing, daylight is often approximated using ] D50 or ], as recommended by the CIE.

			Some ] in the early ] and late ] (the ]) has a lower ("warmer") color temperature due to increased ] of shorter-wavelength sunlight by ] – an ] called the ].
	] scale.]]

			Daylight has a spectrum similar to that of a black body with a correlated color temperature of 6500 K (] viewing standard) or 5500 K (daylight-balanced photographic film standard).
	For colors based on the black body, blue is the "hotter" color, while red is actually the "cooler" color. This is the opposite of the ] that colors have taken on, with "red" as "hot", and "blue" as "cold". The traditional associations come from a variety of sources, such as water and ice appearing blue, while heated metal and ] are of a reddish hue. However, the redness of these heat sources comes precisely from the fact that red is the ''coolest'' of the visible colors, the first color emitted as heat increases.

			]]]
	== Color temperature applications ==

			For colors based on black-body theory, blue occurs at higher temperatures, whereas red occurs at lower temperatures. This is the opposite of the cultural associations attributed to colors, in which "red" is "hot", and "blue" is "cold".<ref>
	"Color temperature" is sometimes used{{Who\|date=August 2008}} loosely to mean "]" or "]". However, color temperature has only one ], whereas white balance has two, R-Y and B-Y. Then again, this is wikipedia, so this paragraph is probably completely wrong.
			{{cite book
			\| title = Mastering Digital Flash Photography: The Complete Reference Guide
			\| author = Chris George
			\| publisher = ]
			\| year = 2008
			\| isbn = 978-1-60059-209-6
			\| page = 11
			\| url = https://books.google.com/books?id=j728wJySfyQC&q=blue+cool+red+hot+color-temperature+sun
			}}</ref>

			==Applications==
	=== Film photography ===
			]

	Film sometimes appears to exaggerate the color of the light, since it does not adapt to lighting color as our visual perception does. An object that appears to the eye to be white may turn out to look very blue or orange in a photograph. The ] may need to be corrected while shooting or while printing to achieve a neutral color print.

	Film is made for specific light sources (most commonly daylight film and ]), and used properly, will create a neutral color print. Matching the ] to the color temperature of the light source is one way to balance color. If tungsten film is used indoors with ] lamps, the yellowish-orange light of the ] bulbs will appear as white (3200 K) in the photograph.

	] on a camera lens, or ]s over the light source(s) may also be used to correct color balance. When shooting with a bluish light (high color temperature) source such as on an overcast day, in the shade, in window light or if using tungsten film with white or blue light, a yellowish-orange filter will correct this. For shooting with daylight film (calibrated to 5600 K) under warmer (low color temperature) light sources such as sunsets, candle light or tungsten lighting, a bluish (e.g. #80A) filter may be used.

	If there is more than one light source with varied color temperatures, one way to balance the color is to use daylight film and place color-correcting gel filters over each light source.

	Photographers sometimes use color temperature meters. Color temperature meters are usually designed to read only two regions along the visible spectrum (red and blue); more expensive ones read three regions (red, green, and blue). However, they are ineffective with sources such as fluorescent or discharge lamps, whose light varies in color and may be harder to correct for. Because it is often greenish, a magenta filter may correct it. More sophisticated ] tools can be used where such meters are lacking.

	=== Desktop publishing ===

	In the desktop publishing industry, it is important to know your monitor’s color temperature. Color matching software, such as ] will measure a monitor's color temperature and then adjust its settings accordingly. This enables on-screen color to more closely match printed color. Common monitor color temperatures, along with matching ]s in parentheses, are as follows:

	5000 K (D50), 5500 K (D55), 6500 K (]), 7500 K (D75), 9300 K.

	Designations such as ''D50'' are used to classify color temperatures of ]s and viewing booths. When viewing a ] at a light table, it is important that the light be balanced properly so that the colors are not shifted towards the red or blue.

	]s, web graphics, ]s, etc. are normally designed for a 6500 K color temperature. The ] commonly used for images on the internet stipulates (among other things) a 6500 K display whitepoint.

	=== TV, video, and digital still cameras ===

	The ] and ] TV norms call for a compliant TV screen to display an electrically "black-and-white" signal (minimal color saturation) at a color temperature of 6500 K. On many actual sets, however, especially older or lower-quality units, there is a very noticeable deviation from this requirement.

	Most video and digital still cameras can adjust for color temperature by zooming into a white or neutral colored object and setting the manual "white balance" (telling the camera that "this object is white"); the camera then shows true white as white and adjusts all the other colors accordingly. White-balancing is necessary especially when indoors under fluorescent lighting and when moving the camera from one lighting situation to another. Most cameras also have an automatic white balance function that attempts to determine the color of the light and correct accordingly. While these settings were once unreliable, they are much improved in today's digital cameras, and will produce the "correct" white balance in a wide variety of lighting situations.

	=== Artistic application via control of color temperature ===

	]

	Experimentation with color temperature is obvious in many ] films; for instance in '']'' the light coming in from a window was almost always conspicuously blue, whereas the light from lamps on end tables was fairly orange. Indoor lights typically give off a yellow hue; fluorescent and natural lighting tends to be more blue.

	Video ]s can also white-balance objects which aren't white, downplaying the color of the object used for white-balancing. For instance, they can bring more warmth into a picture by white-balancing off something light blue, such as faded blue denim; in this way white-balancing can serve in place of a filter or lighting gel when those aren't available.

	]s do not "white balance" in the same way as video camera operators; they can use techniques such as filters, choice of film stock, ], and after shooting, ] (both by exposure at the labs and also digitally). Cinematographers also work closely with set designers and lighting crews to achieve the desired effects.

	For artists, most pigments and papers have a cool or warm cast, as the human eye can detect even a minute amount of saturation. Gray mixed with yellow, orange or red is a "warm gray". Green, blue, or purple, create "cool grays". Note that this sense of ''temperature'' is the reverse of that of real temperature; bluer is described as "cooler" even though it corresponds to a higher-temperature ].
	{\| style="border:1px solid #aaaaaa; background-color:#ffffff; padding:5px; font-size:95%; margin: 0px 12px 12px 0px; float: right; margin-left: 10px"
	\|- align=center
	\|colspan=2\|]
	\|- align=center
	\|\|'''WARM GRAY'''
	\|\|'''COOL GRAY'''
	\|- align=center
	\|\|Mixed with 6% yellow.
	\|\|Mixed with 6% blue.
	\|}

	] sometimes select ] by color temperature, commonly to match light that is theoretically white. Since fixtures using ] type lamps produce a light of considerably higher color temperature than ], using the two in conjunction could potentially produce a stark contrast, so sometimes fixtures with HID lamps, commonly producing light of 6000–7000 K, are fitted with 3200 K filters to emulate tungsten light. Fixtures with color mixing features or with multiple colors, (if including 3200 K) are also capable of producing tungsten like light. Color temperature may also be a factor when selecting ], since each is likely to have a different color temperature.<ref></ref>

	===Lighting===		===Lighting===
			]
	For lighting buildings, it is often important to take into account the color temperature of the light fittings used. For example, a warmer (i.e., lower temperature) light is often used in public areas to promote relaxation, while a cooler, whiter light is used in offices. Due to heightened awareness of the stress that poor lighting can cause, as well as ], many governmental agencies have certain criteria that lighting must meet.{{Who\|date=August 2008}}

			For lighting building interiors, it is often important to take into account the color temperature of illumination. A warmer (i.e., a lower color temperature) light is often used in public areas to promote relaxation, while a cooler (higher color temperature) light is used to enhance concentration, for example in schools and offices.<ref>{{cite book
	The international color code is often used to denote the temperature of a lamp's light. This code is a three digit number. The first digit refers to the ]: if it is 8, then the CRI is between 80 and 90, if it is 9, it lies between 90 and 100. The next two numbers are the color temperature (to the nearest hundred) divided by one hundred kelvins, thus if the temperature is 6500 K, the number is 65.<ref> (Osram)</ref>
			\| title = Encyclopedia of Laser Physics and Technology
			\| author = Rüdiger Paschotta
			\| publisher = Wiley-VCH
			\| year = 2008
			\| isbn = 978-3-527-40828-3
			\| page = 219
			\| url = https://books.google.com/books?id=BN026ye2fJAC&q=lighting%20color-temperature%20relaxing&pg=PA219
			}}{{Dead link\|date=December 2023 \|bot=InternetArchiveBot \|fix-attempted=yes }}</ref>

			CCT dimming for LED technology is regarded as a difficult task, since binning, age and temperature drift effects of LEDs change the actual color value output. Here feedback loop systems are used, for example with color sensors, to actively monitor and control the color output of multiple color mixing LEDs.<ref>{{cite journal
	== Correlated color temperature ==<!-- This section is linked from ] -->
			\| title = Sensors and Feedback Control of Multi-Color LED Systems
			\| author = Thomas Nimz, Fredrik Hailer and Kevin Jensen
			\| journal = LED Professional Review: Trends & Technologie for Future Lighting Solutions
			\| publisher = LED Professional
			\| year = 2012
			\| issn = 1993-890X
			\| pages = 2–5
			\| url = http://www.mazet.de/en/english-documents/english/featured-articles/sensors-and-feedback-control-of-multi-color-led-systems-1/download#.UX7VXYIcUZI
			\| url-status = dead
			\| archive-url = https://web.archive.org/web/20140429162806/http://www.mazet.de/en/english-documents/english/featured-articles/sensors-and-feedback-control-of-multi-color-led-systems-1/download#.UX7VXYIcUZI
			\| archive-date = 2014-04-29
			}}</ref>

			===Aquaculture===
	{{quote\|The '''correlated color temperature''' (T<sub>cp</sub>) is the temperature
	of the Planckian radiator whose perceived colour most closely resembles that of a given stimulus at the same brightness and under specified viewing conditions\| \|International Lighting Vocabulary (ISBN 3900734070)<ref>{{cite journal\|title=The concept of correlated colour temperature revisited\|first=Ákos\|last=Borbély\|coauthors=Sámson, Árpád; Schanda, János\|volume=26\|issue=6\|pages=450–457\|month=December\|year=2001\|doi=10.1002/col.1065\|journal=Color Research & Application\| url=http://www.knt.vein.hu/staff/schandaj/SJCV-Publ-2005/462.doc}}</ref>}}

			In ], color temperature has different functions and foci in the various branches.
	===Motivation===
	] radiators are the reference by which the whiteness of light sources is judged. A black body can be described by its color temperature, whose hues are depicted above. By analogy, nearly-Planckian light sources such as certain ] or ]s can be judged by their ''correlated'' color temperature (CCT); the color temperature of the Planckian radiator that best approximates them. The question is: what is the relationship between the light source's relative ] and its correlated color temperature?

			* In freshwater aquaria, color temperature is generally of concern only for producing a more attractive display.{{citation needed\|date=August 2012}} Lights tend to be designed to produce an attractive spectrum, sometimes with secondary attention paid to keeping the plants in the aquaria alive.
	===Background===
			* In a saltwater/reef ], color temperature is an essential part of tank health. Within about 400 to 3000 nanometers, light of shorter wavelength can ] than longer wavelengths,<ref>{{cite web\|url=http://www.lsbu.ac.uk/water/vibrat.html\|title=Water Absorption Spectrum\|last=Chaplin\|first=Martin\|access-date=2012-08-01\|url-status=live\|archive-url=https://web.archive.org/web/20120717061228/http://www.lsbu.ac.uk/water/vibrat.html\|archive-date=2012-07-17}}</ref><ref>{{cite journal \|author=Pope R. M., Fry E. S. \|year=1997 \|title=Absorption spectrum (380–700 nm) of pure water. II. Integrating cavity measurements \|journal=Applied Optics \|volume=36 \|issue=33 \|pages=8710–8723 \|publisher=Optical Society of America \|doi=10.1364/AO.36.008710 \|bibcode=1997ApOpt..36.8710P \|pmid=18264420 \|s2cid=11061625 }}</ref><ref>{{cite book \|author=Jerlov N. G. \|title=Marine Optics. \|series=Elsevie Oceanography Series. \|volume=14 \|pages=128–129 \|year=1976 \|publisher=Elsevier Scientific Publishing Company \|isbn=0-444-41490-8 \|location=Amsterdam \|url=https://books.google.com/books?id=tzwgrtnW_lYC&pg=PA128 \|access-date=August 1, 2012 \|url-status=live \|archive-url=https://web.archive.org/web/20171221064443/https://books.google.com/books?id=tzwgrtnW_lYC&lpg=PA128&pg=PA128 \|archive-date=December 21, 2017 }}</ref> providing essential energy sources to the algae hosted in (and sustaining) coral. This is equivalent to an increase of color temperature with water depth in this spectral range. Because coral typically live in shallow water and receive intense, direct tropical sunlight, the focus was once on simulating this situation with 6500 K lights.

			===Digital photography===
	].]]
			In ], the term color temperature sometimes refers to remapping of color values to simulate variations in ambient color temperature. Most digital cameras and raw image software provide presets simulating specific ambient values (e.g., sunny, cloudy, tungsten, etc.) while others allow explicit entry of white balance values in kelvins. These settings vary color values along the blue–yellow axis, while some software includes additional controls (sometimes labeled "tint") adding the magenta–green axis, and are to some extent arbitrary and a matter of artistic interpretation.<ref>{{cite web \|url=http://www.chriskern.net/essay/realityCheck.html \|title=Reality Check: Ambiguity and Ambivalence in Digital Color Photography \|last=Kern \|first=Chris \|access-date=2011-03-11 \|url-status=live \|archive-url=https://web.archive.org/web/20110722001411/http://www.chriskern.net/essay/realityCheck.html \|archive-date=2011-07-22 }}</ref>

			===Photographic film===
	]
			{{unreferenced section\|date=June 2012}}
			Photographic emulsion film does not respond to lighting color identically to the human retina or visual perception. An object that appears to the observer to be white may turn out to be very blue or orange in a photograph. The ] may need to be corrected during printing to achieve a neutral color print. The extent of this correction is limited since color film normally has three layers sensitive to different colors and when used under the "wrong" light source, every layer may not respond proportionally, giving odd color casts in the shadows, although the mid-tones may have been correctly white-balanced under the enlarger. Light sources with discontinuous spectra, such as fluorescent tubes, cannot be fully corrected in printing either, since one of the layers may barely have recorded an image at all.

			Photographic film is made for specific light sources (most commonly daylight film and ]), and, used properly, will create a neutral color print. Matching the ] to the color temperature of the light source is one way to balance color. If tungsten film is used indoors with incandescent lamps, the yellowish-orange light of the ] incandescent lamps will appear as white (3200 K) in the photograph. Color negative film is almost always daylight-balanced, since it is assumed that color can be adjusted in printing (with limitations, see above). Color transparency film, being the final artefact in the process, has to be matched to the light source or filters must be used to correct color.
	]

			] on a camera lens, or ]s over the light source(s) may be used to correct color balance. When shooting with a bluish light (high color temperature) source such as on an overcast day, in the shade, in window light, or if using tungsten film with white or blue light, a yellowish-orange filter will correct this. For shooting with daylight film (calibrated to 5600 K) under warmer (low color temperature) light sources such as sunsets, candlelight or ], a bluish (e.g. #80A) filter may be used. More-subtle filters are needed to correct for the difference between, say 3200 K and 3400 K tungsten lamps or to correct for the slightly blue cast of some flash tubes, which may be 6000 K.<ref name=":0">{{Cite book\|last=Präkel\|first=David\|url=https://books.google.com/books?id=VHBUDwAAQBAJ&q=photography+lighting+kelvin&pg=PP1\|title=Basics Photography 02: Lighting\|date=2013-02-28\|publisher=Bloomsbury Publishing\|isbn=978-2-940447-55-8\|language=en}}</ref>
	]s. Note the even spacing of the isotherms when using the reciprocal temperature scale, and compare with the similar figure below. The even spacing of the isotherms on the locus implies that the mired scale is a better measure of perceptual color difference than the temperature scale.]]

			If there is more than one light source with varied color temperatures, one way to balance the color is to use daylight film and place color-correcting gel filters over each light source.
	The notion of using Planckian radiators as a yardstick to judge other light sources against is not a new one.<ref>{{cite journal\|first=Edward P.\|last=Hyde\|year=1911\|quote=This existence of a color match is a consequence of there being approximately the same energy distribution in the visible spectra.\|publisher=The American Physical Society\|journal=Physical Review (Series I)\|volume=32\|pages=632–633\|doi=10.1103/PhysRevSeriesI.32.632\|title=A New Determination of the Selective Radiation from Tantalum (abstract)\|issue=6\|month=June}}</ref> In 1923, writing about "grading of illuminants with reference to quality of color…the temperature of the source as an index of the quality of color", Priest essentially described CCT as we understand it today, going so far as to use the term ''apparent color temperature'', and astutely recognized three cases:<ref name=priest>{{cite journal\|first=Irwin G.\|last=Priest\|title=The colorimetry and photometry of daylight ·and incandescent illuminants by the method of rotatory dispersion\|journal=]\|volume=7\|issue=12\|pages=1175–1209\|year=1923\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-7-12-1175\| quote=''The color temperature of a source is the temperature at which a Planckian radiator would emit radiant energy competent to evoke a color of the same quality as that evoked by the radiant energy from the source in question''. The color temperature is not necessarily the same as the 'true temperature' of the source; but this circumstance has no significance whatever in the use of the color temperature as a means to the end of establishing a scale for the quality of the color of illuminants. For this purpose no knowledge of the temperature of the source nor indeed of its emissive properties is required. ''All that is involved in giving the color temperature of any illuminant is the affirmation that the color of the luminant is of the same quality as the color of a Planckian radiator at the given temperature''.}}</ref>
	* "Those for which the spectral distribution of energy is identical with that given by the Planckian formula."
	* "Those for which the spectral distribution of energy is not identical with that given by the Planckian formula, but still is of such a form that the quality of the color evoked is the same as would be evoked by the energy from a Planckian radiator at the given color temperature."
	* "Those for which the spectral distribution of energy is such that the color can be matched ''only approximately'' by a stimulus of the Planckian form of spectral distribution."

			Photographers sometimes use color temperature meters. These are usually designed to read only two regions along the visible spectrum (red and blue); more expensive ones read three regions (red, green, and blue). However, they are ineffective with sources such as fluorescent or discharge lamps, whose light varies in color and may be harder to correct for. Because this light is often greenish, a magenta filter may correct it. More sophisticated ] tools can be used if such meters are lacking.<ref name=":0" />
	Several important developments occurred in 1931. In chronological order:

			===Desktop publishing===
	# ] published a paper on ''correlated color temperature'' (his term). Referring to the ] on the r-g diagram, he defined the CCT as the average of the ''primary component temperatures'' (RGB CCTs), using ].<ref name=davis>{{cite journal\|first=Raymond\|last=Davis\|authorlink=Raymond Davis, Jr.\|title=A Correlated Color Temperature for Illuminants\|journal=National Bureau of Standards Journal of Research\|volume=7\|comment=Research Paper 365\|pages=659–681\|year=1931\|quote=The ideal correlated colour temperature of a light source is the absolute temperature at which the Planckian radiator emits radiant energy component to evoke a colour which, of all Planckian colours, most closely approximates the colour evoked by the source in question.}}</ref>
			{{unreferenced section\|date=June 2012}}
	# The CIE announced the ].
			In the desktop publishing industry, it is important to know a monitor's color temperature. Color matching software, such as Apple's ] for MacOS, measures a monitor's color temperature and then adjusts its settings accordingly. This enables on-screen color to more closely match printed color. Common monitor color temperatures, along with matching ]s in parentheses, are as follows:
	# Judd published a paper on the nature of "]" with respect to chromatic stimuli. By empirical means he determined that the difference in sensation, which he termed ] for a "discriminatory step between colors…Empfindung" (German for sensation) was proportional to the distance of the colors on the chromaticity diagram. Referring to the (r,g) chromaticity diagram depicted aside, he hypothesized that:<ref name=judd>{{cite journal\|title=Chromaticity sensibility to stimulus differences\|journal=]\|first=Deane B.\|last=Judd\|pages=72–108\|volume=22\|year=1931\|issue=2\| url=http://www.opticsinfobase.org/abstract.cfm?id=48631}}</ref>

			*5000 K (CIE D50)
	::<math>K\Delta E=\| c_1 - c_2 \|=\max(\|r_1-r_2\|,\|g_1-g_2\|)</math>
			*5500 K (CIE D55)
			*6500 K (])
			*7500 K (CIE D75)
			*9300 K

			D50 is scientific shorthand for a ]: the daylight spectrum at a correlated color temperature of 5000 K. Similar definitions exist for D55, D65 and D75. Designations such as ''D50'' are used to help classify color temperatures of ]s and viewing booths. When viewing a ] at a light table, it is important that the light be balanced properly so that the colors are not shifted towards the red or blue.
	These developments paved the way for the development of new chromaticity spaces that are more suited to the estimation of correlated color temperatures and chromaticity differences. Bridging the concepts of color difference and color temperature, Priest made the observation that the eye is sensitive to constant differences in ''reciprocal'' temperature:<ref>{{cite journal\|title=A proposed scale for use in specifying the chromaticity of incandescent illuminants and various phases of daylight\|first=Irwin G.\|last=Priest\|month=February\|year=1933\|journal=]\|volume=23\|issue=2\|url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-23-2-41\|pages=42}}</ref>

			]s, web graphics, ]s, etc., are normally designed for a 6500 K color temperature. The ] commonly used for images on the Internet stipulates a 6500 K display ].
	{{quote\|A difference of one ] (<math>\mu rd</math>) is fairly representative of the doubtfully perceptible difference under the most favorable conditions of observation.}}

			] prior to ] are use ] as default display color space, and use 6500 K as default display color temperature; this can be override by the GPU driver; ]s found on many new laptops can also adjust the display color temperature automatically. ] have supports for Auto Color Management (ACM) which further optimized for ] monitors by reading ] data.<ref> {{Cite web \|title=Auto color management in Windows 11 - Microsoft Support \|url=https://support.microsoft.com/en-us/windows/auto-color-management-in-windows-11-64a4de7f-9c93-43ec-bdf1-3b12ffa0870b \|access-date=2024-09-04 \|website=support.microsoft.com}}</ref>
	Priest proposed to use "the scale of temperature as a scale for arranging the chromaticities of the several illuminants in a serial order."

			===TV, video, and digital still cameras===
	Over the next few years, Judd published three more significant papers:
			{{unreferenced section\|date=June 2012}}
			The ] and ] TV norms call for a compliant TV screen to display an electrically black and white signal (minimal color saturation) at a color temperature of 6500 K. On many consumer-grade televisions, there is a very noticeable deviation from this requirement. However, higher-end consumer-grade televisions can have their color temperatures adjusted to 6500 K by using a preprogrammed setting or a custom calibration. Current versions of ] explicitly call for the color temperature data to be included in the data stream, but old versions of ATSC allowed this data to be omitted. In this case, current versions of ATSC cite default colorimetry standards depending on the format. Both of the cited standards specify a 6500 K color temperature.

			Most video and digital still cameras can adjust for color temperature by zooming into a white or neutral colored object and setting the manual "white balance" (telling the camera that "this object is white"); the camera then shows true white as white and adjusts all the other colors accordingly. White-balancing is necessary especially when indoors under fluorescent lighting and when moving the camera from one lighting situation to another. Most cameras also have an automatic white balance function that attempts to determine the color of the light and correct accordingly. While these settings were once unreliable, they are much improved in today's digital cameras and produce an accurate white balance in a wide variety of lighting situations.
	# The first verified the findings of Priest,<ref name=priest/> Davis,<ref name=davis/> and Judd,<ref name=judd/> with a paper on sensitivity to change in color temperature.<ref>{{cite journal\|first=Deane B.\|last=Judd\|month=January\|year=1933\|journal=]\|volume=23\|issue=1\| title=Sensibility to Color-Temperature Change as a Function of Temperature\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-23-1-7\| quote=Regarding (Davis, 1931): This simpler statement of the spectral-centroid relation might have been deduced by combining two previous findings, one by Gibson (see footnote 10, p. 12) concerning a spectral-centroid relation between incident and transmitted light for daylight filters, the other by Langmuir and Orange (Trans. A.I.E.E., 32, 1944–1946 (1913)) concerning a similar relation involving reciprocal temperature. The mathematical analysis on which this latter finding is based was given later by Foote, Mohler and Fairchild, J. Wash. Acad. Sci. 7, 545–549 (1917), and Gage, Trans. I.E.S. 16, 428–429 (1921) also called attention to this relation.}}</ref>
	# The second proposed a new chromaticity space, guided by a principle that has become the holy grail of color spaces: ] (chromaticity distance should be commensurate with perceptual difference). By means of a ], Judd found a more ''uniform chromaticity space'' (UCS) in which to find the CCT. Judd determined the ''nearest color temperature'' by simply finding the nearest point on the ] to the chromaticity of the stimulus on ]'s ], depicted aside. The ] he used to convert X,Y,Z tristimulus values to R,G,B coordinates was:<ref>{{cite journal\|title=A Maxwell Triangle Yielding Uniform Chromaticity Scales\|journal=]\|first=Deane B.\|last=Judd\|volume=25\|issue=1\|year=1935\|month=January\|pages=24–35\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-25-1-24\| quote=An important application of this coordinate system is its use in finding from any series of colors the one most resembling a neighboring color of the same brilliance, for example, the finding of the nearest color temperature for a neighboring non-Planckian stimulus. The method is to draw the shortest line from the point representing the non-Planckian stimulus to the Planckian locus.}}</ref><br><math>\begin{bmatrix} R \\ G \\ B \end{bmatrix} = \begin{bmatrix} 3.1956 & 2.4478 & -0.1434 \\ -2.5455 & 7.0492 & 0.9963 \\ 0.0000 & 0.0000 & 1.0000 \end{bmatrix} \begin{bmatrix} X \\ Y \\ Z \end{bmatrix}</math>.<br>From this one can find these chromaticities:<ref>{{cite journal\|journal=]\|title=Quantitative data and methods for colorimetry\|volume=34\|issue=11\|month=November\|year=1944\|author=OSA Committee on Colorimetry\| pages=633–688\|url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-34-11-633}} (recommended reading)</ref><br><math>u=\frac{0.4661x+0.1593y}{y-0.15735x+0.2424} \quad v=\frac{0.6581y}{y-0.15735x+0.2424}</math>
	# The third depicted the locus of the isothermal chromaticities on the CIE 1931 ''x,y'' chromaticity diagram.<ref>{{cite journal\|title=Estimation of Chromaticity Differences and Nearest Color Temperatures on the Standard 1931 I.C.I. Colorimetric Coordinate System\|journal=]\|first=Deane B.\|last=Judd\|volume=26\|issue=11\|pages=421–426\|month=November\|year=1936\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-26-11-421}}</ref> Since the isothermal points formed ] on his UCS diagram, transformation back into the xy plane revealed them still to be lines, but no longer perpendicular to the locus.

			However, in ] and ] standards, 9300 K color temperature is recommended. TVs and projectors sold in Japan, South Korea, China, Hong Kong, Taiwan and Philippines are usually adopt 9300 K as default settings. But for compatibility reasons, ]s sold in these country/region are usually adopt 6500 K as default settings; these color temperature settings are usually tuneable in ] menu.
	]

			===Artistic application via control of color temperature===
	===Calculation===
			{{unreferenced section\|date=June 2012}}
	Judd's idea of determining the nearest point to the Planckian locus on a uniform chromaticity space is current. In 1937, MacAdam suggested a "modified uniform chromaticity scale diagram", based on certain simplifying geometrical considerations:<Ref>{{cite journal\|title=Projective transformations of I.C.I. color specifications\|first=David L.\|last=MacAdam\|journal=]\|year=1937\|month=August\|volume=27\|issue=8\|pages=294–299\|url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-27-8-294}}</ref>
			]

			Video ]s can white-balance objects that are not white, downplaying the color of the object used for white-balancing. For instance, they can bring more warmth into a picture by white-balancing off something that is light blue, such as faded blue denim; in this way white-balancing can replace a filter or lighting gel when those are not available.
	:<math>u = \frac{4x}{-2x+12y+3}</math>

			]s do not "white balance" in the same way as video camera operators; they use techniques such as filters, choice of film stock, ], and, after shooting, ], both by exposure at the labs and also digitally. Cinematographers also work closely with set designers and lighting crews to achieve the desired color effects.<ref>{{Cite book\|last=Brown\|first=Blain\|url=https://books.google.com/books?id=GiQlDwAAQBAJ&q=cinematography+filters+by+color+temperature&pg=PP1\|title=Cinematography: Theory and Practice: Image Making for Cinematographers and Directors\|date=2016-09-15\|publisher=Taylor & Francis\|isbn=978-1-317-35927-2\|language=en}}</ref>
	:<math>v = \frac{6y}{-2x+12y+3}</math>

			For artists, most pigments and papers have a cool or warm cast, as the human eye can detect even a minute amount of saturation. Gray mixed with yellow, orange, or red is a "warm gray". Green, blue, or purple create "cool grays". This sense of temperature is the reverse of that of real temperature; bluer is described as "cooler" even though it corresponds to a higher-temperature ].
	This (u,v) chromaticity space became the ], which is still used to calculate the CCT (even though MacAdam did not devise it with this purpose in mind).<ref></ref> Using other chromaticity spaces, such as u'v', leads to non-standard results that may nevertheless be perceptually meaningful.<ref>{{cite journal
	\|title=Correlated Color-Temperature Calculations in the CIE 1976 Chromaticity Diagram
	\|journal=Color Research & Application
	\|publisher=]
	\|last1=Schanda
	\|last2=Danyi
	\|first1=János
	\|first2=M.
	\|volume=2
	\|issue=4
	\|pages=161—163
	\|year=1977
	\|doi=10.1002/col.5080020403
	\|quote=Correlated color temperature can be calculated using the new diagram, leading to somewhat different results than those calculated according to the CIE 1960 uv diagram.
	}}</ref>

			{\| style="border:1px solid #aaaaaa; background-color:white; padding:5px; font-size:95%; margin: 0px 12px 12px 0px; float: left; margin-left: 10px"
	]. The isotherms are perpendicular to the Planckian locus, and are drawn to indicate the maximum distance from the locus that the CIE considers the correlated color temperature to be meaningful: <math>\Delta uv=\pm 0.05</math>]]
			\|- align=center
			\|colspan=2\|]
			\|- align=center
			\|\|'''"Warm" gray'''
			\|\|'''"Cool" gray'''
			\|- align=center
			\|\|Mixed with 6% yellow
			\|\|Mixed with 6% blue
			\|}

			] sometimes select ]s by color temperature, commonly to match light that is theoretically white. Since fixtures using ] type lamps produce a light of a considerably higher color temperature than do ], using the two in conjunction could potentially produce a stark contrast, so sometimes fixtures with ], commonly producing light of 6000–7000 K, are fitted with 3200 K filters to emulate tungsten light. Fixtures with color mixing features or with multiple colors (if including 3200 K), are also capable of producing tungsten-like light. Color temperature may also be a factor when selecting ], since each is likely to have a different color temperature.
	The distance from the locus (i.e., degree of departure from a black body) is traditionally indicated in units of <math>\Delta uv</math>; positive for points above the locus. This concept of distance has evolved to become ], which continues to be used today.
			<div style="clear: both;"></div>

			==Correlated color temperature {{anchor\|Correlated}}==
	====Robertson's method====
			{{excerpt\|Correlated color temperature}}

			==Color rendering index==
	Before the advent of powerful, ]s, it was common to estimate the correlated color temperature by way of interpolation from look-up tables and charts.<ref name=kelly/> The most famous such method is Robertson's,<ref>{{cite journal\|title=Computation of Correlated Color Temperature and Distribution Temperature\|first=Alan R.\|last=Robertson\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-58-11-1528\|journal=]\|volume=58\|issue=11\|pages=1528–1535\|year=1968\|month=November}}</ref> who took advantage of the relatively even spacing of the mired scale (see above) to calculate the CCT T<sub>c</sub> using ] of the isotherm's mired values:<ref>, Bruce Lindbloom</ref>
			{{Main\|Color rendering index}}
			The ] ] (CRI) is a method to determine how well a light source's illumination of eight sample patches compares to the illumination provided by a reference source. Cited together, the CRI and CCT give a numerical estimate of what reference (ideal) light source best approximates a particular artificial light, and what the difference is.

			==Spectral power distribution==
	]
			] (left) and a ] (right). The horizontal axes are wavelengths in ]s, and the vertical axes show relative intensity in arbitrary units.]]

			Light sources and illuminants may be characterized by their ] (SPD). The relative SPD curves provided by many manufacturers may have been produced using 10 ] increments or more on their ].<ref>Gretag's {{webarchive\|url=https://web.archive.org/web/20061110131804/http://www.xrite.com/documents/literature/gmb/en/200_spectrolino_manual_en.pdf \|date=2006-11-10 }} and X-Rite's {{webarchive\|url=https://web.archive.org/web/20090205040118/http://www.pictureline.com/images/pdf/L11-246%20CM%20CompetitCompr_03-17-08.pdf \|archive-url=https://web.archive.org/web/20090205040118/http://www.pictureline.com/images/pdf/L11-246%20CM%20CompetitCompr_03-17-08.pdf \|archive-date=2009-02-05 \|url-status=live \|date=2009-02-05 }} have an optical resolution of 10 nm.</ref> The result is what would seem to be a smoother ("]") power distribution than the lamp actually has. Owing to their spiky distribution, much finer increments are advisable for taking measurements of fluorescent lights, and this requires more expensive equipment.
	<math>\frac{1}{T_c}=\frac{1}{T_i}+\frac{\theta_1}{\theta_1+\theta_2} \left( \frac{1}{T_{i+1}} - \frac{1}{T_i} \right)</math>

			==Color temperature in astronomy==
	where <math>T_i</math> and <math>T_{i+1}</math> are the color temperatures of the look-up isotherms and i is chosen such that <math>T_i < T_c < T_{i+1}</math>. (Furthermore, the test chromaticity lies between the only two adjacent lines for which <math>d_i/d_{i+1}<0</math>.)
			]) compared to black-body spectra. The 15,000 K black-body spectrum (dashed line) matches the visible part of the stellar SPD much better than the black body of 9500 K. All spectra are normalized to intersect at 555 nanometers.]]
			In ], the color temperature is defined by the local slope of the SPD at a given wavelength, or, in practice, a wavelength range. Given, for example, the ]s ''B'' and ''V'' which are calibrated to be equal for an ] (e.g. ]), the stellar color temperature <math>T_C</math> is given by the temperature for which the color index <math>B-V</math> of a black-body radiator fits the stellar one. Besides the <math>B-V</math>, other color indices can be used as well. The color temperature (as well as the correlated color temperature defined above) may differ largely from the effective temperature given by the radiative flux of the stellar surface. For example, the color temperature of an A0V star is about 15000 K compared to an effective temperature of about 9500 K.<ref>{{cite book \| last=Unsöld \| first=Albrecht \|author2=Bodo Baschek \| title = Der neue Kosmos \| edition = 6 \| publisher = Springer \| location = Berlin, Heidelberg, New York \| year = 1999 \| isbn = 3-540-64165-3}}</ref>

			For most applications in astronomy (e.g., to place a star on the ] or to determine the temperature of a model flux fitting an observed spectrum) the ] is the quantity of interest. Various color-effective temperature relations exist in the literature. There relations also have smaller dependencies on other stellar parameters, such as the stellar metallicity and surface gravity<ref>{{cite journal \|last1=Casagrande \|first1=Luca \|title=The GALAH survey: effective temperature calibration from the InfraRed Flux Method in the Gaia system \|journal=MNRAS \|year=2021 \|volume=507 \|issue=2 \|pages=2684–2696 \|doi=10.1093/mnras/stab2304 \|doi-access=free \|arxiv=2011.02517 \|bibcode=2021MNRAS.507.2684C }}</ref>
	If the isotherms are tight enough, one can assume <math>\theta_1/\theta_2 \approx \sin \theta_1/\sin \theta_2</math>, leading to

	<math>\frac{1}{T_c}=\frac{1}{T_i}+\frac{d_i}{d_i-d_{i+1}} \left( \frac{1}{T_{i+1}} - \frac{1}{T_i} \right)</math>

	The distance of the test point to the i'th isotherm is given by

	<math>d_i=\frac{ (v_T-v_i)-m_i (u_T-u_i) }{\sqrt {1+m_i^2}}</math>

	where <math>(u_i,v_i)</math> is the chromaticity coordinate of the i'th isotherm on the Planckian locus and m<sub>i</sub> is the isotherm's ]. Since it is perpendicular to the locus, it follows that <math>m_i=-1/l_i</math> where l<sub>i</sub> is the slope of the locus at <math>(u_i,v_i)</math>.

	===Precautions===
	Although the CCT can be calculated for any chromaticity coordinate, the result is meaningful only if the light sources is nearly white.<ref>{{cite journal\|title=Determination of correlated color temperature based on a color-appearance model\|first=Wolfgang\|last=Walter\|journal=Color Research & Application\|volume=17\|issue=1\|pages=24–30\|month=February\|year=1992\|doi=10.1002/col.5080170107\|quote=The concept of correlated color temperature is only useful for lamps with chromaticity points close to the blackbody…}}</ref> The CIE recommends that "The concept of correlated color temperature should not be used if the chromaticity of the test source differs more than from the Planckian radiator."<ref name=schanda>{{cite book\|title=Colorimetry: Understanding the CIE System\|first=János\|last=Schanda\|publisher=]\|year=2007\|chapter=3: CIE Colorimetry\|page=37–46\|isbn=978-0-470-04904-4\|doi=10.1002/9780470175637.ch3}}</ref>
	Beyond a certain value of <math>\Delta uv</math>, a chromaticity co-ordinate may be equidistant to two points on the locus, causing ambiguity in the CCT.

	===Approximation===
	If a narrow range of color temperatures is considered—those encapsulating daylight being the most practical case—one can approximate the Planckian locus in order to calculate the CCT in terms of chromaticity coordinates. Following Kelly's observation that the isotherms intersect in the purple region near <math>(x=0.325, y=0.154)</math>,<ref name=kelly>{{cite journal\|last=Kelly\|first=Kenneth L.\|year=1963\|month=August\|title=Lines of Constant Correlated Color Temperature Based on MacAdam’s (u,v) Uniform Chromaticity Transformation of the CIE Diagram\|journal=JOSA\|volume=53\|issue=8\|pages=999–1002\| url=http://www.opticsinfobase.org/abstract.cfm?URI=josa-53-8-999}}</ref> McCamy proposed this cubic approximation:<ref>{{cite journal\|title=Correlated color temperature as an explicit function of chromaticity coordinates\|volume=17\|issue=2\|pages=142–144\|journal=Color Research & Application\|first=Calvin S.\|month=April\|year=1992\|last=McCamy\| doi=10.1002/col.5080170211}} plus ]</ref>
	:<math>CCT(x,y)=-449n^3 + 3525n^2 - 6823.3n + 5520.33</math>

	where <math>n=(x-x_e)/(y-y_e)</math> is the inverse slope line and <math>(x_e=0.3320,y_e=0.1858)</math> is the "epicenter"; quite close to the intersection point mentioned by Kelly. The maximum absolute error for color temperatures ranging from 2856 (illuminant A) to 6504 (]) is under 2 K.

	A more recent proposal, using exponential terms, considerably extends the applicable range by adding a second epicenter for high color temperatures:<ref>{{cite journal\|title=Calculating Correlated Color Temperatures Across the Entire Gamut of Daylight and Skylight Chromaticities\|first=Javier\|last=Hernández-Andrés\|coauthors=Lee, Raymond L.; Romero,Javier\|journal=Applied Optics\|volume=38\|issue=27\|pages=5703–5709\|month=September 20\|year=1999\|doi=10.1364/AO.38.005703\| url=http://www.nadn.navy.mil/Users/oceano/raylee/papers/RLee_AO_CCTpaper.pdf}}</ref>

	:<math>CCT(x,y)=A_0+A_1 \exp(-n/t_1)+A_2 \exp(-n/t_2)+A_3 \exp(-n/t_3)</math>

	where n is as before and the other constants are defined below:

	{\| class="wikitable"
	\|-
	!
	! 3–50 kK
	! 50–800 kK
	\|-
	\| x<sub>e</sub>
	\| 0.3366
	\| 0.3356
	\|-
	\| y<sub>e</sub>
	\| 0.1735
	\| 0.1691
	\|-
	\| A<sub>0</sub>
	\| -949.86315
	\| 36284.48953
	\|-
	\| A<sub>1</sub>
	\| 6253.80338
	\| 0.00228
	\|-
	\| t<sub>1</sub>
	\| 0.92159
	\| 0.07861
	\|-
	\| A<sub>2</sub>
	\| 28.70599
	\| 5.4535×10<sup>-36</sup>
	\|-
	\| t<sub>2</sub>
	\| 0.20039
	\| 0.01543
	\|-
	\| A<sub>3</sub>
	\| 0.00004
	\|
	\|-
	\| t<sub>3</sub>
	\| 0.07125
	\|
	\|}

	== Color rendering index ==

	The ] ] (CRI) is a method to determine how well a light source's illumination of eight sample patches compares to the illumination provided by a reference source. Cited together, the CRI and CCT give a numerical estimate of what reference (ideal) light source best approximates a particular artificial light, and what the difference is.

	== Spectral power distribution ==

	]

	Light sources and illuminants may be characterized by their ] (SPD). The relative SPD curves provided by many manufacturers may have been produced using 10-] (nm) increments or more on their ].<ref>Gretag's and X-Rite's have an optical resolution of 10 nm.</ref> The result is what would seem to be a smoother ("]") power distribution than the lamp actually has. Owing to their spiky distribution, much finer increments are advisable for taking measurements of fluorescent lights, and this requires more expensive equipment.

	==See also==		==See also==

	* ]
	* ]
	* ]		* ]
			* ]
	* ]		* ]
			* ]
			* ]
			* ]
			* ]
			* ]
			* ]

	==References==		==References==
	{{~~reflist\|2~~}}		{{Reflist}}

	==Further reading==		==Further reading==
			* {{cite book \| last = Stroebel \| first= Leslie \|author2=John Compton \|author3=Ira Current \|author4= Richard Zakia \| title = Basic Photographic Materials and Processes \| edition = 2nd \| publisher = Focal Press \| location = Boston \| year = 2000 \| isbn = 0-240-80405-8}}

	* {{cite book \| ~~last~~ = ~~Stroebel~~ \| ~~first~~= ~~Leslie~~ \|~~coauthors~~=~~John~~ ~~Compton;~~ ~~Ira~~ ~~Current;~~ ~~Richard~~ ~~Zakia~~ \| title = ~~Basic~~ ~~Photographic~~ ~~Materials~~ and ~~Processes~~ \| ~~edition~~ = 2E \| ~~publisher~~ = ~~Focal~~ ~~Press~~ \| ~~location~~ = ~~Boston~~ \| ~~year~~ = ~~2000~~ \| isbn = 0-~~240~~-~~80405~~-8}}		* {{cite book \| first = Günter\|last=Wyszecki\|author2=Stiles, Walter Stanley \| year = 1982 \| title = Color Science: Concept and Methods, Quantitative Data and Formulæ \| chapter=3.11: Distribution Temperature, Color Temperature, and Correlated Color Temperature\| pages=224–229\|publisher= Wiley \| location = New York \| isbn=0-471-02106-7}}
	* {{cite book \| first = Wyszecki\|last=Günther\|coauthors=Stiles, Walter Stanley \| year = 1982 \| title = Color Science: Concept and Methods, Quantitative Data and Formulæ \| chapter=3.11: Distribution Temperature, Color Temperature, and Correlated Color Temperature\| pages=224-229\|publisher= Wiley \| location = New York \| isbn=0-471-02106-7}}

	==External links==		==External links==
			* from Academo.org
	* Charity, Mitchell. sRGB values corresponding to blackbodies of varying temperature.
			* Boyd, Andrew. at The Discerning Photographer.
			* Charity, Mitchell. sRGB values corresponding to blackbodies of varying temperature.
	* Lindbloom, Bruce. .		* Lindbloom, Bruce. .
			* Konica Minolta Sensing. .

	{{photography subject}}		{{photography subject}}
			{{Artificial light sources}}
			{{Color topics}}
			{{Authority control}}

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Latest revision as of 08:23, 26 November 2024

Property of light sources related to black-body radiation

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The CIE 1931 *x,y* chromaticity space, also showing the chromaticities of black-body light sources of various temperatures (Planckian locus), and lines of constant correlated color temperature

Color temperature is a parameter describing the color of a visible light source by comparing it to the color of light emitted by an idealized opaque, non-reflective body. The temperature of the ideal emitter that matches the color most closely is defined as the color temperature of the original visible light source. The color temperature scale describes only the color of light emitted by a light source, which may actually be at a different (and often much lower) temperature.

Color temperature has applications in lighting, photography, videography, publishing, manufacturing, astrophysics, and other fields. In practice, color temperature is most meaningful for light sources that correspond somewhat closely to the color of some black body, i.e., light in a range going from red to orange to yellow to white to bluish white. Although the concept of correlated color temperature extends the definition to any visible light, the color temperature of a green or a purple light rarely is useful information. Color temperature is conventionally expressed in kelvins, using the symbol K, a unit for absolute temperature.

Color temperatures over 5000 K are called "cool colors" (bluish), while lower color temperatures (2700–3000 K) are called "warm colors" (yellowish). "Warm" in this context is with respect to a traditional categorization of colors, not a reference to black body temperature. The hue-heat hypothesis states that low color temperatures will feel warmer while higher color temperatures will feel cooler. The spectral peak of warm-colored light is closer to infrared, and most natural warm-colored light sources emit significant infrared radiation. The fact that "warm" lighting in this sense actually has a "cooler" color temperature often leads to confusion.

Categorizing different lighting

Color temperatures and example sources
Temperature	Source
1700 K	Match flame, low pressure sodium lamps (LPS/SOX)
1850 K	Candle flame, sunset/sunrise
2400 K	Standard incandescent lamps
2550 K	Soft white incandescent lamps
2700 K	"Soft white" compact fluorescent and LED lamps
3000 K	Warm white compact fluorescent and LED lamps
3200 K	Studio lamps, photofloods, etc.
3350 K	Studio "CP" light
5000 K	Horizon daylight, Tubular fluorescent lamps or cool white/daylight compact fluorescent lamps (CFL)
5500–6000 K	Vertical daylight, electronic flash
6200 K	Xenon short-arc lamp
6500 K	Daylight, overcast
6500–9500 K	LCD or CRT screen
15,000–27,000 K	Clear blue poleward sky

The black-body radiance (B_λ) vs. wavelength (λ) curves for the visible spectrum. The vertical axes of Planck's law plots building this animation were proportionally transformed to keep equal areas between functions and horizontal axis for wavelengths 380–780 nm. K indicates the color temperature in kelvins, and M indicates the color temperature in micro reciprocal degrees.

The color temperature of the electromagnetic radiation emitted from an ideal black body is defined as its surface temperature in kelvins, or alternatively in micro reciprocal degrees (mired). This permits the definition of a standard by which light sources are compared.

To the extent that a hot surface emits thermal radiation but is not an ideal black-body radiator, the color temperature of the light is not the actual temperature of the surface. An incandescent lamp's light is thermal radiation, and the bulb approximates an ideal black-body radiator, so its color temperature is essentially the temperature of the filament. Thus a relatively low temperature emits a dull red and a high temperature emits the almost white of the traditional incandescent light bulb. Metal workers are able to judge the temperature of hot metals by their color, from dark red to orange-white and then white (see red heat).

Many other light sources, such as fluorescent lamps, or light emitting diodes (LEDs) emit light primarily by processes other than thermal radiation. This means that the emitted radiation does not follow the form of a black-body spectrum. These sources are assigned what is known as a correlated color temperature (CCT). CCT is the color temperature of a black-body radiator which to human color perception most closely matches the light from the lamp. Because such an approximation is not required for incandescent light, the CCT for an incandescent light is simply its unadjusted temperature, derived from comparison to a black-body radiator.

The Sun

The Sun closely approximates a black-body radiator. The effective temperature, defined by the total radiative power per square unit, is 5772 K. The color temperature of sunlight above the atmosphere is about 5900 K.

The Sun may appear red, orange, yellow, or white from Earth, depending on its position in the sky. The changing color of the Sun over the course of the day is mainly a result of the scattering of sunlight and is not due to changes in black-body radiation. Rayleigh scattering of sunlight by Earth's atmosphere causes the blue color of the sky, which tends to scatter blue light more than red light.

Some daylight in the early morning and late afternoon (the golden hours) has a lower ("warmer") color temperature due to increased scattering of shorter-wavelength sunlight by atmospheric particulates – an optical phenomenon called the Tyndall effect.

Daylight has a spectrum similar to that of a black body with a correlated color temperature of 6500 K (D65 viewing standard) or 5500 K (daylight-balanced photographic film standard).

For colors based on black-body theory, blue occurs at higher temperatures, whereas red occurs at lower temperatures. This is the opposite of the cultural associations attributed to colors, in which "red" is "hot", and "blue" is "cold".

Applications

Lighting

Color temperature comparison of common electric lamps — Color temperatures of common electric lamps

For lighting building interiors, it is often important to take into account the color temperature of illumination. A warmer (i.e., a lower color temperature) light is often used in public areas to promote relaxation, while a cooler (higher color temperature) light is used to enhance concentration, for example in schools and offices.

CCT dimming for LED technology is regarded as a difficult task, since binning, age and temperature drift effects of LEDs change the actual color value output. Here feedback loop systems are used, for example with color sensors, to actively monitor and control the color output of multiple color mixing LEDs.

Aquaculture

In fishkeeping, color temperature has different functions and foci in the various branches.

In freshwater aquaria, color temperature is generally of concern only for producing a more attractive display. Lights tend to be designed to produce an attractive spectrum, sometimes with secondary attention paid to keeping the plants in the aquaria alive.
In a saltwater/reef aquarium, color temperature is an essential part of tank health. Within about 400 to 3000 nanometers, light of shorter wavelength can penetrate deeper into water than longer wavelengths, providing essential energy sources to the algae hosted in (and sustaining) coral. This is equivalent to an increase of color temperature with water depth in this spectral range. Because coral typically live in shallow water and receive intense, direct tropical sunlight, the focus was once on simulating this situation with 6500 K lights.

Digital photography

In digital photography, the term color temperature sometimes refers to remapping of color values to simulate variations in ambient color temperature. Most digital cameras and raw image software provide presets simulating specific ambient values (e.g., sunny, cloudy, tungsten, etc.) while others allow explicit entry of white balance values in kelvins. These settings vary color values along the blue–yellow axis, while some software includes additional controls (sometimes labeled "tint") adding the magenta–green axis, and are to some extent arbitrary and a matter of artistic interpretation.

Photographic film

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Photographic emulsion film does not respond to lighting color identically to the human retina or visual perception. An object that appears to the observer to be white may turn out to be very blue or orange in a photograph. The color balance may need to be corrected during printing to achieve a neutral color print. The extent of this correction is limited since color film normally has three layers sensitive to different colors and when used under the "wrong" light source, every layer may not respond proportionally, giving odd color casts in the shadows, although the mid-tones may have been correctly white-balanced under the enlarger. Light sources with discontinuous spectra, such as fluorescent tubes, cannot be fully corrected in printing either, since one of the layers may barely have recorded an image at all.

Photographic film is made for specific light sources (most commonly daylight film and tungsten film), and, used properly, will create a neutral color print. Matching the sensitivity of the film to the color temperature of the light source is one way to balance color. If tungsten film is used indoors with incandescent lamps, the yellowish-orange light of the tungsten incandescent lamps will appear as white (3200 K) in the photograph. Color negative film is almost always daylight-balanced, since it is assumed that color can be adjusted in printing (with limitations, see above). Color transparency film, being the final artefact in the process, has to be matched to the light source or filters must be used to correct color.

Filters on a camera lens, or color gels over the light source(s) may be used to correct color balance. When shooting with a bluish light (high color temperature) source such as on an overcast day, in the shade, in window light, or if using tungsten film with white or blue light, a yellowish-orange filter will correct this. For shooting with daylight film (calibrated to 5600 K) under warmer (low color temperature) light sources such as sunsets, candlelight or tungsten lighting, a bluish (e.g. #80A) filter may be used. More-subtle filters are needed to correct for the difference between, say 3200 K and 3400 K tungsten lamps or to correct for the slightly blue cast of some flash tubes, which may be 6000 K.

If there is more than one light source with varied color temperatures, one way to balance the color is to use daylight film and place color-correcting gel filters over each light source.

Photographers sometimes use color temperature meters. These are usually designed to read only two regions along the visible spectrum (red and blue); more expensive ones read three regions (red, green, and blue). However, they are ineffective with sources such as fluorescent or discharge lamps, whose light varies in color and may be harder to correct for. Because this light is often greenish, a magenta filter may correct it. More sophisticated colorimetry tools can be used if such meters are lacking.

Desktop publishing

In the desktop publishing industry, it is important to know a monitor's color temperature. Color matching software, such as Apple's ColorSync Utility for MacOS, measures a monitor's color temperature and then adjusts its settings accordingly. This enables on-screen color to more closely match printed color. Common monitor color temperatures, along with matching standard illuminants in parentheses, are as follows:

5000 K (CIE D50)
5500 K (CIE D55)
6500 K (D65)
7500 K (CIE D75)
9300 K

D50 is scientific shorthand for a standard illuminant: the daylight spectrum at a correlated color temperature of 5000 K. Similar definitions exist for D55, D65 and D75. Designations such as D50 are used to help classify color temperatures of light tables and viewing booths. When viewing a color slide at a light table, it is important that the light be balanced properly so that the colors are not shifted towards the red or blue.

Digital cameras, web graphics, DVDs, etc., are normally designed for a 6500 K color temperature. The sRGB standard commonly used for images on the Internet stipulates a 6500 K display white point.

Microsoft Windows prior to Windows 11 are use sRGB as default display color space, and use 6500 K as default display color temperature; this can be override by the GPU driver; ambient light sensors found on many new laptops can also adjust the display color temperature automatically. Windows 11 22H2 have supports for Auto Color Management (ACM) which further optimized for OLED monitors by reading EDID data.

TV, video, and digital still cameras

The NTSC and PAL TV norms call for a compliant TV screen to display an electrically black and white signal (minimal color saturation) at a color temperature of 6500 K. On many consumer-grade televisions, there is a very noticeable deviation from this requirement. However, higher-end consumer-grade televisions can have their color temperatures adjusted to 6500 K by using a preprogrammed setting or a custom calibration. Current versions of ATSC explicitly call for the color temperature data to be included in the data stream, but old versions of ATSC allowed this data to be omitted. In this case, current versions of ATSC cite default colorimetry standards depending on the format. Both of the cited standards specify a 6500 K color temperature.

Most video and digital still cameras can adjust for color temperature by zooming into a white or neutral colored object and setting the manual "white balance" (telling the camera that "this object is white"); the camera then shows true white as white and adjusts all the other colors accordingly. White-balancing is necessary especially when indoors under fluorescent lighting and when moving the camera from one lighting situation to another. Most cameras also have an automatic white balance function that attempts to determine the color of the light and correct accordingly. While these settings were once unreliable, they are much improved in today's digital cameras and produce an accurate white balance in a wide variety of lighting situations.

However, in NTSC-J and NTSC-C standards, 9300 K color temperature is recommended. TVs and projectors sold in Japan, South Korea, China, Hong Kong, Taiwan and Philippines are usually adopt 9300 K as default settings. But for compatibility reasons, computer monitors sold in these country/region are usually adopt 6500 K as default settings; these color temperature settings are usually tuneable in OSD menu.

Artistic application via control of color temperature

Video camera operators can white-balance objects that are not white, downplaying the color of the object used for white-balancing. For instance, they can bring more warmth into a picture by white-balancing off something that is light blue, such as faded blue denim; in this way white-balancing can replace a filter or lighting gel when those are not available.

Cinematographers do not "white balance" in the same way as video camera operators; they use techniques such as filters, choice of film stock, pre-flashing, and, after shooting, color grading, both by exposure at the labs and also digitally. Cinematographers also work closely with set designers and lighting crews to achieve the desired color effects.

For artists, most pigments and papers have a cool or warm cast, as the human eye can detect even a minute amount of saturation. Gray mixed with yellow, orange, or red is a "warm gray". Green, blue, or purple create "cool grays". This sense of temperature is the reverse of that of real temperature; bluer is described as "cooler" even though it corresponds to a higher-temperature black body.


"Warm" gray	"Cool" gray
Mixed with 6% yellow	Mixed with 6% blue

Lighting designers sometimes select filters by color temperature, commonly to match light that is theoretically white. Since fixtures using discharge type lamps produce a light of a considerably higher color temperature than do tungsten lamps, using the two in conjunction could potentially produce a stark contrast, so sometimes fixtures with HID lamps, commonly producing light of 6000–7000 K, are fitted with 3200 K filters to emulate tungsten light. Fixtures with color mixing features or with multiple colors (if including 3200 K), are also capable of producing tungsten-like light. Color temperature may also be a factor when selecting lamps, since each is likely to have a different color temperature.

Correlated color temperature

This section is an excerpt from Correlated color temperature.

Correlated color temperature (CCT, T_cp) refers to the temperature of a Planckian radiator whose perceived color most closely resembles that of a given stimulus at the same brightness and under specified viewing conditions."

Color rendering index

Main article: Color rendering index

The CIE color rendering index (CRI) is a method to determine how well a light source's illumination of eight sample patches compares to the illumination provided by a reference source. Cited together, the CRI and CCT give a numerical estimate of what reference (ideal) light source best approximates a particular artificial light, and what the difference is.

Spectral power distribution

Light sources and illuminants may be characterized by their spectral power distribution (SPD). The relative SPD curves provided by many manufacturers may have been produced using 10 nm increments or more on their spectroradiometer. The result is what would seem to be a smoother ("fuller spectrum") power distribution than the lamp actually has. Owing to their spiky distribution, much finer increments are advisable for taking measurements of fluorescent lights, and this requires more expensive equipment.

Color temperature in astronomy

In astronomy, the color temperature is defined by the local slope of the SPD at a given wavelength, or, in practice, a wavelength range. Given, for example, the color magnitudes B and V which are calibrated to be equal for an A0V star (e.g. Vega), the stellar color temperature $T_{C}$ is given by the temperature for which the color index $B-V$ of a black-body radiator fits the stellar one. Besides the $B-V$ , other color indices can be used as well. The color temperature (as well as the correlated color temperature defined above) may differ largely from the effective temperature given by the radiative flux of the stellar surface. For example, the color temperature of an A0V star is about 15000 K compared to an effective temperature of about 9500 K.

For most applications in astronomy (e.g., to place a star on the HR diagram or to determine the temperature of a model flux fitting an observed spectrum) the effective temperature is the quantity of interest. Various color-effective temperature relations exist in the literature. There relations also have smaller dependencies on other stellar parameters, such as the stellar metallicity and surface gravity

References

"Colour temperature explained | Adobe". www.adobe.com. Retrieved June 17, 2024.
"What is Color Temperature? How Does it Affect Color Performance of the Monitor?". BenQ. Retrieved June 17, 2024.
"Kelvin Color Temperature Chart | Lighting Color Scale at Lumens". www.lumens.com. February 22, 2022. Retrieved June 17, 2024.
IoP (April 17, 2023). "Colour Temperature and Its Importance in Photography". Institute of Photography. Retrieved June 17, 2024.
Redding, Kevin (February 10, 2023). "Why Color Temperature Is Important in Filmmaking and Editing". Backstage. Retrieved June 17, 2024.
"Correct Color Temperature When Lighting Prints". Gintchin Fine Art. December 23, 2020. Retrieved June 17, 2024.
de Varona, Ray (January 24, 2020). "Ideal Color Temperature for Office and Industrial Spaces". RelightDepot. Retrieved June 17, 2024.
"Colors of Stars | Astronomy". courses.lumenlearning.com. Retrieved June 17, 2024.
See the comments section of this LightNowBlog.com article Archived 2017-03-07 at the Wayback Machine on the recommendations of the American Medical Association to prefer LED-lighting with cooler color temperatures (i.e. warmer color).
"OSRAM SYVLANIA XBO" (PDF). Archived from the original (PDF) on March 3, 2016."
Wallace Roberts Stevens (1951). Principles of Lighting. Constable.
Williams, David R. (2022). "Sun Fact Sheet". NASA. Archived from the original on March 16, 2023. Retrieved March 24, 2023.
"Principles of Remote Sensing". CRISP. Archived from the original on July 2, 2012. Retrieved June 18, 2012.
Chris George (2008). Mastering Digital Flash Photography: The Complete Reference Guide. Sterling. p. 11. ISBN 978-1-60059-209-6.
Rüdiger Paschotta (2008). Encyclopedia of Laser Physics and Technology. Wiley-VCH. p. 219. ISBN 978-3-527-40828-3.
Thomas Nimz, Fredrik Hailer and Kevin Jensen (2012). "Sensors and Feedback Control of Multi-Color LED Systems". LED Professional Review: Trends & Technologie for Future Lighting Solutions. LED Professional: 2–5. ISSN 1993-890X. Archived from the original on April 29, 2014.
Chaplin, Martin. "Water Absorption Spectrum". Archived from the original on July 17, 2012. Retrieved August 1, 2012.
Pope R. M., Fry E. S. (1997). "Absorption spectrum (380–700 nm) of pure water. II. Integrating cavity measurements". Applied Optics. 36 (33). Optical Society of America: 8710–8723. Bibcode:1997ApOpt..36.8710P. doi:10.1364/AO.36.008710. PMID 18264420. S2CID 11061625.
Jerlov N. G. (1976). Marine Optics. Elsevie Oceanography Series. Vol. 14. Amsterdam: Elsevier Scientific Publishing Company. pp. 128–129. ISBN 0-444-41490-8. Archived from the original on December 21, 2017. Retrieved August 1, 2012.
Kern, Chris. "Reality Check: Ambiguity and Ambivalence in Digital Color Photography". Archived from the original on July 22, 2011. Retrieved March 11, 2011.
^ Präkel, David (February 28, 2013). Basics Photography 02: Lighting. Bloomsbury Publishing. ISBN 978-2-940447-55-8.
"Auto color management in Windows 11 - Microsoft Support". support.microsoft.com. Retrieved September 4, 2024.
Brown, Blain (September 15, 2016). Cinematography: Theory and Practice: Image Making for Cinematographers and Directors. Taylor & Francis. ISBN 978-1-317-35927-2.
CIE/IEC 17.4:1987 International Lighting Vocabulary Archived 2010-02-27 at the Wayback Machine (ISBN 3900734070)
Borbély, Ákos; Sámson, Árpád; Schanda, János (December 2001). "The concept of correlated colour temperature revisited". Color Research & Application. 26 (6): 450–457. doi:10.1002/col.1065. Archived from the original on February 5, 2009.
Gretag's SpectroLino Archived 2006-11-10 at the Wayback Machine and X-Rite's ColorMunki Archived 2009-02-05 at the Wayback Machine have an optical resolution of 10 nm.
Unsöld, Albrecht; Bodo Baschek (1999). Der neue Kosmos (6 ed.). Berlin, Heidelberg, New York: Springer. ISBN 3-540-64165-3.
Casagrande, Luca (2021). "The GALAH survey: effective temperature calibration from the InfraRed Flux Method in the Gaia system". MNRAS. 507 (2): 2684–2696. arXiv:2011.02517. Bibcode:2021MNRAS.507.2684C. doi:10.1093/mnras/stab2304.

External links

Kelvin to RGB calculator from Academo.org
Boyd, Andrew. Kelvin temperature in photography at The Discerning Photographer.
Charity, Mitchell. What color is a black body? sRGB values corresponding to blackbodies of varying temperature.
Lindbloom, Bruce. ANSI C implementation of Robertson's method to calculate the correlated color temperature of a color in XYZ.
Konica Minolta Sensing. The Language of Light.

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Terminology	35 mm equivalent focal length Angle of view Aperture Backscatter Black-and-white Chromatic aberration Circle of confusion Clipping Color balance Color temperature Depth of field Depth of focus Exposure Exposure compensation Exposure value Zebra patterning F-number Film format large medium Film speed Focal length Guide number Hyperfocal distance Lens flare Metering mode Perspective distortion Photograph Photographic printing Albumen Photographic processes Reciprocity Red-eye effect Science of photography Shutter speed Sync Zone System
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Category Outline

Lighting

Concepts

Methods of
generation

Incandescent	Regular Edison Halogen Nernst
Luminescent	Cathodoluminescent Electron-stimulated Chemiluminescent Electrochemiluminescence Electroluminescent field-induced polymer Fluorescent Fluorescent lamp (compact) Fluorescent induction Photoluminescent Laser headlamp Radioluminescence Solid-state LED lamp
Combustion	Acetylene/Carbide Argand Campfire Candle Carcel Diya Flare Gas Kerosene Petromax Lantern Fanous Paper Limelight Luchina Magnesium torch Oil Qulliq Rushlight Safety Tilley Torch
Electric arc	Carbon arc Klieg light Yablochkov candle
Gas discharge	Deuterium arc Neon Neon lamp Plasma Sulfur Xenon arc Xenon flash
High-intensity discharge (HID)	Mercury-vapor Metal-halide ceramic Hydrargyrum medium-arc iodide (HMI) Hydrargyrum quartz iodide (HQI) Sodium vapor

Stationary

Portable

Automotive

Display
Decorative

Theatrical
Cinematic

Industrial
Scientific

Latest revision as of 08:23, 26 November 2024

Categorizing different lighting

The Sun

Applications

Lighting

Aquaculture

Digital photography

Photographic film

Desktop publishing

TV, video, and digital still cameras

Artistic application via control of color temperature

Correlated color temperature

Color rendering index

Spectral power distribution

Color temperature in astronomy

See also

References

Further reading

External links