[[File:Goniometr-1900.png|thumb|right|Manual (1), and Mitscherlich's optical (2) goniometers for use in crystallography, c. 1900]] A '''goniophotometer''' is a photometer for measuring the directional light distribution characteristics of light sources, luminaires, optical media, and surfaces.<ref>{{cite encyclopedia |title=goniophotometer |encyclopedia=e-ILV, online version of CIE S 017:2020, International Lighting Vocabulary |edition=2 |url=https://cie.co.at/e-ilv |at=§17-25-026 |location=Vienna |publisher=International Commission on Illumination |year=2020 |access-date=19 Dec 2025}}</ref><ref>{{cite encyclopedia |date=2022 |title=goniophotometer |encyclopedia=ANSI/IES LS-1-22, Lighting Science: Nomenclature And Definitions For Illuminating Engineering |url=https://ies.org/standards/definitions/ |at=§8.4.1.5 |location=New York |publisher=Illuminating Engineering Society |access-date=19 Dec 2025}}</ref> A goniophotometer typically incorporates a goniometer that measures direction using spherical coordinates to capture the angular distribution of the transmitted, emitted, or reflected light.<ref>{{cite web |title=Practical Estimation of Measurement Times in Goniospectroradiometry and Goniophotometry |date=12 Mar 2015 |website=LED-Professional.com |url=https://www.led-professional.com/resources-1/articles/practical-estimation-of-measurement-times-in-goniospectroradiometry-and-goniophotometry |access-date=19 Dec 2025}}</ref> A ''gonioradiometer'' differs only in that it is a radiometer (i.e., is not specific to human vision), rather than a photometer.<ref>{{cite journal |last1=Zhang |first1=John |last2=Levin |first2=Robert |last3=Angelo |first3=Robert |last4=Vincent |first4=Richard |last5=Brickner |first5=Philip |last6=Ngai |first6=Peter |last7=Nardell |first7=Edward A. |title=A Radiometry Protocol for UVGI Fixtures Using a Moving-Mirror Type Gonioradiometer |journal=Journal of Occupational and Environmental Hygiene |volume=9 |issue=3 |pages=140–141 |date=2012 |doi=10.1080/15459624.2011.648569}}</ref>
The directional distribution of light is of high importance to architectural lighting, automotive lighting, and other applications. A goniophotometer enables characterization of emitted light that is not isotropic.
==Uses== [[File:Lambertian-intensity-80-20-v0.png|thumb|right|alt=Polar plot of luminous intensity|Polar plot of the luminous intensity distribution for a luminaire with Lambertian downlight (80%) and uplight (20%)]] A goniophotometer can be used for various applications: * Measurement of luminous flux of a light source * Measurement of luminous intensity distribution from a source much smaller than the size of the goniophotometer
Equipped with color sensors additional characteristics can be measured * Distribution of correlated color temperature * Color uniformity
A goniophotometer can also be used to determine an ''indicatrix of diffusion'' or ''scattering indicatrix'', which is a representation in space, in the form of a surface expressed in polar coordinates, of the angular distribution of (relative) radiant intensity or luminous intensity or of (relative) radiance or luminance of an element of the surface of a medium that diffuses an incident beam of optical radiation by reflection or transmission.<ref name="ILV">{{cite encyclopedia |date=2020 |edition=2 |title=scattering indicatrix |at=§17-24-098 |encyclopedia=e-ILV, online version of CIE S 017:2020, International Lighting Vocabulary |url=https://cie.co.at/e-ilv |location=Vienna |publisher=International Commission on Illumination |access-date=28 Jan 2026}}</ref>
==Types== The goniophotometer types A, B, and C defined here are derived from publication CIE 070-1987 of the International Commission on Illumination.<ref>{{cite web |title=CIE 070-1987, The Measurement of Absolute Luminous Intensity Distributions |date=1987 |publisher=International Commission on Illumination |location=Vienna |url=https://cie.co.at/publications/measurement-absolute-luminous-intensity-distributions |website=cie.co.at |ISBN=9783900734053}}</ref> Use of goniophometers is further detailed in CIE 084-1989 and CIE 121-1996.<ref>{{cite web |title=CIE 084-1989, Measurement of Luminous Flux |date=1989 |publisher=International Commission on Illumination |location=Vienna |url=https://cie.co.at/publications/measurement-luminous-flux |website=cie.co.at |ISBN=9783900734213}}</ref><ref>{{cite web |title=CIE 121-1996, The Photometry & Goniophotometry of Luminaires |date=1996 |publisher=International Commission on Illumination |location=Vienna |url=https://cie.co.at/publications/photometry-goniophotometry-luminaires |website=cie.co.at |ISBN=9783900734749}}</ref> The Illuminating Engineering Society offers similar definitions and guidance in ANSI/IES LM-75-19.<ref>{{cite web |title=ANSI/IES LM-75-19, Approved Method: Guide to Goniometer Measurements and Types, and Photometric Coordinate Systems |date=2019 |publisher=International Commission on Illumination |location=New York |url=https://store.ies.org/product/lm-75-19-approved-method-guide-to-goniometer-measurements-and-types-and-photometric-coordinate-systems/ |website=ies.org}}</ref>
===Type A=== Fixed horizontal axis, with the vertical axis attached, both perpendicular to the main output direction of the light source
===Type B=== Fixed vertical axis, with the horizontal axis attached, both perpendicular to the main output direction of the light source
Type A and B are Double columns structure. This type is applied to fixed the grille lamp. The symmetry axis of lamp and the horizontal of rotating supporter is coaxial, in the B-βcoordinate system, and the two is vertical Cross, in the A-αcoordinate system.
===Type C=== Fixed vertical axis perpendicular to the line of measurement, with a horizontal axis parallel to the main output direction of the light source
Type C are single column structures. The single column structure is created when the assistant column is taken down from double columns structure. This type is applied to a fixed tube lamp, spot lamp, or other devices. The axis radiation of lamp and the horizontal of rotating supporter is coaxial.
=== Camera-based goniophotometers === Luminous intensity distributions can also be measured using imaging goniophotometers.<ref>{{Cite web |title=US Patent for Differential goniophotometer Patent (Patent # 9,958,317 issued May 1, 2018) - Justia Patents Search |url=https://patents.justia.com/patent/9958317 |access-date=2023-05-17 |website=patents.justia.com}}</ref> In order to measure the full angular distribution of a light source, the fisheye camera method can be used. The method is based on employing a fisheye-lens camera installed into a port of an integrating sphere. The camera simultaneously records the luminous intensity data for all angles of light emission, reducing the measurement uncertainty due to temporal effects, such as drift and temporal modulation of the light source. The instantaneous nature of the camera measurement also significantly reduces the time required to obtain the luminous intensity distribution of the device under test, and is not affected by the angular resolution set for the measurement.
==See also== *{{Annotated link|EULUMDAT}} *{{Annotated link|Goniometer}} *{{Annotated link|Goniophotometry}} *{{Annotated link|Integrating sphere}} *{{Annotated link|List of file formats for luminaire radiometric data}}
==References== {{Reflist}}
Category:Photometry Category:Lighting
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