Lux
The lux (symbol: lx) is the International System of Units (SI) derived unit of illuminance, defined as the amount of luminous flux incident on one square meter of surface area, equivalent to one lumen per square meter.[1] It quantifies the intensity of visible light as perceived by the human eye, distinguishing it from radiometric units like watts per square meter that measure total electromagnetic energy without visual weighting.[2] Adopted in 1948 by the 9th General Conference on Weights and Measures (CGPM) as part of the metric system's photometric framework, the lux built on earlier standards like the lumen for luminous flux and the candela for luminous intensity, with full integration into the SI system occurring in 1960.[3] Photometry, the field encompassing lux measurements, originated in the 18th and 19th centuries with efforts to standardize light sources such as candles and lamps for industrial and scientific applications, evolving through international agreements to account for the eye's spectral sensitivity curve peaking at green wavelengths around 555 nanometers.[4] The unit remains essential in modern lighting engineering, where it guides specifications for energy efficiency, safety, and visual comfort under standards from organizations like the Illuminating Engineering Society (IES) and the International Commission on Illumination (CIE).[5] In practical applications, lux levels vary widely by environment to support human tasks and well-being; for instance, full daylight can reach 100,000 lx, while moonlight is about 0.2 lx, and recommended indoor values include 300–500 lx for general offices and 500–1,000 lx for detailed work like reading or inspection.[6] For roadways, the U.S. Federal Highway Administration (FHWA) and Texas Department of Transportation (TxDOT) endorse average illuminance targets such as 5–10 lx for local streets and 10–20 lx for high-speed highways, ensuring uniformity ratios of 4:1 to 6:1 to minimize glare and shadows.[7] These standards promote sustainable design, as excessive lux can waste energy, while insufficient levels impair visibility and productivity.[8]Fundamentals of Illuminance
Definition of Illuminance
Illuminance is a photometric quantity that quantifies the total luminous flux incident on a surface per unit area, representing the amount of visible light illuminating that surface as perceived by the human eye.[9] This measure, expressed in lux (lumens per square meter), emphasizes the density of light reaching the surface rather than the light source's emission.[10] Unlike radiometric quantities, illuminance specifically accounts for human visual perception by weighting the light's spectral distribution according to the eye's sensitivity.[11] The calculation of illuminance incorporates the luminous efficiency function, denoted as V(λ), which describes the human eye's relative sensitivity to different wavelengths of light. For bright conditions, the photopic curve V(λ), standardized by the International Commission on Illumination (CIE) in 1924, peaks at around 555 nm in the green-yellow region and declines sharply toward the ultraviolet and infrared ends of the spectrum.[12] In low-light environments, the scotopic curve V'(λ), adopted by the CIE in 1951, shifts the peak sensitivity to about 507 nm in the blue-green region, reflecting the rod cells' dominance over cone cells in the retina.[13] These functions ensure that illuminance values prioritize wavelengths between approximately 380 nm and 780 nm, the visible spectrum, while ignoring non-visible radiation.[14] Photometry, the field encompassing illuminance, emerged in the early 20th century as a perceptual counterpart to radiometry, which measures all electromagnetic radiation without regard to human vision.[15] The distinction arose from efforts to standardize light measurements for practical applications like lighting design, with photometry formalized through CIE standards focusing exclusively on the visible range to align with biological vision.[16] To illustrate scale, typical illuminance levels include about 0.1 lux under a full moon, providing minimal visibility for navigation, and 300–500 lux in standard office lighting, sufficient for reading and desk work.[6][17]The Lux Unit
The lux (symbol: lx) is the SI derived unit of illuminance, formally defined as the illuminance produced by a luminous flux of one lumen uniformly distributed over a surface of one square metre. This definition derives from the base SI unit of luminous intensity, the candela (cd), and the metre (m), with one lumen equivalent to one candela-steradian (cd·sr). The dimensional formula for the lux is [lx] = cd · sr / m², where the steradian (sr) is the SI unit of solid angle, defined as the solid angle subtended at the centre of a sphere by a portion of its surface with area equal to the square of the radius. This expression reflects the photometric nature of illuminance, linking luminous intensity through solid angle to area. The lux was adopted as part of the International System of Units (SI) by the 11th General Conference on Weights and Measures (CGPM) in 1960 via Resolution 12, which established the framework for SI derived units in photometry.[18] Its definition was confirmed in 1979 through the 16th CGPM's Resolution 3, which redefined the candela and thereby stabilized derived units like the lux.[19] It is equivalent to the older unit meter-candle, where 1 meter-candle = 1 lx.[20] For precise measurement of illuminance in lux, detectors such as photodiodes or photometers are calibrated to the CIE 1931 spectral luminous efficiency function V(λ), which weights the incident spectral power distribution according to the human eye's photopic sensitivity peaking at 555 nm.[21] This calibration ensures traceability to the SI and accounts for the eye's non-uniform response across wavelengths.Relationships to Other Photometric Quantities
Connection to Irradiance
Irradiance represents the total power of electromagnetic radiation incident on a surface per unit area, quantified in watts per square meter (W/m²), and remains independent of human visual perception as it encompasses all wavelengths. In photometry, illuminance serves as the analogous quantity but incorporates the eye's spectral sensitivity, effectively weighting the radiant power according to visibility to the human observer. The precise mathematical connection between illuminance E_v (in lux) and spectral irradiance E_e(\lambda) (in W/m² per unit wavelength) is expressed through spectral integration: E_v = K_m \int_{0}^{\infty} E_e(\lambda) V(\lambda) \, d\lambda where V(\lambda) denotes the photopic luminous efficiency function, which peaks at approximately 555 nm and describes the relative sensitivity of the human eye to different wavelengths, and K_m is the maximum luminous efficacy of radiation, fixed at 683 lm/W.[23] This formulation transforms the radiometric measure into a photometric one by emphasizing visible light while diminishing contributions from ultraviolet and infrared regions.[23] The constant K_m = 683 lm/W originates from the International System of Units (SI) definition of the candela, the base unit for luminous intensity. Specifically, the candela is defined such that a source emitting monochromatic radiation at a frequency of exactly 540 × 10¹² hertz (corresponding to a wavelength of about 555 nm in air) with a radiant intensity of 1/683 watt per steradian produces a luminous intensity of one candela; this establishes the exact luminous efficacy for that monochromatic green light as 683 lm/W, serving as the scaling factor for broadband spectra. As an illustrative conversion, solar irradiance of 1000 W/m² under clear sky conditions with a standard spectral distribution—approximating the CIE reference solar spectrum—yields an illuminance of approximately 110,000 lux, reflecting the luminous efficacy of sunlight around 110 lm/W due to its balanced visible content.[24]Role in Luminous Efficacy
Luminous efficacy of radiation (LER) quantifies the efficiency with which a given spectral power distribution produces visible light as perceived by the human eye, expressed in lumens per watt (lm/W) of radiant power. It serves as a key metric linking illuminance—measured in lux (lm/m²)—to the input radiant power, enabling assessments of how effectively light sources convert energy into useful illumination over a surface. By weighting the spectral radiant flux with the photopic luminosity function, LER accounts for the eye's sensitivity, peaking at 555 nm.[25] The LER for a source with spectral power distribution \Phi_e(\lambda) is given by: \eta = 683 \frac{\int \Phi_e(\lambda) V(\lambda) \, d\lambda}{\int \Phi_e(\lambda) \, d\lambda} \, \text{lm/W}, where V(\lambda) is the CIE photopic spectral luminous efficiency function, and 683 lm/W is the maximum luminous efficacy for monochromatic radiation at 555 nm. This formulation directly relates the luminous flux contributing to illuminance with the total radiant power, allowing designers to evaluate spectral efficiency without electrical losses. For monochromatic green light at 555 nm, LER reaches its theoretical maximum of 683 lm/W.[25][26] In practice, LER values vary by source type, influencing overall system efficiency in applications where illuminance is critical. For example, incandescent lamps typically achieve around 15 lm/W overall efficacy, limited by their broad-spectrum emission and low electrical-to-optical conversion, while modern white LEDs reach 100–200 lm/W, benefiting from spectra tailored to the luminosity function. These values highlight how higher LER enables greater illuminance per unit power, optimizing energy use in lighting systems. For blackbody radiators, LER peaks at approximately 95 lm/W for a color temperature of 6620 K, where the emission spectrum aligns optimally with visible wavelengths, informing the design of thermal light sources like daylight simulators.[25][27] Illuminance measurements play a pivotal role in efficacy calculations during lighting design, as they provide empirical data on achieved luminous flux density, which can be back-calculated to verify source performance against theoretical LER. By combining field-measured illuminance levels with known source power inputs and surface areas, engineers assess real-world efficacy, identifying inefficiencies from factors like light distribution or spectral mismatches, and refine designs to meet standards with minimal energy consumption. This integration ensures that LER evaluations translate directly to practical illuminance outcomes in environments such as offices or roadways.Practical Applications
In Imaging and Display Technology
In imaging and display technology, lux serves as a key metric for specifying the performance of cameras and sensors under varying light conditions, where illuminance directly influences image quality and exposure settings. Video cameras, particularly those used in security and surveillance, often list minimum illuminance requirements in lux to indicate their low-light capabilities. For instance, standard night vision modes in many cameras operate effectively at around 0.1 lux for color imaging, enabling clear footage in dimly lit environments without infrared assistance. Advanced models equipped with Sony's STARVIS CMOS technology push this boundary further, achieving usable color images at 0.004 lux or lower, thanks to enhanced sensitivity in the visible and near-infrared spectrum.[28][29] The role of lux extends to ISO sensitivity and exposure calculations in photography and videography, where it quantifies scene illuminance to determine optimal camera settings. Exposure value (EV) at ISO 100, also known as light value (LV), relates directly to illuminance E in lux via the [formula E](/page/Formula_E) = 2.5 \times 2^{\text{EV}}, allowing photographers to balance aperture (N), shutter speed (t), and ISO for proper exposure without over- or underexposure in low-lux scenarios. This relationship underpins auto-exposure algorithms in digital cameras, where sensors measure ambient lux to adjust ISO dynamically—higher ISO compensates for lower lux by amplifying signal gain, though at the cost of increased noise. In practice, this enables reliable imaging from bright daylight (thousands of lux) down to twilight levels (around 10 lux), with the formula derived from ISO standards for incident light metering.[30] For displays, lux measurements from ambient light sensors guide brightness adaptation, contrasting with the luminance unit of nits (cd/m²) used for screen output. Smartphones and monitors employ lux sensors to detect environmental illuminance, automatically scaling display brightness—for example, ramping up to 1000–2000 nits in direct sunlight (approximately 100,000 lux) to maintain visibility and contrast against glare, while dimming to 2–50 nits indoors (under 500 lux) for eye comfort and battery efficiency. This adaptation ensures perceptual consistency, as higher ambient lux demands elevated luminance to counteract veiling glare on the screen surface.[31] Modern applications leverage lux sensors for auto-exposure in specialized devices, with CMOS technology enabling detection below 0.01 lux. In AR/VR headsets, such as those using onsemi's AR0234CS global shutter CMOS sensors, integrated lux metering adjusts exposure in real-time for indoor tracking (often 1–100 lux), minimizing motion blur and latency during mixed-reality interactions. Similarly, automotive dash cams incorporate low-light CMOS sensors like Sony's IMX462 STARVIS, which perform at 0.0005 lux for night driving footage, using lux-based auto-exposure to capture license plates and road details in urban twilight (0.01–1 lux) or highway conditions without supplemental lighting. These advancements stem from back-illuminated CMOS architectures that boost quantum efficiency in low illuminance.[32][33]In Environmental and Safety Standards
Illuminance standards for indoor environments specify recommended lux levels to ensure visual performance, comfort, and safety in human-occupied spaces. For offices, the Illuminating Engineering Society (IES) recommends horizontal illuminance targets of 300-500 lux on workplanes for general and private areas, supporting tasks like reading and computer use, while conference rooms may require 300 lux on average. In healthcare facilities, IES RP-29-22 guidelines suggest 1,000 lux for general treatment areas and higher targeted levels up to 3,000 lux for detailed procedures, though surgical suites often employ specialized lighting exceeding 40,000 lux at the operating field. For streets and pedestrian areas, IES RP-8-22 advises average illuminance of 10-20 lux for low-pedestrian residential roads to balance safety and energy use. Safety regulations establish minimum illuminance thresholds to prevent hazards in workplaces and egress paths. The Occupational Safety and Health Administration (OSHA) mandates at least 5 foot-candles (approximately 54 lux) for general construction and industrial areas under 29 CFR 1926.56, with emergency exit routes requiring an average of 1 foot-candle (10.8 lux) and no less than 0.6 foot-candles (6.5 lux) at any point.[34] In the European Union, EN 12464-1:2021 sets minimum illuminance for indoor workplaces, including 200 lux for general industrial tasks and 5-10 lux for emergency exits, aligning with directives like the Workplace Minimum Safety and Health Requirements (89/654/EEC). These standards emphasize uniformity and glare control to maintain safe visibility. Outdoor applications incorporate natural and artificial illuminance variations for functional design. Direct sunlight delivers up to 120,000 lux under clear conditions at 1,000 W/m² solar irradiance, as characterized by CIE standard illuminants, influencing urban shading and glare assessments. In urban planning for public spaces, the CIE Guide to the Lighting of Urban Areas (CIE 136:2000) recommends 20-50 lux for pedestrian zones and squares to enhance security and accessibility without excessive light pollution.[35] Measurement protocols for verifying compliance rely on calibrated instruments adhering to international standards. Lux meters must comply with ISO/CIE 19476:2014, which defines performance indices for illuminance meters, including cosine correction to accurately account for light incidence at oblique angles per Lambert's law, ensuring errors remain below 2% for angles up to 60 degrees. These devices, often featuring spectral matching to the V(λ) response, enable precise field assessments in both indoor and outdoor settings.In Biological and Health Contexts
Illuminance plays a critical role in human visual performance, with thresholds determining the ability to perform basic tasks under varying light conditions. For basic orientation and navigation in low-light environments, such as emergency egress, an illuminance of approximately 1 lux is sufficient to allow recognition of outlines and safe movement, as established in international building safety standards. More demanding visual tasks, like reading printed material, require higher levels; illuminance around 300 lux supports comfortable and accurate reading by providing adequate contrast for detailed discrimination.[6] In the context of circadian rhythms, illuminance influences alertness and hormonal regulation, particularly through exposure to blue-enriched light. Daytime illuminance exceeding 1000 lux promotes sustained alertness and supports circadian entrainment by enhancing physiological arousal and cognitive performance.[36] Blue-enriched light at these intensities effectively suppresses melatonin production, helping to align the sleep-wake cycle with natural day-night patterns and mitigating disruptions from artificial lighting.[37] Health guidelines emphasize minimizing illuminance at night to preserve sleep quality and prevent circadian disruption. Recommendations from lighting and sleep research experts advise keeping indoor ambient illuminance below 1 lux during sleep to avoid melatonin suppression and associated risks like insomnia or metabolic disturbances.[38] Ecologically, illuminance drives key biological responses in plants and animals. For plants, phototropism—the directional growth toward light sources—elicits stem bending in response to light gradients, as seen in high-light-adapted species under full sunlight equivalents. In animals, low-threshold twilight lighting triggers vocalizations in songbirds, synchronizing behaviors with seasonal patterns.[39]Units and Measurement Standards
SI Photometry Framework
The SI photometry framework forms part of the International System of Units (SI), providing a coherent set of units for measuring light quantities as perceived by the human eye, distinct from radiometric units that measure physical radiation.[40] Photometry weights measurements by the spectral luminous efficiency function V(λ), which peaks at 555 nm for photopic vision, ensuring relevance to visual perception.[41] The foundational unit in SI photometry is the candela (cd), the base unit for luminous intensity, defined as the luminous intensity in a given direction of a source emitting monochromatic radiation at frequency 540 × 10¹² Hz with a radiant intensity such that the luminous efficacy of the radiation is exactly 683 lumens per watt.[42] This definition links photometry directly to radiometry through the fixed luminous efficacy constant K_cd = 683 lm/W.[40] Derived from the candela are the lumen (lm) for luminous flux and the lux (lx) for illuminance, positioning the lux as a measure of luminous flux per unit area. The following table summarizes the core SI photometric units, their symbols, associated quantities, and definitions:| Unit | Symbol | Quantity | Definition |
|---|---|---|---|
| Candela | cd | Luminous intensity | Base unit: luminous intensity of a source emitting monochromatic radiation of frequency 540 × 10¹² Hz with luminous efficacy K_cd = 683 lm/W.[42] |
| Lumen | lm | Luminous flux | cd ⋅ sr (where sr is the steradian, the SI unit of solid angle).[40] |
| Lux | lx | Illuminance | lm / m² (luminous flux per square meter). |
Non-SI Units and Conversions
In addition to the SI unit of lux, several non-SI units have historically been used to measure illuminance, particularly in imperial, CGS (centimeter-gram-second), and older metric systems.[44] The foot-candle (fc), derived from the imperial system, represents the illuminance produced by one international candle (a predecessor to the candela) at a distance of one foot on a surface perpendicular to the light rays; it equals one lumen per square foot.[44] This unit originated in the early 20th century and became prominent in North American applications, such as photography and architectural lighting, due to its alignment with imperial measurements.[45] Another non-SI unit is the phot (ph), part of the CGS system, defined as one lumen per square centimeter, making it significantly larger than the lux.[44] The phot was employed in scientific contexts during the mid-20th century for its convenience in smaller-scale measurements but has been deprecated in favor of SI units.[44] For low-level illuminance, such as in astronomical or nocturnal environments, the nox (nx) was used as a decimal metric subunit, equivalent to one millilux, facilitating measurements in the range of faint light.[45] Conversions between these units and the lux are standardized as follows:| Unit | Symbol | Conversion to Lux |
|---|---|---|
| Foot-candle | fc | 1 fc = 10.76391 lx |
| Phot | ph | 1 ph = 10 000 lx |
| Nox | nx | 1 nx = 0.001 lx |