Measurement Geometries - Chapter 7 - Light Measurement Tutorial

Measurement Geometries (Chapter 7)

Solid Angles

One of the key concepts to understanding the relationships between measurement geometries is that of the solid angle, or steradian. A sphere contains 4π steradians. A steradian is defined as the solid angle which, having its vertex at the center of the sphere, cuts off a spherical surface area equal to the square of the radius of the sphere. For example, a one steradian section of a one meter radius sphere subtends a spherical surface area of one square meter.


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The sphere shown in cross section in figure 7.1 illustrates the concept. A cone with a solid angle of one steradian has been removed from the sphere. This removed cone is shown in figure 7.2. The solid angle, Ω, in steradians, is equal to the spherical surface area, A, divided by the square of the radius, r.

Most radiometric measurements do not require an accurate calculation of the spherical surface area to convert between units. Flat area estimates can be substituted for spherical area when the solid angle is less than 0.03 steradians, resulting in an error of less than one percent. This roughly translates to a distance at least 5 times greater than the largest dimension of the detector. In general, if you follow the “five times rule” for approximating a point source (see Chapter 6), you can safely estimate using planar surface area.


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Radiant and Luminous Flux

Radiant flux is a measure of radiometric power. Flux, expressed in watts, is a measure of the rate of energy flow, in joules per second. Since photon energy is inversely proportional to wavelength, ultraviolet photons are more powerful than visible or infrared.

Luminous flux is a measure of the power of visible light. Photopic flux, expressed in lumens, is weighted to match the responsivity of the human eye, which is most sensitive to yellow-green.

Scotopic flux is weighted to the sensitivity of the human eye in the dark adapted state.


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lm / W
lm / W
380 0.000039 0.027 0.000589 1.001
390 .000120 0.082 .002209 3.755
400 .000396 0.270 .009290 15.793
410 .001210 0.826 .034840 59.228
420 .004000 2.732 .096600 164.220
430 .011600 7.923 .199800 339.660
440 .023000 15.709 .328100 557.770
450 .038000 25.954 .455000 773.500
460 .060000 40.980 .567000 963.900
470 .090980 62.139 .676000 1149.200
480 .139020 94.951 .793000 1348.100
490 .208020 142.078 .904000 1536.800
500 .323000 220.609 .982000 1669.400
507 .444310 303.464 1.000000 1700.000
510 .503000 343.549 .997000 1694.900
520 .710000 484.930 .935000 1589.500
530 .862000 588.746 .811000 1378.700
540 .954000 651.582 .650000 1105.000
550 .994950 679.551 .481000 817.700
555 1.000000 683.000 .402000 683.000
560 .995000 679.585 .328800 558.960
570 .952000 650.216 .207600 352.920
580 .870000 594.210 .121200 206.040
590 .757000 517.031 .065500 111.350
600 .631000 430.973 .033150 56.355
610 .503000 343.549 .015930 27.081
620 .381000 260.223 .007370 12.529
630 .265000 180.995 .003335 5.670
640 .175000 119.525 .001497 2.545
650 .107000 73.081 .000677 1.151
660 .061000 41.663 .000313 0.532
670 .032000 21.856 .000148 0.252
680 .017000 11.611 .000072 0.122
690 .008210 5.607 .000035 .060
700 .004102 2.802 .000018 .030
710 .002091 1.428 .000009 .016
720 .001047 0.715 .000005 .008
730 .000520 0.355 .000003 .004
740 .000249 0.170 .000001 .002
750 .000120 0.082 .000001 .001
760 .000060 0.041    
770 .000030 0.020    



Irradiance and Illuminance:


Irradiance is a measure of radiometric flux per unit area, or flux density. Irradiance is typically expressed in W/cm2 (watts per square centimeter) or W/m2 (watts per square meter).

Illuminance is a measure of photometric flux per unit area, or visible flux density. Illuminance is typically expressed in lux (lumens per square meter) or foot-candles (lumens per square foot).


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In figure 7.4, above, the light bulb is producing 1 candela. The candela is the base unit in light measurement, and is defined as follows: a 1 candela light source emits 1 lumen per steradian in all directions (isotropically). A steradian is defined as the solid angle which, having its vertex at the center of the sphere, cuts off an area equal to the square of its radius. The number of steradians in a beam is equal to the projected area divided by the square of the distance.

So, 1 steradian has a projected area of 1 square meter at a distance of 1 meter. Therefore, a 1 candela (1 lm/sr) light source will similarly produce 1 lumen per square foot at a distance of 1 foot, and 1 lumen per square meter at 1 meter. Note that as the beam of light projects farther from the source, it expands, becoming less dense. In fig. 7.4, for example, the light expanded from 1 lm/ft2 at 1 foot to 0.0929 lm/ft2 (1 lux) at 3.28 feet (1 m).


Cosine Law

Irradiance measurements should be made facing the source, if possible. The irradiance will vary with respect to the cosine of the angle between the optical axis and the normal to the detector.


Calculating Source Distance

Lenses will distort the position of a point source. You can solve for the virtual origin of a source by measuring irradiance at two points and solving for the offset distance, X, using the Inverse Square Law:

E1(d1 + X)2 = E2(d2 + X)2

Figure 7.5 illustrates a typical setup to determine the location of an LED’s virtual point source (which is behind the LED due to the built-in lens). Two irradiance measurements at known distances from a reference point are all that is needed to calculate the offset to the virtual point source.


Light Measurement Geometries






Units Conversion: Flux Density


1 W/cm2 (watts per square centimeter)

               = 104 W/m2 (watts per square meter)

               = 6.83 x 106 lux at 555 nm

               = 14.33 gram*calories/cm2/minute



1 lm/m2 (lumens per square meter)

               = 1 lux (lx)

               = 10-4 lm/cm2

               = 10-4 phot (ph)

               = 9.290 x 10-2 lm/ft2

               = 9.290 x 10-2 foot-candles (fc)


Radiance and Luminance:

Radiance is a measure of the flux density per unit solid viewing angle, expressed in W/cm2/sr. Radiance is independent of distance for an extended area source, because the sampled area increases with distance, cancelling inverse square losses.

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The radiance, L, of a diffuse (Lambertian) surface is related to the radiant exitance (flux density), M, of a surface by the relationship:

L = M / π

Some luminance units (asb, L, fL) already contain π in the denominator, allowing simpler conversion to illuminance units.

Example: Suppose a diffuse surface with a reflectivity, ρ, of 85% is exposed to an illuminance, E, of 100.0 lux (lm/ m2) at the plane of the surface. What would be the luminance, L, of that surface, in cd/m2?


1.) Calculate the luminous exitance of the surface: M = E ρ M = 100.0 * 0.85 = 85.0 lm/m2

2.) Calculate the luminance of the surface: L = M / π L = 85.0 / π = 27.1 lm/m2/sr = 27.1 cd/m2


Irradiance From An Extended Source:

The irradiance, E, at any distance from a uniform extended area source, is related to the radiance, L, of the source by the following relationship, which depends only on the subtended central viewing angle, θ, of the radiance detector:

E = π L sin2(θ/2)

So, for an extended source with a radiance of 1 W/cm2/sr, and a detector with a viewing angle of 3°, the irradiance at any distance would be 2.15x 10-3 W/cm2. This assumes, of course, that the source extends beyond the viewing angle of the detector input optics.


Units Conversion: Radiance & Luminance


1 W/cm2/sr (watts per sq. cm per steradian)

     = 6.83 x 106 lm/m2/sr at 555 nm

     = 683 cd/cm2 at 555 nm



1 lm/m2/sr (lumens per sq. meter per steradian)

     = 1 candela/m2 (cd/m2)

     = 1 nit

     = 10-4 lm/cm2/sr

     = 10-4 cd/cm2

     = 10-4 stilb (sb)

     = 9.290 x 10-2 cd/ft2

     = 9.290 x 10-2 lm/ft2/sr

     = π apostilbs (asb)

     = π cd/π/m2

     = π x 10-4 lamberts (L)

     = π x 10-4 cd/π/cm2

     = 2.919 x 10-1 foot-lamberts (fL)

     = 2.919 x 10-1 lm/π/ft2/sr


Radiant and Luminous Intensity:


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Radiant Intensity is a measure of radiometric power per unit solid angle, expressed in watts per steradian. Similarly, luminous intensity is a measure of visible power per solid angle, expressed in candela (lumens per steradian). Intensity is related to irradiance by the inverse square law, shown below in an alternate form:

I = E d2

If you are wondering how the units cancel to get flux/sr from flux/area times distance squared, remember that steradians are a dimensionless quantity. Since the solid angle equals the area divided by the square of the radius, d2=A/Ω, and substitution yields:

I = E * A / Ω

The biggest source of confusion regarding intensity measurements involves the difference between Mean Spherical Candela and Beam Candela, both of which use the candela unit (lumens per steradian). Mean spherical measurements are made in an integrating sphere, and represent the total output in lumens divided by 4π sr in a sphere. Thus, a one candela isotropic lamp produces one lumen per steradian.

Beam candela, on the other hand, samples a very narrow angle and is only representative of the lumens per steradian at the peak intensity of the beam. This measurement is frequently misleading, since the sampling angle need not be defined.


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Suppose that two LED’s each emit 0.1 lm total in a narrow beam: One has a 10° solid angle and the other a 5° angle. The 10° LED has an intensity of 4.2 cd, and the 5° LED an intensity of 16.7 cd. They both output the same total amount of light, however - 0.1 lm.

A flashlight with a million candela beam sounds very bright, but if its beam is only as wide as a laser beam, then it won’t be of much use. Be wary of specifications given in beam candela, because they often misrepresent the total output power of a lamp.


Units Conversion: Intensity


1 W/sr (watts per steradian)

     = 12.566 watts (isotropic)

     = 4*π W

     = 683 candela at 555 nm


1 lm/sr (lumens per steradian)

     = 1 candela (cd)

     = 4*π lumens (isotropic)

     = 1.464 x 10-3 watts/sr at 555 nm


Converting Between Geometries


Converting between geometry-based measurement units is difficult, and should only be attempted when it is impossible to measure in the actual desired units. You must be aware of what each of the measurement geometries implicitly assumes before you can convert. The example below shows the conversion between lux (lumens per square meter) and lumens.


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Chapter 7 - The Light Measurement Handbook

Copyright © 1997 by Alexander D. Ryer

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