SOLAR SPECTRUM: SOLAR ELEVATION 60 DEGREES
2395 daylight measurements of spectral irradiance, measured from the roof of the University of Granada’s Science Faculty (Granada, Spain, 37°11'N 3°35'W,
elevation 680·m) from February 1996 to February 1998 using a LI-1800 spectroradiometer (LI-COR Bioscience, Lincoln, NE, USA) fitted with a cosine-corrected receptor. Measurements were taken at all solar elevations greater than –4° and in all weather except for rain or snowfall.
From: Johnsen S, Kelber A, Warrant E, Sweeney AM, Widder EA, Lee RL Jr, Hernández-Andrés J. Crepuscular and nocturnal illumination and its effects on color perception by the nocturnal hawkmoth Deilephila elpenor. (2006) Journal of Experimental Biology 209, 789-800
Spectrum 407: SUN Edit
DeleteMeasurement
Brand |
other other |
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Lamp Product |
Sun Direct sunlight |
Lamp ID |
SUN (01/2000) |
Spectrometer | - |
Ballast | - no ballast or default/unknown ballast - |
Reflector | |
Distance | 0 cm |
Age | 0 hours |
Originator (measurement) | Publication |
Colorimetry
Colorimetry is the science to describe physically the human color perception. The wavelength range 380 nm - 780 nm is visible to humans and detected by three different photoreceptors. Many Reptiles see the range 350 nm - 800 nm and have an additional UV photoreceptor in their retina.
WARNING: The measurement range (350 - 800 nm) is not sufficient for this evaluation! Data is only available in the range 355 - 700 nm. Results are shown anyway but should be ignored by anyone except experts.
Whereas a spectrometer measures the intensity in every tiny wavelength interval resulting in thousands of individual intensities, the human eye only measures three intensities detected by the three cones. The same is true for the reptile eye with usually three or four photoreceptors. Effectively the detailled spectrum displayed above reduces to a much compacter bar graph displayed below. The photoreceptor sensitivites from these L-Cone, M-Cone, S-Cone, and U-Cone are used, they are chosen as an average of measured reptile photoreceptor sensitivity curves. The bar graph also shows as reference the intensity seen by the three or four photoreceptors for average sunlight (id 1).
From these three numbers the colour coordinate and the correlated colour temperature for humans are calculated using the CIE standard method. I adapted this concept to a "3 cone reptile (M,S,U)" and a "4 cone reptile (L,M,S,U)". I am sure, that this adaption to other colour spaces makes sense mathematically and this is also done in scientific research regarding colour vision of animals, however I have not seen calculation of colour temperatures for other animals in the scientific literature. Even if it is hypothetical, at least this shows, how arbitrary the colour temperature is, and that the colour temperature calculated for humans does not apply to reptiles. The colour spaces also show the colour coordinates of different phases of daylight ((ids 1, 338 – 451, 511 – 513 ), indicated by crosses, coloured in the appriximate colour perceived by a human.
Human (CIE) | 3 cone reptile | 4 cone reptile | |
---|---|---|---|
Cone Excitation | |||
Colour Coordinate | ( 0.33 ; 0.34 ) | ( 0.41 ; 0.37 ) | ( 0.28 ; 0.3 ; 0.27 ) |
CCT | 5700 Kelvin | 4700 Kelvin | 5100 Kelvin |
distance | 0.03 | 0.03 | |
colour space | 3-D-graph not implemented yet |
Vitamin D3 Analysis
Vitamin D3 is produced by UVB radiation around 300 nm. 7DHC/ProD3 present in the skin is converted to PreD3 when absorbing an UV photon. PreD3 can be converted back to ProD3, to Lumisterol, or to Tachysterol when absorbing another UV photon or can be converted to Vitamin D3 in a warm environment.
This process prevents any overdose of vitamin D3 from UV radiation with a spectrum similar to sunlight. As a comparison the solar spectra at 20°(id:14) and at 85°(id:21) solar angle are shown.
The ratio of the two solarmeters 6.2 (UVB) and 6.5 (UV index) readings has proven a useful and very simply number to acess the spectral shape in the vitamin-d3-active region.
Effective Irradiances
Effective irradiances are calculated for all ranges, actionspectra and radiometers currently present in this database.
The calculation method is a numerical implementation (Simpson's rule) of the formula
To learn more about calculating effective irradiances and radiometers I recommend this excellent report on UVB meters: Characterizing the Performance of Integral Measuring UV-Meters (pdf).
The numbers in the following tables can also be used to estimate certain (effective) irradiances from radiomer readings. Example: If the database lists
- range: UVB (US) = 13.8 µW/cm²
- radiometer: Solarmeter 6.2 = 19.6 µW/cm²
total ( 0 nm - 0 nm) 39900 µW/cm² = 399 W/m² UVC ( 0 nm - 280 nm) 0 µW/cm² = 0 W/m² non-terrestrial ( 0 nm - 290 nm) 0 µW/cm² = 0 W/m² total2 ( 250 nm - 880 nm) 39900 µW/cm² = 399 W/m² UVB (EU) ( 280 nm - 315 nm) 0 µW/cm² = 0 W/m² UVB (US) ( 280 nm - 320 nm) 0 µW/cm² = 0 W/m² UVA+B ( 280 nm - 380 nm) 1450 µW/cm² = 14.5 W/m² Solar UVB ( 290 nm - 315 nm) 0 µW/cm² = 0 W/m² UVA D3 regulating ( 315 nm - 335 nm) 0 µW/cm² = 0 W/m² UVA (EU) ( 315 nm - 380 nm) 1450 µW/cm² = 14.5 W/m² UVA2 (medical definition) ( 320 nm - 340 nm) 0 µW/cm² = 0 W/m² UVA (US) ( 320 nm - 380 nm) 1450 µW/cm² = 14.5 W/m² UVA1 (variant) ( 335 nm - 380 nm) 1450 µW/cm² = 14.5 W/m² UVA1 (medical) ( 340 nm - 400 nm) 2710 µW/cm² = 27.1 W/m² vis. UVA ( 350 nm - 380 nm) 1450 µW/cm² = 14.5 W/m² VIS Rep3 ( 350 nm - 600 nm) 28200 µW/cm² = 282 W/m² VIS Rep4 ( 350 nm - 700 nm) 39900 µW/cm² = 399 W/m² purple ( 380 nm - 420 nm) 3350 µW/cm² = 33.5 W/m² VIS ( 380 nm - 780 nm) 38500 µW/cm² = 385 W/m² VIS2 ( 400 nm - 680 nm) 35100 µW/cm² = 351 W/m² PAR ( 400 nm - 700 nm) 37200 µW/cm² = 372 W/m² tmp ( 400 nm - 1100 nm) 37200 µW/cm² = 372 W/m² blue ( 420 nm - 490 nm) 8930 µW/cm² = 89.3 W/m² green ( 490 nm - 575 nm) 11300 µW/cm² = 113 W/m² yellow ( 575 nm - 585 nm) 1310 µW/cm² = 13.1 W/m² orange ( 585 nm - 650 nm) 8010 µW/cm² = 80.1 W/m² red ( 650 nm - 780 nm) 5510 µW/cm² = 55.1 W/m² IRA ( 700 nm - 1400 nm) 0 µW/cm² = 0 W/m² IR2 ( 720 nm - 1100 nm) 0 µW/cm² = 0 W/m² IRB ( 1400 nm - 3000 nm) 0 µW/cm² = 0 W/m²
Erythema 0.287 UV-Index Pyrimidine dimerization of DNA 0 µW/cm² Photoceratitis 0 µW/cm² Photoconjunctivitis 0 µW/cm² DNA Damage 0.00106 Vitamin D3 0 µW/cm² Photosynthesis 25400 µW/cm² Luminosity 100000 lx Human L-Cone 15000 µW/cm² Human M-Cone 12500 µW/cm² Human S-Cone 7300 µW/cm² CIE X 13400 µW/cm² CIE Y 13900 µW/cm² CIE Z 13600 µW/cm² PAR 171000000 mol photons Extinction preD3 0 e-3*m²/mol Extinction Tachysterol 0 e-3*m²/mol Exctincition PreD3 0 m²/mol Extinction Lumisterol 0 m²/mol Exctincition Tachysterol 0 m²/mol Extinction 7DHC 0 m²/mol L-Cone 12800 µW/cm² M-Cone 13400 µW/cm² S-Cone 12000 µW/cm² U-Cone 7010 µW/cm² UVR - ICNIRP 2004 0.191 Rel Biol Eff Melatonin Supression 11200 µW/cm² Blue Light Hazard 8380 µW/cm² (83.6 µW/cm² per 1000 lx) CIE 174:2006 PreVit D3 0 µW/cm² Lumen Reptil 105000 "pseudo-lx" Vitamin D3 Degradation 0 µW/cm² Actinic UV 0.191 µW/cm² (0.0191 mW/klm) Exctincition Lumisterol 0 m²/mol Exctincition 7DHC 0 m²/mol Exctincition Toxisterols 0 m²/mol
Solarmeter 6.2 (UVB, pre 2010) 8.87 µW/cm² Solarmeter 6.5 (UV-Index, pre 2010) 0.126 Leybold UVB 0 µW/cm² Leybold UVA 1050 µW/cm² Leybold UVC 0 µW/cm² DeltaOhm UVB 0 µW/cm² DeltaOhm UVC 0 µW/cm² Vernier UVB 0 µW/cm² Vernier UVA 519 µW/cm² Gröbel UVA 1120 µW/cm² Gröbel UVB -0.129 µW/cm² Gröbel UVC 0 µW/cm² Luxmeter 101000 lx Solarmeter 6.4 (D3) 0.394 IU/min UVX-31 30.9 µW/cm² IL UVB 0.0043 µW/cm² IL UVA 1410 µW/cm² Solarmeter 6.5 (UVI, post 2010) 0.0403 UV-Index Solarmeter 6.2 (UVB, post 2010) 0.369 µW/cm² (Solarmeter Ratio = 9.14) Solarmeter AlGaN 6.5 UVI sensor 0.359 UV Index GenUV 7.1 UV-Index 0.393 UV-Index Solarmeter 10.0 (Global Power) (manuf.) 401 W/m² Solarmeter 4.0 (UVA) 28 mW/cm² LS122 (manuf.) 0 W/m² ISM400 (first guess) 276 W/m² LS122 (assumption) 14 W/m² ISM400_new 223 W/m² Solarmeter 10.0 (Global Power) (assumption) 383 W/m²