Photometric system
In astronomy, a photometric system is a set of well-defined passbands (or optical filters), with a known sensitivity to incident radiation. The sensitivity usually depends on the optical system, detectors and filters used. For each photometric system a set of primary standard stars is provided.
A commonly adopted standardized photometric system is the Johnson-Morgan or UBV photometric system (1953). At present, there are more than 200 photometric systems.[citation needed]
Photometric systems are usually characterized according to the widths of their passbands:
- broadband (passbands wider than 30 nm, of which the most widely used is Johnson-Morgan UBV system)
- intermediate band (passbands between 10 and 30 nm wide)
- narrow band (passbands less than 10 nm wide)
Photometric letters
[edit]Each letter designates a section of light of the electromagnetic spectrum; these cover well the consecutive major groups, near-ultraviolet (NUV), visible light (centered on the V band), near-infrared (NIR) and part of mid-infrared (MIR).[a] The letters are not standards, but are recognized by common agreement among astronomers and astrophysicists.
The use of U,B,V,R,I bands dates from the 1950s, being single-letter abbreviations.[b]
With the advent of infrared detectors in the next decade, the J to N bands were labelled following on from near-infrared's closest-to-red band, I.
Later the H band was inserted, then Z in the 1990s and finally Y, without changing earlier definitions. Hence, H is out of alphabetical order from its neighbours, while Z,Y are reversed from the alphabetical – higher-wavelength – sub-series which dominates current photometric bands.
Filter Letter |
Effective Wavelength Midpoint λeff for Standard Filter[2] |
Full width at half maximum[2] [c] (archetypal Bandwidth) (Δλ)[d] |
Variant(s) | Description |
---|---|---|---|---|
Ultraviolet | ||||
U | 365 nm | 66 nm | u, u', u* | "U" stands for ultraviolet. |
Visible | ||||
B | 445 nm | 94 nm | b | "B" stands for blue. |
G[3] | 464 nm | 128 nm | g, g' | "G" stands for green. |
V | 551 nm | 88 nm | v, v' | "V" stands for visual. |
R | 658 nm | 138 nm | r, r', R', Rc, Re, Rj | "R" stands for red. |
Near-Infrared | ||||
I | 806 nm | 149 nm | i, i', Ic, Ie, Ij | "I" stands for infrared. |
z-s' | 893.2 nm | 100 nm | z-s' | |
Z | 900 nm[4] | 152 nm | z, z' | |
Y | 1020 nm | 120 nm | y | |
J | 1220 nm | 213 nm | J', Js | |
H | 1630 nm | 307 nm | ||
K | 2190 nm | 390 nm | K Continuum, K', Ks, Klong, K8, nbK | |
L | 3450 nm | 472 nm | L', nbL' | |
Mid-Infrared | ||||
M | 4750 nm | 460 nm | M', nbM | |
N | 10500 nm | 2500 nm | ||
Q | 21000 nm[5] | 5800 nm[5] | Q' |
Note: colors are only approximate and based on wavelength to sRGB representation (when possible).[6]
Combinations of these letters are frequently used; for example the combination JHK has been used more or less as a synonym of "near-infrared", and appears in the title of many papers.[7]
Filters used
[edit]The filters currently being used by other telescopes or organizations.
Units of measurements:
- Å = Ångström
- nm = nanometre
- μm = micrometre
Name | Filters | Link | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
2.2 m telescope at La Silla, ESO | J = 1.24 μm | H = 1.63 μm | K = 2.19 μm | L' = 3.78 μm | M = 4.66 μm | N1 = 8.36 μm | N2 = 9.67 μm | N3 = 12.89 μm | 2.2 m telescope at La Silla, ESO[8] | |
2MASS/PAIRITEL | J = 1.25 μm | H = 1.65 μm | Ks = 2.15 μm | Two Micron All-Sky Survey, Peters Automated InfraRed Imaging TELescope | ||||||
CFHTLS (Megacam) | u* = 374 nm | g' = 487 nm | r' = 625 nm | i' = 770 nm | z' = 890 nm | Canada-France-Hawaii Telescope | ||||
Chandra X-ray Observatory | LETG = 0.08-0.2 keV | HETG = 0.4-10 keV | Chandra X-ray Observatory | |||||||
CTIO | J = 1.20 μm | H = 1.60 μm | K = 2.20 μm | L = 3.50 μm | Cerro Tololo Inter-American Observatory, a division of NOAO | |||||
Cousins RI photometry | Rc = 647 nm | Ic = 786.5 nm | Cousins RI photometry, 1976[9] | |||||||
the Dark Energy Camera | g = 472.0 nm | r = 641.5 nm | i = 783.5 nm | z = 926.0 nm | Y = 1009.5 nm | Central wavelengths for bands in the Dark Energy Survey[10] | ||||
DENIS | I = 0.79 μm | J = 1.24 μm | K = 2.16 μm | Deep Near Infrared Survey | ||||||
Eggen RI photometry | Re = 635 nm | Ie = 790 nm | Eggen RI photometry, 1965[11] | |||||||
FIS | N60 = 65.00 μm | WIDE-S = 90.00 μm | WIDE-L = 145.00 μm | N160 = 160.00 μm | Far-Infrared Surveyor on board, AKARI space telescope | |||||
Gaia | G = 673 nm | GBP = 532 nm | GRP = 797 nm | GRVS = 860 nm | Gaia (spacecraft)[12] | |||||
GALEX[13] | NUV = 175–280 nm | FUV = 135–175 nm | GALaxy Evolution Explorer | |||||||
GOODS (Hubble ACS) | B = 435 nm | V = 606 nm | i = 775 nm | z = 850 nm | Advanced Camera for Surveys on the Hubble Space Telescope | |||||
HAWC+ | Band 1 = 53 μm | Band 2 = 89 μm | Band 3 = 154 μm | Band 4 = 214 μm | High-resolution Airborne Wideband Camera+ for SOFIA[14] | |||||
HDF | 450 nm | 606 nm | 814 nm | Hubble Deep Field from the Hubble Space Telescope | ||||||
IRTF NSFCAM | J = 1.26 μm | H = 1.62 μm | K' = 2.12 μm | Ks = 2.15 μm | K = 2.21 μm | L = 3.50 μm | L' = 3.78 μm | M' = 4.78 μm | M = 4.85 μm | NASA Infrared Telescope Facility NSFCAM[15] |
ISAAC UTI/VLT[16] | Js = 1.2 μm | H = 1.6 μm | Ks = 2.2 μm | L = 3.78 μm | Brα = 4.07 μm | Infrared Spectrometer And Array Camera at Very Large Telescope | ||||
Johnson system (UBV) | U = 364 nm | B = 442 nm | V = 540 nm | UBV photometric system | ||||||
Vera C. Rubin Observatory (LSST)[17] | u = 320.5–393.5 nm | g = 401.5–551.9 nm | r = 552.0–691.0 nm | i = 691.0–818.0 nm | z = 818.0–923.5 nm | y = 923.8–1084.5 nm | Vera C. Rubin Observatory | |||
OMC | Johnson V-filter = 500-580 nm | Optical Monitor Camera[18] on INTEGRAL | ||||||||
Pan-STARRS | g = 481 nm | r = 617 nm | i = 752 nm | z = 866 nm | y = 962 nm | Panoramic Survey Telescope And Rapid Response System[19] | ||||
ProNaOS/SPM | Band 1 = 180-240 μm | Band 2 = 240-340 μm | Band 3 = 340-540 μm | Band 4 = 540-1200 μm | PROgramme NAtional d'Observations Submillerètrique/Systéme Photométrique Multibande, balloon-borne experiment[20] | |||||
Sloan, SDSS | u' = 354 nm | g' = 475 nm | r' = 622 nm | i' = 763 nm | z' = 905 nm | Sloan Digital Sky Survey | ||||
SPIRIT III | Band B1 = 4.29 μm | Band B2 = 4.35 μm | Band A = 8.28 μm | Band C = 12.13 μm | Band D = 14.65 μm | Band E = 21.34 μm | Infrared camera on Midcourse Space Experiment[21] | |||
Spitzer IRAC | ch1 = 3.6 μm | ch2 = 4.5 μm | ch3 = 5.8 μm | ch4 = 8.0 μm | Infrared Array Camera on Spitzer Space Telescope | |||||
Spitzer MIPS | 24 μm | 70 μm | 160 μm | Multiband Imaging Photometer for Spitzer on Spitzer | ||||||
Stromvil filters | U = 345 nm | P = 374 nm | S = 405 nm | Y = 466 nm | Z = 516 nm | V = 544 nm | S = 656 nm | Stromvil photometry | ||
Strömgren filters | u = 350 nm | v = 411 nm | b = 467 nm | y = 547 nm | β narrow = 485.8 nm | β wide = 485 nm | Strömgren photometric system | |||
UKIDSS (WFCAM) | Z = 882 nm | Y = 1031 nm | J = 1248 nm | H = 1631 nm | K = 2201 nm | UKIRT Infrared Deep Sky Survey | ||||
Vilnius photometric system | U = 345 nm | P = 374 nm | S = 405 nm | Y = 466 nm | Z = 516 nm | V = 544 nm | S = 656 nm | Vilnius photometric system | ||
VISTA IRC | Z = 0.88 μm | Y = 1.02 μm | J = 1.25 μm | H = 1.65 μm | Ks = 2.20 μm | NB1.18 = 1.18 μm | Visible & Infrared Survey Telescope for Astronomy | |||
WISE | W1 = 3.4 μm | W2 = 4.6 μm | W3 = 12 μm | W4 = 22 μm | Wide-field Infrared Survey Explorer | |||||
XMM-Newton OM | UVW2 = 212 nm | UVM2 = 231 nm | UVW1 = 291 nm | U = 344 nm | B = 450 nm | V = 543 nm | XMM-Newton Optical/UV Monitor[22] | |||
XEST Survey | UVW2 = 212 nm | UVM2 = 231 nm | UVW1 = 291 nm | U = 344 nm | B = 450 nm | V = 543 nm | J = 1.25 μm | H = 1.65 μm | Ks = 2.15 μm | Survey includes the point source of 2MASS with XMM-Newton OM[23] |
Note: colors are only approximate and based on wavelength to sRGB representation (when possible).[24]
See also
[edit]References and footnotes
[edit]- ^ Spectral Colors
- ^ a b Binney, J.; Merrifield M. Galactic Astronomy, Princeton University Press, 1998, ch. 2.3.2, pp. 53
- ^ Bessell, Michael S. (September 2005). "Standard Photometric Systems" (PDF). Annual Review of Astronomy and Astrophysics. 43 (1): 293–336. Bibcode:2005ARA&A..43..293B. doi:10.1146/annurev.astro.41.082801.100251. ISSN 0066-4146.
- ^ Gouda, N.; Yano, T.; Kobayashi, Y.; Yamada, Y.; et al. (23 May 2005). "JASMINE: Japan Astrometry Satellite Mission for INfrared Exploration". Proceedings of the International Astronomical Union. 2004 (IAUC196): 455–468. Bibcode:2005tvnv.conf..455G. doi:10.1017/S1743921305001614. S2CID 123261288.
z-band: 0.9 μm
- ^ a b [1] Handbook of Geophysics and the Space Environment 1985, Air Force Geophysics Laboratory, 1985, ed. Adolph S. Jursa, Ch. 25, Table 25-1
- ^ "Light wavelength to RGB Converter". www.johndcook.com. Retrieved 2023-07-28.
- ^ Monson, Andrew J.; Pierce, Michael J. (2011). "Near-Infrared (Jhk) Photometry of 131 Northern Galactic Classical Cepheids". The Astrophysical Journal Supplement Series. 193 (1): 12. Bibcode:2011ApJS..193...12M. doi:10.1088/0067-0049/193/1/12. Example of use of J for "near-infrared"
- ^ A study of the Chamaeleon I dark cloud and T-association. II – High-resolution IRAS maps around HD 97048 and 97300, Assendorp, R.; Wesselius, P. R.; Prusti, T.; Whittet, D. C. B., 1990
- ^ ADPS
- ^ DES
- ^ ADPS
- ^ Jordi, C.; Gebran, M.; Carrasco, J. M.; de Bruijne, J.; Voss, H.; Fabricius, C.; Knude, J.; Vallenari, A.; Kohley, R.; Mora, A. (2010). "Gaia broad band photometry". Astronomy and Astrophysics. 523: A48. arXiv:1008.0815. Bibcode:2010A&A...523A..48J. doi:10.1051/0004-6361/201015441. S2CID 34033669.
- ^ "GALEX Instrument Summary". Goddard Space Flight Center. Retrieved 5 June 2019.
- ^ "HAWC". Archived from the original on 2008-03-13. Retrieved 2008-05-25.
- ^ NSFCAM
- ^ "ISAAC Overview". Paranal Instrumentation. ESO. Retrieved 13 October 2011.
- ^ LSST filter characteristics taken from https://github.com/lsst/throughputs/blob/master/baseline/ (see the filter_X.dat files) with the limits at half the peak transmission.
- ^ About INTEGRAL
- ^ Tonry, J. L.; Stubbs, C. W.; Lykke, K. R.; Doherty, P.; Shivvers, I. S.; Burgett, W. S.; Chambers, K. C.; Hodapp, K. W.; Kaiser, N.; Kudritzki, R.-P.; Magnier, E. A.; Morgan, J. S.; Price, P. A.; Wainscoat, R. J. (2012). "THE Pan-STARRS1 PHOTOMETRIC SYSTEM". The Astrophysical Journal. 750 (2): 99. arXiv:1203.0297. Bibcode:2012ApJ...750...99T. doi:10.1088/0004-637X/750/2/99. S2CID 119266289.
- ^ Pajot, F.; Stepnik, B.; Lamarre, J.-M.; Bernard, J.-P.; Dupac, X.; Giard, M.; Lagache, G.; Leriche, B.; Meny, C.; Recouvreur, G.; Renault, J.-C.; Rioux, C.; Ristorcelli, I.; Serra, G.; Torre, J.-P. (2006). "Calibration of the PRONAOS/SPM submillimeter photometer" (PDF). Astronomy & Astrophysics. 447 (2): 769–781. Bibcode:2006A&A...447..769P. doi:10.1051/0004-6361:20034226. S2CID 4822401.
- ^ MSXPSC – Midcourse Space Experiment (MSX) Point Source Catalog, V2.3
- ^ XMM-Newton User's Handbook Sect. 3.5.3.1
- ^ Audard, M.; Briggs, K. R.; Grosso, N.; Güdel, M.; Scelsi, L.; Bouvier, J.; Telleschi, A. (2007). "The XMM-Newton Optical Monitor survey of the Taurus molecular cloud". Astronomy & Astrophysics. 468 (2): 379–390. arXiv:astro-ph/0611367. Bibcode:2007A&A...468..379A. doi:10.1051/0004-6361:20066320. S2CID 59479808.
- ^ "Light wavelength to RGB Converter". www.johndcook.com. Retrieved 2023-07-28.
- ^ Indigo and cyan are not standard colors.[1] Orange, yellow, and green fall under visual bands, while violet and purple are in every blue band.
- ^ See Description column of the chart
- ^ The width of the band of the curve's 50% upper values (that is, peak) for a natural curve of paradigm source of this light
- ^ Delta lambda
External links
[edit]- Johnson, H. L.; Morgan, W. W. (1953), Fundamental stellar photometry for standards of spectral type on the revised system of the Yerkes spectral atlas, The Astrophysical Journal, vol. 117, pp. 313–352 [2]
- The Asiago Database on Photometric Systems
- Michael S. Bessell (2005), STANDARD PHOTOMETRIC SYSTEMS, Annual Review of Astronomy and Astrophysics vol. 43, pp. 293–336
- Infrared portrait of the nearby massive star-forming region IRAS 09002-4732, Apai, D.; Linz, H.; Henning, Th.; Stecklum, B., 2005