Abstract
The development of instruments for the measurement of solar radiation fluxes is reviewed with emphasis on instruments that can be used as primary or secondary standards for meteorological radiation measurements. The fundamental principles used in radiometric instruments are briefly discussed. It is shown that calorimetric techniques are the best suited for precision measurements because of their fundamental independence of the spectral characteristic of the fluxes to be measured. A simple first-order model of the caloric radiometer is used to demonstrate its different useful modes of operation. The historical evolution is shown by a discussion of the famous classical instruments that in their modern versions still represent or support the International Pyrheliometric Scale. Areas of possible improvement of today’s instruments are indicated and two very recent attempts to construct radiometers of the highest precision are described.
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References
Abbot, C. G., 1911: The silver-disk pryheliometer. Misc. Coll. Smithsonian Inst., 56, No. 19.
Abbot, C. G., and L. B. Aldrich, 1913: Smithsonian pyrheliometry revised. Smithsonian Misc. Coll., 60, No. 18.
Abbot, C. G., and L. B. Aldrich, 1932: An improved waterflow pyrheliometer. Smithsonian Misc. Coll., 87, No. 15.
Abbot, C. G., L. B. Aldrich and W. H. Hoover, 1942: Description of Smithsonian-Angström pyrheliometer. Ann. Astrophys. Obs. Smithsonian Inst., 6, 50–56.
Abbot, C. G., F. E. Fowle and L. B. Aldrich, 1913. Standard pyrheliometer. Ann. Astrophys. Obs. Smithsonian Inst., 3, 52–72.
Angström, A., 1899: Über absolute Bestimmung der Wärmestrahlung mit dem elektrischen Kompensationspyrheliometer nebst einigen Beispielen der Anwendung dieses Instruments. Ann. Phys. Chemie, 67, 633–648.
Angström, A., 1914: Das Angströmsche Kompensations-Pyrheliometer und die pyrheliometrische Skala. Meteor. Z., 31, 369–373.
Angström, A., 1919: Note on comparisons between pyrheliometers and on the difference between the Angström standard and the Smithsonian standard. Mon. Wea. Rev., 47, 798–799.
Crommelijnck, D., 1966: Description of the absolute radiometer under construction at the Royal Meteorological Institute of Belgium. Institut Royal Meteorologique de Belgique, Note Preliminaires No. 7.
De Brichambaut, Ch. Perrin, 1963: Rayonnement Solaire et Echanges Radiatifs Naturels. Paris, Gauthiers-Villars, 300 pp.
Falckenberg, G., 1943: Beiträge zur Absolut-Pyrheliometrie. Meteor. Z., 60, 314–316.
Feussner, K., 1935: Beiträge zur Absolut-Pyrheliometrie. I. Untersuchungen am Potsdamer Absolut Pyrheliometer in seiner ursprüglichen Form. Meteor. Z., 52, 318–326.
Feussner, K., 1936a: Beiträge zur Absolut-Pyrheliometrie. II. Ein neues Rührwasser-Kalorimeter. Meteor. Z., 53, 303–307.
Feussner, K., 1936b: Beiträge zur Absolut-Pyrheliometrie. III. Prüfung der neuen Rührwasser-Kalorimeter und Ergebnisse von Vergleichsmessungen in Davos. Meteor. Z., 53, 361–374.
Feussner, K., 1941: Neuere Arbeiten auf dem Gebiet der Absolut-Pyrheliometrie. Meteor. Z., 58, 68–69.
Feussner, K., 1943a: Beiträge zur Absolut-Pyrheliometrie. IV. Grundsätzliche Aufgaben der Absolut-Pyrheliometrie und pyrheliometrische Arbeiten in Potsdam. Meteor. Z., 60, 73–76.
Feussner, K., 1943b: Beiträge zur Absolut Pyrheliometrie. V. Uber das Silverdisk-Pyrheliometer. Meteor. Z., 60, 82–93.
Foitzik, L., and H. Hinzpeter, 1958: Sonnenstrahlung und Lufttrübung. Germany, Geest & Portig, Akad. Verlagsgesellschaft, 309 pp.
Gillham, E. J., 1962: Recent investigations in absolute radiom- etry. Proc. Royal Soc. London, A269, 249–276.
Guild, J., 1937: Investigations in absolute radiometrie. Proc. Roy. Soc. London, A161, 1–38.
International Council of Scientific Unions (ICSU), 1957: Annals of the International Geophysical Year, Part IV. New York, Pergammon Press, 98 pp.
Kendall, Sr., L. M., 1968: The standard total-radiation absolute radiometer. National Aeronautics and Space Administration, Tech. Rept. 32–1263, 10 pp.
Robinson, N., 1966: Solar Radiation. New York, Elsevier, 347 pp.
Volochine, F. E. 1932: Quelques appareils de Laboratoire actinometrique a Trappes. Proc. Intern. Radiation Commission, Frankfurt.
World Meteorological Organization (WMO), 1961: Guide to meteorological instrument and observing practices, Geneva, TP. 3 Tech. Note, Chap. 9, 32 pp.
World Meteorological Organization (WMO), 1967: Précisions des measures pyrhéliométriques. Geneva, Tech. Note TP 109, 130 pp.
Yanishevskiy, Yu. D., 1957: Actinometric instruments and observations methods. Aklinometricheskiye Pribory i Metody Nablyudeniy, Leningrad, Gidrometeoizdat, 371 pp.
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© 1970 American Meteorological Society
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Marchgraber, R.M. (1970). The Development of Standard Instruments for Radiation Measurements. In: Teweles, S., Giraytys, J. (eds) Meteorological Observations and Instrumentation. Meteorological Monographs, vol 11. American Meteorological Society, Boston, MA. https://doi.org/10.1007/978-1-935704-35-5_40
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DOI: https://doi.org/10.1007/978-1-935704-35-5_40
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