Your search keyword '"Mario Ribnitzky"' showing total 5 results

1. Total ozone column intercomparison of Brewers, Dobsons, and BTS-Solar at Hohenpeißenberg and Davos in 2019/2020

Author

Julian Gröbner, Luca Egli, Wolfgang Steinbrecht, Ulf Köhler, Mario Ribnitzky, and Ralf Zuber

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, TA715-787, Environmental engineering, Total ozone, Seasonality, TA170-171, medicine.disease, Atmospheric sciences, 01 natural sciences, Column (database), Standard deviation, 010309 optics, Earthwork. Foundations, 0103 physical sciences, Calibration, medicine, Environmental science, Retrieval algorithm, 0105 earth and related environmental sciences

Abstract

During the 2019/2020 measurement campaign at Hohenpeißenberg (Germany) and Davos (Switzerland) we compared the well-established Dobson and Brewer spectrometers (single- and double-monochromator Brewer) with newer BTS array-spectroradiometer-based systems in terms of total ozone column (TOC) determination. The aim of this study is to validate the BTS performance in a longer-term TOC analysis over more than 1 year with seasonal and weather influences. Two different BTS setups have been used – a fibre-coupled entrance optic version by PMOD/WRC called Koherent and a diffusor optic version from Gigahertz Optik GmbH called BTS-Solar, which proved to be simpler in terms of calibration. The array-spectrometer-based BTS systems have been calibrated with traceability to NMI, and both versions of TOC retrieval algorithms are based on spectral measurements in the range of 305 to 350 nm instead of single-wavelength or wavelength pair measurements as per Brewer or Dobson. The two BTS-based systems, however, used fundamentally different retrieval algorithms for the TOC assessment, whereby the retrieval of the BTS-Solar turned out to achieve significantly smaller seasonal drifts. The intercomparison showed a difference of the BTS-Solar to Brewers of < 0.1 % with an expanded standard deviation (k=2) of < 1.5 % over the whole measurement campaign. Koherent showed a difference of 1.7 % with an expanded standard deviation (k=2) of 2.7 % mostly caused by a significant seasonal variation. To summarize, the BTS-Solar performed at the level of Brewers in the comparison in Hohenpeißenberg. The BTS-Solar showed very small dependence on the slant path column compared to the double-monochromator Brewer and performed better than the single-monochromator Brewer. Koherent showed a strong seasonal variation in Davos due to the sensitivity of its ozone retrieval algorithm to stratospheric temperature.

Published

2021

2. TOC intercomparison of Brewer, Dobson and BTS Solar at Hohenpeißenberg and Davos 2019/2020

Author

Ulf Köhler, Julian Gröbner, Ralf Zuber, Mario Ribnitzky, Luca Egli, and Wolfgang Steinbrecht

Subjects

Spectroradiometer, Spectrometer, Calibration, Environmental science, Total ozone, Retrieval algorithm, Metrology, Remote sensing

Abstract

In the 2019/2020 measurement campaign at Hohenpeißenberg (Germany) and Davos (Switzerland) we compared the well-established Dobson and Brewer spectrometers (single and double monochromator Brewer) with newer BTS array spectroradiometer based systems in terms of total ozone column (TOC) determination. The aim of this study is to validate the BTS performance in a longer-term TOC analysis over more than one year with seasonal and weather influences. Two different BTS setups have been used. A fibre coupled entrance optic version by PMOD/WRC called Koherent and a diffusor optic which proved to be simpler in terms of calibration from Gigahertz-Optik GmbH called BTS Solar. The array-spectrometer based BTS systems have been traceable calibrated to National Metrology Institutes (NMI) and the used TOC retrieval algorithms are based on spectral measurements in the range of 305 nm and 350 nm instead of single wavelength measurements as for Brewer or Dobson. The two BTS based systems, however, used fundamentally different retrieval algorithms for the TOC assessment, whereby the retrieval of the BTS solar turned out to achieve significantly smaller seasonal drifts. The intercomparison showed a deviation of the BTS Solar to Brewers of < 0.1 % with an expanded standard deviation of < 1.5 % within the whole measurement campaign. Koherent showed a deviation of 1.7 % with an expanded standard deviation of 2.7 % mostly given by a significant seasonal drift. Resulting, the BTS Solar performance is comparable to Brewers at the comparison in Hohenpeißenberg. The slant path slope is in-between double monochromator and single monochromator Brewer. Koherent shows a strong seasonal variation in Davos due to the sensitivity of its ozone retrieval algorithm to stratospheric temperature similar to the Dobson results.

Published

2021

3. COMBINED OUT OF RANGE AND IN BAND STRAY LIGHT CORRECTION FOR ARRAY SPECTRORADIOMETERS

Author

Mario Ribnitzky and Ralf Zuber

Subjects

Physics, Range (particle radiation), Spectroradiometer, Optics, business.industry, Stray light, business

Published

2019

4. Global spectral irradiance array spectroradiometer validation according to WMO

Author

Michael Schrempf, Ralf Zuber, Mario Tobar, Mario Ribnitzky, Dimitrij Kutscher, Angelika Niedzwiedz, Kezia Lange, and Gunther Seckmeyer

Subjects

010504 meteorology & atmospheric sciences, Irradiance, Dewey Decimal Classification::600 | Technik::620 | Ingenieurwissenschaften und Maschinenbau, Radiometers, 01 natural sciences, law.invention, 010309 optics, WMO S-2 UV instrument, Meteorology, law, 0103 physical sciences, University of Hanover, Reference instruments, Instrumentation, Engineering (miscellaneous), Zenith, 0105 earth and related environmental sciences, Monochromator, Remote sensing, blue light hazard, World meteorological organizations, Radiometer, Intercomparisons, Spectrometer, stray light, Spectrometers, Stray light, Atmospheric composition, Applied Mathematics, NDACC intercomparison, Hazards, Solar spectral irradiance, Ultraviolet instruments, Dewey Decimal Classification::600 | Technik, Wavelength, Spectroradiometer, spectroradiometer, Spectro-radiometers, Environmental science, ddc:620, ddc:600, UV index, Blue light

Abstract

Solar spectral irradiance measured by two recently developed array spectroradiometers (called UV-BTS and VIS-BTS) are compared to the results of a scanning double monochromator system which is certified as a travelling reference instrument by the Network for the detection of atmospheric composition change (NDACC) and fulfils the specifications of S-2 UV instruments of the world meteorological organization (WMO). The comparison took place between 15 and 18 May 2017 at the Institute of Meteorology and Climatology of the University of Hanover (IMuK) between 4:00 and 17:00UTC. The UV-BTS array spectroradiometer is equipped with special hardware to significantly reduce internal stray light which has been the limiting factor of many array spectroradiometers in the past. It covers a wavelength range of 200 nm-430 nm. The VIS-BTS covers a wider spectral range from 280 nm up to 1050 nm, and stray light reduction is achieved by mathematical methods. For the evaluation, wavelength integrated quantities and spectral global irradiance are compared. The deviation for UV index measured by the UV-BTS, is within ±1% for solar zenith angles (SZA) below 70° and increased to a maximum of ±3% for SZA between 70° and 85° when synchronisation between measurements was possible. The deviation of global spectral irradiance is smaller ±2.5% in the spectral range from 300 nm to 420 nm (evaluated for SZA < 70°). The VIS-BTS achieved the same deviation for blue light hazard as the UV-BTS for the UV index. The evaluations of global spectral irradiance data of the VIS-BTS show a deviation smaller than ±2% in the spectral range from 365 nm to 900 nm (evaluated for SZA < 70°). Below 365 nm, the deviation rises up to ±7% at 305 nm due to remaining stray light. The agreement within the limited time of the intercomparison is considered to be satisfactory for a number of applications and provides a good basis for further investigations. © 2018 IOP Publishing Ltd.

Published

2018

5. Global spectral irradiance array spectroradiometer validation according to WMO.

Author

Ralf Zuber, Mario Ribnitzky, Mario Tobar, Kezia Lange, Dimitrij Kutscher, Michael Schrempf, Angelika Niedzwiedz, and Gunther Seckmeyer

Subjects

SPECTRAL irradiance, SPECTRORADIOMETER, ATMOSPHERIC composition, ULTRAVIOLET radiation

Abstract

Solar spectral irradiance measured by two recently developed array spectroradiometers (called UV-BTS and VIS-BTS) are compared to the results of a scanning double monochromator system which is certified as a travelling reference instrument by the Network for the detection of atmospheric composition change (NDACC) and fulfils the specifications of S-2 UV instruments of the world meteorological organization (WMO). The comparison took place between 15 and 18 May 2017 at the Institute of Meteorology and Climatology of the University of Hanover (IMuK) between 4:00 and 17:00UTC. The UV-BTS array spectroradiometer is equipped with special hardware to significantly reduce internal stray light which has been the limiting factor of many array spectroradiometers in the past. It covers a wavelength range of 200 nm–430 nm. The VIS-BTS covers a wider spectral range from 280 nm up to 1050 nm, and stray light reduction is achieved by mathematical methods. For the evaluation, wavelength integrated quantities and spectral global irradiance are compared. The deviation for UV index measured by the UV-BTS, is within  ±1% for solar zenith angles (SZA) below 70° and increased to a maximum of  ±3% for SZA between 70° and 85° when synchronisation between measurements was possible. The deviation of global spectral irradiance is smaller  ±2.5% in the spectral range from 300 nm to 420 nm (evaluated for SZA  <  70°). The VIS-BTS achieved the same deviation for blue light hazard as the UV-BTS for the UV index. The evaluations of global spectral irradiance data of the VIS-BTS show a deviation smaller than  ±2% in the spectral range from 365 nm to 900 nm (evaluated for SZA  <  70°). Below 365 nm, the deviation rises up to  ±7% at 305 nm due to remaining stray light. The agreement within the limited time of the intercomparison is considered to be satisfactory for a number of applications and provides a good basis for further investigations. [ABSTRACT FROM AUTHOR]

Published

2018