Indian Journal of Pure and Applied Physics

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Radiometric Traceability for Pyranometer Calibration Based on High Flux LEDs and Reference Detector


Affiliations
1 Division of Photometry and Radiometry, National Institute of Standards (NIS), President Sadat St., Al-Haram, Giza, 136, Egypt
 

This article aims to establish a new system for pyranometer calibration traceable to the radiometric chain. Different spectrum high flux LEDs have been used as tunable irradiance sources. The calibration procedure, uncertainty budget, and traceability chain of the solar irradiance measurements are presented. Additionally, the results were evaluated using a reference pyranometer, calibrated traceable to radiometric traceability and World Radiometric Reference (WRR).

The uncertainty values are also estimated to be around 1.19 % (k = 2) for LEDs-based pyranometer-pyranometer calibration (WRR traceability), and about 0.68 % (k = 2) for reference standard radiometer based (Radiometric traceability). The deviation between the reference pyranometer and the pyranometer under test was about 0.8% using LED at 655nm for irradiance of 500 W/m2 .The sensitivity results have been evaluated by reference standard pyranometer traceable to WRR using a xenon lamp as a solar source, with a deviation of about 1 %.


Keywords

Pyranometer, Radiometer, WRR, Radiometric Traceability.
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  • Berroug F, Lakhal E K, Omari M El, Faraji M & Qarnia H El, Energy Build, 43 (2011) 3027.

  • Meza F & Varas E, Agric For Meteorol, 100 (2000) 231.

  • Nugraha M R & Adriansyah A, Int J Electr Comput Eng, 12 (2022) 1385.

  • Balenzategui J L, et al., Meas Sci Technol, 33 (2022) 115009.

  • Sanchez G, Serrano A & M L Cancillo, J Atmos Ocean Technol, 34 (2017) 1155.

  • Cavaco A, Canhoto P & Pereira M C, Renew Energy, 163 (2021) 2208.

  • International Standard USO9060 ‘Solar energy — Specification and classification of instruments for measuring hemispherical solar and direct solar radiation.’” Switzerland, 2018, [Online], ISO 9060:2018(E), “Available: www.iso.org.

  • Oyelami S, Azeez N A, Adedigba S A, Akinola O J & Ajayi R M, Adeleke Univ J Eng Technol, 3 (2020) 61.

  • Mubarak R, Schilke H & Seckmeyer G, Energies, 14 (2021) 10.

  • Azouzoute A, Merrouni A A, Bennouna E G & Gennioui A, Energy Procedia, 157 (2019) 1202.

  • Abal G, Monetta A & Alonso-Suárez R, 2018 IEEE 9th Power Instrum Meas Meet, (2018).

  • D Alarcon, et al., Solar Resources Mapping. (2019).


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  • Radiometric Traceability for Pyranometer Calibration Based on High Flux LEDs and Reference Detector

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Authors

Abdallah M Karmalawi
Division of Photometry and Radiometry, National Institute of Standards (NIS), President Sadat St., Al-Haram, Giza, 136, Egypt

Abstract


This article aims to establish a new system for pyranometer calibration traceable to the radiometric chain. Different spectrum high flux LEDs have been used as tunable irradiance sources. The calibration procedure, uncertainty budget, and traceability chain of the solar irradiance measurements are presented. Additionally, the results were evaluated using a reference pyranometer, calibrated traceable to radiometric traceability and World Radiometric Reference (WRR).

The uncertainty values are also estimated to be around 1.19 % (k = 2) for LEDs-based pyranometer-pyranometer calibration (WRR traceability), and about 0.68 % (k = 2) for reference standard radiometer based (Radiometric traceability). The deviation between the reference pyranometer and the pyranometer under test was about 0.8% using LED at 655nm for irradiance of 500 W/m2 .The sensitivity results have been evaluated by reference standard pyranometer traceable to WRR using a xenon lamp as a solar source, with a deviation of about 1 %.


Keywords


Pyranometer, Radiometer, WRR, Radiometric Traceability.

References