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22 results on '"Wandji Nyamsi, William"'

1. On the Relationships between Clear-Sky Indices in Photosynthetically Active Radiation and Broadband Ranges in Overcast and Broken-Cloud Conditions.

Author

Wandji Nyamsi, William, Saint-Drenan, Yves-Marie, Augustine, John A., Arola, Antti, and Wald, Lucien

Subjects
*PHOTOSYNTHETICALLY active radiation (PAR), *SOLAR surface, *CLOUDINESS
Abstract

Several studies proposed relationships linking irradiances in the photosynthetically active radiation (PAR) range and broadband irradiances. A previous study published in 2024 by the same authors proposes a linear model relating clear-sky indices in the PAR and broadband ranges that has been validated in clear and overcast conditions only. The present work extends this study for broken-cloud conditions by using ground-based measurements obtained from the Surface Radiation Budget Network in the U.S.A. mainland. As expected, the clear-sky indices are highly correlated and are linked by affine functions whose parameters depend on the fractional sky cover (FSC), the year, and the site. The previous linear model is also efficient in broken-cloud conditions, with the same level of accuracy as in overcast conditions. When this model is combined with a PAR clear-sky model, the result tends to overestimate the PAR as the FSC decreases, i.e., when fewer and fewer scattered clouds are present. The bias is equal to 1 W m−2 in overcast conditions, up to 18 W m−2 when the FSC is small, and 6 W m−2 when all cloudy conditions are merged. The RMSEs are, respectively, 5, 24, and 15 W m−2. The linear and the clear-sky models can be combined with estimates of the broadband irradiance from satellites to yield estimates of PAR. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Detecting clear‐sky periods from photovoltaic power measurements.

Author

Wandji Nyamsi, William and Lindfors, Anders

Subjects
*SPECTRAL irradiance, *SURFACE of the earth, *INSPECTION & review, *WIND speed
Abstract

A method for detecting clear‐sky periods from photovoltaic (PV) power measurements is presented and validated. It uses five tests dealing with parameters characterizing the connections between the measured PV power and the corresponding clear‐sky power. To estimate clear‐sky PV power, a PV model has been designed using as inputs downwelling shortwave irradiance and its direct and diffuse components received at ground level under clear‐sky conditions as well as reflectivity of the Earth's surface and extraterrestrial irradiance, altogether provided by the McClear service. In addition to McClear products, the PV model requires wind speed and temperature as inputs taken from ECMWF twentieth century reanalysis ERA5 products. The performance of the proposed method has been assessed and validated by visual inspection and compared to two well‐known algorithms identifying clear‐sky periods with broadband global and diffuse irradiance measurements on a horizontal surface. The assessment was carried out at two stations located in Finland offering collocated 1‐min PV power and broadband irradiance measurements. Overall, total agreement ranges between 84% and 97% (depending on the season) in discriminating clear‐sky and cloudy periods with respect to the two well‐known algorithms serving as reference. The disagreement fluctuating between 6% and 15%, depending on the season, primarily occurs while the PV module temperature is adequately high and/or when the sun is close to the horizon with many more interactions between the radiation, the atmosphere and the ground surface. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Evidence of linear relationships between clear‑sky indices in photosynthetically active radiation and broadband ranges

Author

Wandji Nyamsi, William, Saint-Drenan, Yves-Marie, Augustine, John A., Arola, Antti, and Wald, Lucien

Abstract

This study provides empirical relationships between photosynthetically active radiation (PAR) and broadband clear‑sky indices at ground level for both the PAR global irradiance and its direct component. Once multiplied by the irradiance in clear‑sky conditions, the clear‑sky index provides the irradiance under cloudy conditions. The relationships are developed by the means of radiative transfer simulations of various realistic atmospheric states including both ice and water cloud phases. For the direct component, the PAR clear‑sky index is equal to the broadband clear‑sky index. For global irradiance, several linear relationships are proposed depending on the availability of cloud properties namely cloud phase and cloud optical depth. The developed relationships are validated numerically and experimentally by using ground-based measurements from the SURFRAD network in the U.S.A. Overall, it has been found, a squared correlation coefficient  R 2 $R^{2}$ close to 1.00 and a relative bias (relative root mean square error) in absolute value less than 3 % (6 %) with respect to the means of the relevant measurements, demonstrating a high level of accuracy of the proposed relationships.

Published
2024
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13. Assessment of five different methods for the estimation of surface photosynthetically active radiation from satellite imagery at three sites – application to the monitoring of indoor soft fruit crops in southern UK

Author

Thomas, Claire, primary, Dorling, Stephen, additional, Wandji Nyamsi, William, additional, Wald, Lucien, additional, Rubino, Stéphane, additional, Saboret, Laurent, additional, Trolliet, Mélodie, additional, and Wey, Etienne, additional

Published
2019
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16. Technical Note: A novel parameterization of the transmissivity due to ozone absorption in the k-distribution method and correlated-k approximation of Kato et al. (1999) over the UV band

Author

Wandji Nyamsi, William, Arola, Antti, Blanc, Philippe, lindfors, Anders V., Cesnulyte, Vaida, Pitkänen, M. R. A., Wald, Lucien, Centre Observation, Impacts, Énergie (O.I.E.), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Finnish Meteorological Institute (FMI), ADEME 1105C0028, and Faculty of Science and Forestry

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, lcsh:Chemistry, [SPI]Engineering Sciences [physics], lcsh:QD1-999, [SDU.STU.ME]Sciences of the Universe [physics]/Earth Sciences/Meteorology, lcsh:Physics, lcsh:QC1-999
Abstract

Article, The k-distribution method and the correlated-k approximation of Kato et al. (1999) is a computationally efficient approach originally designed for calculations of the broadband solar radiation at ground level by dividing the solar spectrum in 32 specific spectral bands from 240 to 4606 nm. Compared to a spectrally resolved computation, its performance in the UV band appears to be inaccurate, especially in the spectral intervals #3 [283, 307] nm and #4 [307, 328] nm because of inaccuracy in modeling the transmissivity due to ozone absorption. Numerical simulations presented in this paper indicate that a single effective ozone cross section is insufficient to accurately represent the transmissivity over each spectral interval. A novel parameterization of the transmissivity using more quadrature points yields maximum errors of respectively 0.0006 and 0.0143 for intervals #3 and #4. How to practically implement this new parameterization in a radiative transfer model is discussed for the case of libRadtran (library for radiative transfer). The new parameterization considerably improves the accuracy of the retrieval of irradiances in UV bands., published version, http://purl.org/eprint/status/PeerReviewed

Published
2015
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17. Advanced Ultraviolet Radiation and Ozone Retrieval for Applications (AURORA): A Project Overview

Author

Cortesi, Ugo, primary, Ceccherini, Simone, additional, Del Bianco, Samuele, additional, Gai, Marco, additional, Tirelli, Cecilia, additional, Zoppetti, Nicola, additional, Barbara, Flavio, additional, Bonazountas, Marc, additional, Argyridis, Argyros, additional, Bós, André, additional, Loenen, Edo, additional, Arola, Antti, additional, Kujanpää, Jukka, additional, Lipponen, Antti, additional, Wandji Nyamsi, William, additional, van der A, Ronald, additional, van Peet, Jacob, additional, Tuinder, Olaf, additional, Farruggia, Vincenzo, additional, Masini, Andrea, additional, Simeone, Emilio, additional, Dragani, Rossana, additional, Keppens, Arno, additional, Lambert, Jean-Christopher, additional, van Roozendael, Michel, additional, Lerot, Christophe, additional, Yu, Huan, additional, and Verberne, Koen, additional

Published
2018
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20. Towards an automatic method for estimating the spectral distribution of the solar radiation in clear sky conditions. Application cases : UV, photosynthesis, daylight

Author

Wandji Nyamsi, William, Centre Observation, Impacts, Énergie (O.I.E.), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Ecole Nationale Supérieure des Mines de Paris, and Lucien Wald

Subjects
[SPI.OTHER]Engineering Sciences [physics]/Other, Approche k-Corrélés, Spectral, Albédo, Rayonnement solaire, Solar radiation, Spectrale, Correlated-K approach, Atmosphère
Abstract

We are interested in the estimation of the spectral distribution of the solar irradiance on the ground in any place and time. Given the very small number of measurement stations on the ground, we suggest developing a digital method exploiting estimations of the atmospheric composition made daily. This method must be enough fast to be used in intensive mode in an operational way. The targeted fields of application are the ultraviolet (UV), photosynthesis and daylight; with a limitation in the case of the clear sky. Our first innovation is to leave paradoxically from very rapid numerical approaches of calculation of the total irradiance. These developed approaches give a description of the spectral distribution of solar irradiance in a number restricted by discrete bands. The finest and the most recent of these approaches is «k-distribution method and the correlated-k approximation» of Kato and al. (1999). It supplies estimations of the irradiance in 32 spectral bands. To achieve this PhD goal, we have first of all, studied the accuracy of the approach in each of 32 bands. The results are good in all the bands except in the UV. We proposed a novel parametrization of the transmittance of the ozone, which we integrated into the radiative transfer model libRadtran. Finally, we developed two techniques of re-sampling allowing to obtain from 32 discrete values, estimations of the irradiance in any spectral interval, including by taking into account a spectral response of the illuminated system. Experimental validations have been carried out by means of some measurement stations. The preliminary results are considered encouraging in comparison with the precision found on quality measuring instruments. Ways of improvements have been listed for a gain of notable precision.; Nous nous intéressons à l'estimation de la distribution spectrale de l'éclairement solaire au sol en tout lieu et tout instant. Etant donné le très petit nombre de stations de mesure au sol, nous nous proposons de développer une méthode numérique exploitant des estimations de la composition atmosphérique faites quotidiennement. Cette méthode doit être suffisamment rapide pour être utilisée en mode intensif de manière opérationnelle. Les domaines d'applications ciblés sont l'ultraviolet (UV), la photosynthèse et la lumière du jour, avec une limitation au cas du ciel clair. Notre première innovation est de partir paradoxalement des approches numériques très rapides et précises de calcul de l'éclairement total. Ces approches développées donnent une description de la distribution spectrale du rayonnement solaire en un nombre restreint de bandes discrètes. La plus fine et la plus récente de ces approches est la «k distribution method and the correlated k approximation» de Kato et al. (1999). Elle fournit des estimations de l'éclairement dans 32 bandes spectrales. Pour atteindre l'objectif de la thèse, nous avons tout d'abord étudié la précision de cette approche dans chacune des 32 bandes. Les résultats sont bons dans toutes les bandes excepté l'UV. Nous avons proposé une nouvelle paramétrisation de la transmittance de l'ozone, que nous avons intégré au code numérique de transfert radiatif libRadtran. Enfin, nous avons élaboré deux techniques de ré-échantillonnage permettant d'obtenir à partir des 32 valeurs discrètes, des estimations de l'éclairement dans n'importe quel intervalle spectral, y compris en prenant en compte une réponse spectrale du système éclairé. Des validations ont pu être faites à l'aide de quelques stations de mesures. Les premiers résultats sont jugés encourageants en comparaison avec la précision relevée sur les instruments de mesure de qualité. Des voies d'améliorations ont pu être recensées pour un gain de précision notable.

Published
2015

21. Deriving Photosynthetically Active Radiation at ground level in cloud-free conditions from Copernicus Atmospheric Monitoring Service (CAMS) products.

Author

Wandji Nyamsi, William, Blanc, Phillipe, Augustine, John A., Arola, Antti, and Wald, Lucien

Subjects
PHOTOSYNTHETICALLY active radiation (PAR), RADIATIVE transfer, SPECTRAL irradiance, APPROXIMATION theory, K-distribution (Probability theory)
Abstract

A method is described that estimates the photosynthetically active radiation (PAR) at ground level in cloud-free conditions. It uses a fast approximation of the libRadtran radiative transfer numerical model, known as the k-distribution method and the correlated-k approximation of Kato et al. (1999). LibRadtran provides irradiances aggregated over several fixed spectral bands and a spectral resampling is proposed followed by an aggregation in the range [400, 700] nm. The Copernicus Atmosphere Monitoring Service (CAMS) produces daily estimates of the aerosol properties, and total column contents in water vapor and ozone that are input to the method. A comparison of the results is performed against instantaneous measurements of global Photosynthetic Photon Flux Density (PPFD) on a horizontal plane made in cloud-free conditions at seven sites of the Surface Radiation network (SURFRAD) in the USA in various climates. The bias ranges between -12 μmol m-2 s-1 (-1 % of the mean value at Desert Rock) and +61 μmol m-2 s-1 (+5 % at Penn. State Univ). The root mean square error ranges from 37 μmol m-2 s-1 (3 %) to 82 μmol m-2 s-1 (6 %). The coefficient of determination R² ranges between 0.97 and 0.99. This work demonstrates the quality of the proposed method combined with the CAMS products. [ABSTRACT FROM AUTHOR]

Published
2018
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