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Improving shadows detection for solar radiation numerical models

Author

Listed:
  • Díaz, F.
  • Montero, H.
  • Santana, D.
  • Montero, G.
  • Rodríguez, E.
  • Mazorra Aguiar, L.
  • Oliver, A.

Abstract

Solar radiation numerical models need the implementation of an accurate method for determining cast shadows on the terrain or on solar collectors. The aim of this work is the development of a new methodology to detect the shadows on a particular terrain. The paper addresses the detection of self and cast shadows produced by the orography as well as those caused by clouds. The paper presents important enhancements on the methodology proposed by the authors in previous works, to detect the shadows caused by the orography. The domain is the terrain surface discretised using an adaptive mesh of triangles. A triangle of terrain will be under cast shadows when, looking at the mesh from the Sun, you can find another triangle that covers all or partially the first one. For each time step, all the triangles should be checked to see if there are cast or self shadows on it. The computational cost of this procedure eventually resulted unaffordable when dealing with complex topography such as that in Canary Islands thus, a new methodology was developed. This one includes a filtering system to identify which triangles are those likely to be shadowed. If there are no self shadowed triangles, the entire mesh will be illuminated and there will not be any shadows. Only triangles that have their backs towards the Sun will be able to cast shadows on other triangles. Detection of shadows generated by clouds is achieved by a shadow algorithm using satellite images. In this paper, Landsat 8 images have been used. The code was done in python programming language. Finally, the outputs of both approaches, shadows generated by the topography and generated by clouds, can be combined in one map. The whole problem has been tested in Gran Canaria and Tenerife Island (Canary Islands – Spain), and in the Tatra Mountains (Poland and Slovakia).

Suggested Citation

  • Díaz, F. & Montero, H. & Santana, D. & Montero, G. & Rodríguez, E. & Mazorra Aguiar, L. & Oliver, A., 2018. "Improving shadows detection for solar radiation numerical models," Applied Mathematics and Computation, Elsevier, vol. 319(C), pages 71-85.
  • Handle: RePEc:eee:apmaco:v:319:y:2018:i:c:p:71-85
    DOI: 10.1016/j.amc.2017.01.046
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    References listed on IDEAS

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    1. Elisha B. Babatunde (ed.), 2012. "Solar Radiation," Books, IntechOpen, number 2039, January-J.
    2. Díaz, F. & Montero, G. & Escobar, J.M. & Rodríguez, E. & Montenegro, R., 2015. "A new predictive solar radiation numerical model," Applied Mathematics and Computation, Elsevier, vol. 267(C), pages 596-603.
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    Cited by:

    1. Gardashov, Rauf & Eminov, Murad & Kara, Gökhan & Emecen Kara, Esma Gül & Mammadov, Tural & Huseynova, Xedce, 2020. "The optimum daily direction of solar panels in the highlands, derived by an analytical method," Renewable and Sustainable Energy Reviews, Elsevier, vol. 120(C).
    2. Arias-Rosales, Andrés & LeDuc, Philip R., 2023. "Urban solar harvesting: The importance of diffuse shadows in complex environments," Renewable and Sustainable Energy Reviews, Elsevier, vol. 175(C).
    3. Kosmopoulos, Panagiotis & Dhake, Harshal & Kartoudi, Danai & Tsavalos, Anastasios & Koutsantoni, Pelagia & Katranitsas, Apostolos & Lavdakis, Nikolaos & Mengou, Eftihia & Kashyap, Yashwant, 2024. "Ray-Tracing modeling for urban photovoltaic energy planning and management," Applied Energy, Elsevier, vol. 369(C).
    4. Arias-Rosales, Andrés & LeDuc, Philip R., 2022. "Shadow modeling in urban environments for solar harvesting devices with freely defined positions and orientations," Renewable and Sustainable Energy Reviews, Elsevier, vol. 164(C).

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