Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction

Jessy Tapia; Gustavo Caiza; Paulina Ayala; Jaime Guilcapi-M; Marcelo V. Garcia

doi:10.1007/978-3-031-69228-4_16

Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction

Jessy Tapia
, Gustavo Caiza
, Paulina Ayala
, Jaime Guilcapi-M
, Marcelo V. Garcia

Research Group in Electronics Control and Automation (GIECA)

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

3 Scopus citations

Abstract

This study delves into the utilization of artificial neural networks (ANNs) to enhance the efficiency and stability of photovoltaic solar systems. Despite their clean and renewable energy source, photovoltaic systems encounter challenges arising from solar radiation, temperature variations, and environmental conditions, leading to fluctuations in current and voltage output and impacting power generation. The research addresses this concern by advocating for control strategies that optimize power extraction from the photovoltaic field. The central focus lies on the maximum power point (MPP), which denotes the optimal power transfer point on the current-voltage characteristic curve of a solar panel. Achieving precise MPP tracking is pivotal for bolstering system efficiency, given the task’s complexity in adapting to changing conditions. Existing tracking algorithms exhibit shortcomings in tracking rates and steady-state oscillations. To overcome these limitations, the study explores the application of ANNs in designing control algorithms. ANNs stand out for their agility in responding dynamically and adapting to nonlinear conditions. Yet, acquiring accurate training data for the controller remains a primary challenge. The investigation considers crucial factors like solar radiation, temperature, and optimal voltage as inputs for the controller. The proposed approach, built upon daily satellite-derived data for Latacunga city, yields promising results. It showcases an impressive average efficiency increase of up to 11.24%, alongside achieving rapid transient responses as swift as 0.56 ms. This research contributes to the advancement of photovoltaic technology by harnessing the potential of ANNs to revolutionize power extraction and utilization in solar systems.

Original language	English
Title of host publication	Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies
Editors	Marcelo V. Garcia, Carlos Gordón-Gallegos, Asier Salazar-Ramírez, Carlos Nuñez
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	235-256
Number of pages	22
ISBN (Print)	9783031692277
DOIs	https://doi.org/10.1007/978-3-031-69228-4_16
State	Published - 2024
Event	International Conference on Computer Science, Electronics and Industrial Engineering, CSEI 2023 - Ambato, Ecuador Duration: 6 Nov 2023 → 10 Nov 2023

Publication series

Name	Lecture Notes in Networks and Systems
Volume	775 LNNS
ISSN (Print)	2367-3370
ISSN (Electronic)	2367-3389

Conference

Conference	International Conference on Computer Science, Electronics and Industrial Engineering, CSEI 2023
Country/Territory	Ecuador
City	Ambato
Period	6/11/23 → 10/11/23

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

ANN-based control
Artificial neural networks (ANNs)
Efficiency; Photovoltaic solar systems
Maximum power point (MPP)

CACES Knowledge Areas

417A Electronics, Automation and Sound

Access to Document

10.1007/978-3-031-69228-4_16

Cite this

Tapia, J., Caiza, G., Ayala, P., Guilcapi-M, J., & Garcia, M. V. (2024). Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction. In M. V. Garcia, C. Gordón-Gallegos, A. Salazar-Ramírez, & C. Nuñez (Eds.), Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies (pp. 235-256). (Lecture Notes in Networks and Systems; Vol. 775 LNNS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-69228-4_16

Tapia, Jessy ; Caiza, Gustavo ; Ayala, Paulina et al. / Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction. Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies. editor / Marcelo V. Garcia ; Carlos Gordón-Gallegos ; Asier Salazar-Ramírez ; Carlos Nuñez. Springer Science and Business Media Deutschland GmbH, 2024. pp. 235-256 (Lecture Notes in Networks and Systems).

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title = "Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction",

abstract = "This study delves into the utilization of artificial neural networks (ANNs) to enhance the efficiency and stability of photovoltaic solar systems. Despite their clean and renewable energy source, photovoltaic systems encounter challenges arising from solar radiation, temperature variations, and environmental conditions, leading to fluctuations in current and voltage output and impacting power generation. The research addresses this concern by advocating for control strategies that optimize power extraction from the photovoltaic field. The central focus lies on the maximum power point (MPP), which denotes the optimal power transfer point on the current-voltage characteristic curve of a solar panel. Achieving precise MPP tracking is pivotal for bolstering system efficiency, given the task{\textquoteright}s complexity in adapting to changing conditions. Existing tracking algorithms exhibit shortcomings in tracking rates and steady-state oscillations. To overcome these limitations, the study explores the application of ANNs in designing control algorithms. ANNs stand out for their agility in responding dynamically and adapting to nonlinear conditions. Yet, acquiring accurate training data for the controller remains a primary challenge. The investigation considers crucial factors like solar radiation, temperature, and optimal voltage as inputs for the controller. The proposed approach, built upon daily satellite-derived data for Latacunga city, yields promising results. It showcases an impressive average efficiency increase of up to 11.24\%, alongside achieving rapid transient responses as swift as 0.56 ms. This research contributes to the advancement of photovoltaic technology by harnessing the potential of ANNs to revolutionize power extraction and utilization in solar systems.",

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author = "Jessy Tapia and Gustavo Caiza and Paulina Ayala and Jaime Guilcapi-M and Garcia, \{Marcelo V.\}",

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Tapia, J, Caiza, G, Ayala, P, Guilcapi-M, J & Garcia, MV 2024, Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction. in MV Garcia, C Gordón-Gallegos, A Salazar-Ramírez & C Nuñez (eds), Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies. Lecture Notes in Networks and Systems, vol. 775 LNNS, Springer Science and Business Media Deutschland GmbH, pp. 235-256, International Conference on Computer Science, Electronics and Industrial Engineering, CSEI 2023, Ambato, Ecuador, 6/11/23. https://doi.org/10.1007/978-3-031-69228-4_16

Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction. / Tapia, Jessy; Caiza, Gustavo; Ayala, Paulina et al.
Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies. ed. / Marcelo V. Garcia; Carlos Gordón-Gallegos; Asier Salazar-Ramírez; Carlos Nuñez. Springer Science and Business Media Deutschland GmbH, 2024. p. 235-256 (Lecture Notes in Networks and Systems; Vol. 775 LNNS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Tapia, Jessy

AU - Caiza, Gustavo

AU - Ayala, Paulina

AU - Guilcapi-M, Jaime

AU - Garcia, Marcelo V.

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.

PY - 2024

Y1 - 2024

N2 - This study delves into the utilization of artificial neural networks (ANNs) to enhance the efficiency and stability of photovoltaic solar systems. Despite their clean and renewable energy source, photovoltaic systems encounter challenges arising from solar radiation, temperature variations, and environmental conditions, leading to fluctuations in current and voltage output and impacting power generation. The research addresses this concern by advocating for control strategies that optimize power extraction from the photovoltaic field. The central focus lies on the maximum power point (MPP), which denotes the optimal power transfer point on the current-voltage characteristic curve of a solar panel. Achieving precise MPP tracking is pivotal for bolstering system efficiency, given the task’s complexity in adapting to changing conditions. Existing tracking algorithms exhibit shortcomings in tracking rates and steady-state oscillations. To overcome these limitations, the study explores the application of ANNs in designing control algorithms. ANNs stand out for their agility in responding dynamically and adapting to nonlinear conditions. Yet, acquiring accurate training data for the controller remains a primary challenge. The investigation considers crucial factors like solar radiation, temperature, and optimal voltage as inputs for the controller. The proposed approach, built upon daily satellite-derived data for Latacunga city, yields promising results. It showcases an impressive average efficiency increase of up to 11.24%, alongside achieving rapid transient responses as swift as 0.56 ms. This research contributes to the advancement of photovoltaic technology by harnessing the potential of ANNs to revolutionize power extraction and utilization in solar systems.

AB - This study delves into the utilization of artificial neural networks (ANNs) to enhance the efficiency and stability of photovoltaic solar systems. Despite their clean and renewable energy source, photovoltaic systems encounter challenges arising from solar radiation, temperature variations, and environmental conditions, leading to fluctuations in current and voltage output and impacting power generation. The research addresses this concern by advocating for control strategies that optimize power extraction from the photovoltaic field. The central focus lies on the maximum power point (MPP), which denotes the optimal power transfer point on the current-voltage characteristic curve of a solar panel. Achieving precise MPP tracking is pivotal for bolstering system efficiency, given the task’s complexity in adapting to changing conditions. Existing tracking algorithms exhibit shortcomings in tracking rates and steady-state oscillations. To overcome these limitations, the study explores the application of ANNs in designing control algorithms. ANNs stand out for their agility in responding dynamically and adapting to nonlinear conditions. Yet, acquiring accurate training data for the controller remains a primary challenge. The investigation considers crucial factors like solar radiation, temperature, and optimal voltage as inputs for the controller. The proposed approach, built upon daily satellite-derived data for Latacunga city, yields promising results. It showcases an impressive average efficiency increase of up to 11.24%, alongside achieving rapid transient responses as swift as 0.56 ms. This research contributes to the advancement of photovoltaic technology by harnessing the potential of ANNs to revolutionize power extraction and utilization in solar systems.

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KW - Maximum power point (MPP)

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Tapia J, Caiza G, Ayala P, Guilcapi-M J, Garcia MV. Enhancing Photovoltaic System Efficiency Through Neural Network-Based Tracking for Optimal Power Extraction. In Garcia MV, Gordón-Gallegos C, Salazar-Ramírez A, Nuñez C, editors, Proceedings of the International Conference on Computer Science, Electronics and Industrial Engineering (CSEI 2023) - Advances in Computer Sciences - Exploring Innovations at the Intersection of Computing Technologies. Springer Science and Business Media Deutschland GmbH. 2024. p. 235-256. (Lecture Notes in Networks and Systems). doi: 10.1007/978-3-031-69228-4_16