Generalized and Mechanistic PV Module Performance Prediction from Computer Vision and Machine Learning on Electroluminescence Images

Ahmad Maroof Karimi; Justin S. Fada; Nicholas A. Parrilla; Benjamin G. Pierce; Mehmet Koyuturk; Roger H. French; Jennifer L. Braid

doi:10.1109/JPHOTOV.2020.2973448

Generalized and Mechanistic PV Module Performance Prediction from Computer Vision and Machine Learning on Electroluminescence Images

Ahmad Maroof Karimi, Justin S. Fada, Nicholas A. Parrilla, Benjamin G. Pierce, Mehmet Koyuturk, Roger H. French, Jennifer L. Braid

Analytics and AI Methods at Scale

Research output: Contribution to journal › Article › peer-review

52 Scopus citations

Abstract

Electroluminescence (EL) imaging of photovoltiac (PV) modules offers high-speed, high-resolution information about device performance, affording opportunities for greater insight and efficiency in module characterization across manufacturing, research and development, and power plant operations and management. Predicting module electrical properties from EL image features is a critical step toward these applications. In this article, we demonstrate quantification of both generalized and performance mechanism-specific EL image features, using pixel intensity-based and machine learning classification algorithms. From EL image features, we build predictive models for PV module power and series resistance, using time-series current-voltage (I-V) and EL data obtained stepwise on five brands of modules spanning three Si cell types through two accelerated exposures: damp heat (DH) (85 ^circC/85% RH) and thermal cycling (TC) (IEC 61215). In total, 195 pairs of EL images and I-V characteristics were analyzed, yielding 11 700 individual PV cell images. A convolutional neural network was built to classify cells by the severity of busbar corrosion with high accuracy (95%). Generalized power predictive models estimated the maximum power of PV modules from EL images with high confidence and an adjusted-R^2 of 0.88, across all module brands and cell types in extended DH and TC exposures. Mechanistic degradation prediction was demonstrated by quantification of busbar corrosion in EL images of three module brands in DH, and subsequent modeling of series resistance using these mechanism-specific EL image features. For modules exhibiting busbar corrosion, we demonstrated series resistance predictive models with adjusted-R^2 of up to 0.73.

Original language	English
Article number	9050914
Pages (from-to)	878-887
Number of pages	10
Journal	IEEE Journal of Photovoltaics
Volume	10
Issue number	3
DOIs	https://doi.org/10.1109/JPHOTOV.2020.2973448
State	Published - May 2020

Funding

Manuscript received October 17, 2019; revised December 11, 2019 and January 24, 2020; accepted February 3, 2020. Date of publication March 30, 2020; date of current version April 21, 2020. This work was supported by the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy (EERE) under Solar Energy Technologies Office (SETO) Agreement no. DE-EE-0008172. The work of Jennifer L. Braid was supported by the U.S. Department of Energy (DOE) Office of Energy Efficiency and Renewable Energy administered by the Oak Ridge Institute for Science and Education (ORISE) for the DOE. ORISE is managed by Oak Ridge Associated Universities (ORAU) under DOE Contract no. DE-SC0014664. (Corresponding author: Jennifer Braid.) Ahmad Maroof Karimi and Benjamin G. Pierce are with SDLE Research Center, Case Western Reserve University, Cleveland, OH 44106 USA, and also with the Department of Computer and Data Sciences, Case Western Reserve University, Cleveland, OH 44106 USA (e-mail: [email protected]; [email protected]).

Keywords

Computer vision
convolutional neural network (CNN)
corrosion
damp heat (DH)
electroluminescence (EL) imaging
photovoltiac (PV) module degradation
thermal cycling (TC)

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10.1109/JPHOTOV.2020.2973448

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@article{8cbdaffadcb142e39a8eb268ce2c5768,

title = "Generalized and Mechanistic PV Module Performance Prediction from Computer Vision and Machine Learning on Electroluminescence Images",

abstract = "Electroluminescence (EL) imaging of photovoltiac (PV) modules offers high-speed, high-resolution information about device performance, affording opportunities for greater insight and efficiency in module characterization across manufacturing, research and development, and power plant operations and management. Predicting module electrical properties from EL image features is a critical step toward these applications. In this article, we demonstrate quantification of both generalized and performance mechanism-specific EL image features, using pixel intensity-based and machine learning classification algorithms. From EL image features, we build predictive models for PV module power and series resistance, using time-series current-voltage (I-V) and EL data obtained stepwise on five brands of modules spanning three Si cell types through two accelerated exposures: damp heat (DH) (85 ^circC/85% RH) and thermal cycling (TC) (IEC 61215). In total, 195 pairs of EL images and I-V characteristics were analyzed, yielding 11 700 individual PV cell images. A convolutional neural network was built to classify cells by the severity of busbar corrosion with high accuracy (95%). Generalized power predictive models estimated the maximum power of PV modules from EL images with high confidence and an adjusted-R^2 of 0.88, across all module brands and cell types in extended DH and TC exposures. Mechanistic degradation prediction was demonstrated by quantification of busbar corrosion in EL images of three module brands in DH, and subsequent modeling of series resistance using these mechanism-specific EL image features. For modules exhibiting busbar corrosion, we demonstrated series resistance predictive models with adjusted-R^2 of up to 0.73.",

keywords = "Computer vision, convolutional neural network (CNN), corrosion, damp heat (DH), electroluminescence (EL) imaging, photovoltiac (PV) module degradation, thermal cycling (TC)",

author = "Karimi, {Ahmad Maroof} and Fada, {Justin S.} and Parrilla, {Nicholas A.} and Pierce, {Benjamin G.} and Mehmet Koyuturk and French, {Roger H.} and Braid, {Jennifer L.}",

note = "Publisher Copyright: {\textcopyright} 2011-2012 IEEE.",

year = "2020",

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doi = "10.1109/JPHOTOV.2020.2973448",

language = "English",

volume = "10",

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T1 - Generalized and Mechanistic PV Module Performance Prediction from Computer Vision and Machine Learning on Electroluminescence Images

AU - Karimi, Ahmad Maroof

AU - Fada, Justin S.

AU - Parrilla, Nicholas A.

AU - Pierce, Benjamin G.

AU - Koyuturk, Mehmet

AU - French, Roger H.

AU - Braid, Jennifer L.

PY - 2020/5

Y1 - 2020/5

N2 - Electroluminescence (EL) imaging of photovoltiac (PV) modules offers high-speed, high-resolution information about device performance, affording opportunities for greater insight and efficiency in module characterization across manufacturing, research and development, and power plant operations and management. Predicting module electrical properties from EL image features is a critical step toward these applications. In this article, we demonstrate quantification of both generalized and performance mechanism-specific EL image features, using pixel intensity-based and machine learning classification algorithms. From EL image features, we build predictive models for PV module power and series resistance, using time-series current-voltage (I-V) and EL data obtained stepwise on five brands of modules spanning three Si cell types through two accelerated exposures: damp heat (DH) (85 ^circC/85% RH) and thermal cycling (TC) (IEC 61215). In total, 195 pairs of EL images and I-V characteristics were analyzed, yielding 11 700 individual PV cell images. A convolutional neural network was built to classify cells by the severity of busbar corrosion with high accuracy (95%). Generalized power predictive models estimated the maximum power of PV modules from EL images with high confidence and an adjusted-R^2 of 0.88, across all module brands and cell types in extended DH and TC exposures. Mechanistic degradation prediction was demonstrated by quantification of busbar corrosion in EL images of three module brands in DH, and subsequent modeling of series resistance using these mechanism-specific EL image features. For modules exhibiting busbar corrosion, we demonstrated series resistance predictive models with adjusted-R^2 of up to 0.73.

AB - Electroluminescence (EL) imaging of photovoltiac (PV) modules offers high-speed, high-resolution information about device performance, affording opportunities for greater insight and efficiency in module characterization across manufacturing, research and development, and power plant operations and management. Predicting module electrical properties from EL image features is a critical step toward these applications. In this article, we demonstrate quantification of both generalized and performance mechanism-specific EL image features, using pixel intensity-based and machine learning classification algorithms. From EL image features, we build predictive models for PV module power and series resistance, using time-series current-voltage (I-V) and EL data obtained stepwise on five brands of modules spanning three Si cell types through two accelerated exposures: damp heat (DH) (85 ^circC/85% RH) and thermal cycling (TC) (IEC 61215). In total, 195 pairs of EL images and I-V characteristics were analyzed, yielding 11 700 individual PV cell images. A convolutional neural network was built to classify cells by the severity of busbar corrosion with high accuracy (95%). Generalized power predictive models estimated the maximum power of PV modules from EL images with high confidence and an adjusted-R^2 of 0.88, across all module brands and cell types in extended DH and TC exposures. Mechanistic degradation prediction was demonstrated by quantification of busbar corrosion in EL images of three module brands in DH, and subsequent modeling of series resistance using these mechanism-specific EL image features. For modules exhibiting busbar corrosion, we demonstrated series resistance predictive models with adjusted-R^2 of up to 0.73.

KW - Computer vision

KW - convolutional neural network (CNN)

KW - corrosion

KW - damp heat (DH)

KW - electroluminescence (EL) imaging

KW - photovoltiac (PV) module degradation

KW - thermal cycling (TC)

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U2 - 10.1109/JPHOTOV.2020.2973448

DO - 10.1109/JPHOTOV.2020.2973448

M3 - Article

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VL - 10

SP - 878

EP - 887

JO - IEEE Journal of Photovoltaics

JF - IEEE Journal of Photovoltaics

IS - 3

M1 - 9050914

ER -

Generalized and Mechanistic PV Module Performance Prediction from Computer Vision and Machine Learning on Electroluminescence Images

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