Determining the optimal standard test condition correction procedure for high‐throughput field <i>I</i>–<i>V</i> measurements of photovoltaic modules

Golive, Yogeswara Rao; Kottantharayil, Anil; Vasi, J.; Shiradkar, Narendra

doi:10.1002/pip.3457

Cited by 19 publications

(32 citation statements)

References 13 publications

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“…Contour plots of average percentage errors in P max obtained in STC correction by Anderson procedure with ( A E , A s ) −15%, ( B E , B s ) 0%, 9 and ( C E , C s ) +15% errors in all three TC ( α , β , and γ ) for experimental (left) and simulation (right) data…”

Section: Resultsmentioning

confidence: 99%

“…The I‐V curves of six multi‐c‐Si PV modules (three each from the two major tier‐1 module manufacturers 15 ) were experimentally measured at STC and at other irradiance and temperature conditions using the SPIRE 5600SLP BLUE system. Based on these measurements and the simulation models discussed in previous studies, 9,16–18 the I‐V curves at desired temperature and irradiance values were generated. The irradiance conditions for the experimentally measured I‐V curves range from 200 to 1,100 W/m 2 with a step of 100 W/m 2 , while the temperature conditions range from 25°C to 70°C with a step of 5°C.…”

Section: Methodsmentioning

confidence: 99%

“…The I‐V curves generated through simulation have the same temperature range and step size; however, they are generated over a slightly broader irradiance range of 200 to 1,300 W/m 2 with the same step size. The Average Root Mean Square Error (ARMSE) was computed by comparing the experimentally measured I‐V curves with those that were generated through simulation 9 . The average percentage errors in all the performance parameters ( P max , V oc , I sc , and FF ) for the entire range of measured and simulated irradiance and temperature conditions for all the six STC correction procedures were predicted and reported 9 .…”

Section: Methodsmentioning

confidence: 99%

“…The Average Root Mean Square Error (ARMSE) was computed by comparing the experimentally measured I‐V curves with those that were generated through simulation 9 . The average percentage errors in all the performance parameters ( P max , V oc , I sc , and FF ) for the entire range of measured and simulated irradiance and temperature conditions for all the six STC correction procedures were predicted and reported 9 . The reported average percentage errors in STC correction in Golive et al 9 are predicted with an assumption that we know the true values of temperature coefficients.…”

Section: Methodsmentioning

confidence: 99%

“…The same conclusion was also valid in a broader range of 200–1,300 W/m 2 irradiance. Out of these procedures, the IEC 60891‐Procedure 4 (VDTC) (the authors have used this name throughout this paper for IEC 60891‐Procedure 4, to be consistent with our previous publication 9 ) was deemed most appropriate for field applications due to its high accuracy and the requirement of only one I‐V curve measured in the field. It should be noted that the VDTC procedure described in Hishikawa et al 8 and the IEC 60891‐Procedure 4 described in the standard have a minor difference.…”

Section: Introductionmentioning

confidence: 99%

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Sensitivity of accuracy of various standard test condition correction procedures to the errors in temperature coefficients of c‐Si PV modules

Golive

Kottantharayil

Shiradkar

2022

Progress in Photovoltaics

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The Standard Test Condition (STC) correction procedures are algorithms used for transforming the Photovoltaic (PV) module current-voltage (I-V) data measured at arbitrary conditions back to STC. The PV module Temperature Coefficients are used as inputs by various STC correction procedures and can significantly influence their accuracy. This paper presents the sensitivity analysis of accuracy of six STC correction procedures (IEC 60891-Procedure 1, Procedure 2, Modified IEC 60891-Procedure 1, IEC 60891-Procedure 4 (Voltage Dependent Temperature Coefficient (VDTC) Procedure), Anderson Procedure, and Standard Irradiance and Desired Temperature Procedure) to the errors in the temperature coefficients of P max , V oc , and I sc . Experimentally measured as well as simulated I-V curves of six multi c-Si PV modules were used in this study. IEC 60891-Procedure 4 (Voltage Dependent Temperature Coefficient) that uses a Voltage Dependent Temperature Coefficient which can be calculated using a single measured I-V curve was found to be most robust against errors in the temperature coefficients.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Sensitivity of accuracy of various standard test condition correction procedures to the errors in temperature coefficients of c‐Si PV modules

Golive

Kottantharayil

Shiradkar

2022

Progress in Photovoltaics

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An accurate analytical model for predicting the maximum power of photovoltaic module operating outdoor under varying conditions

Benahmida

Maouhoub

Tifidat

et al. 2022

Intl J of Energy Research

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Summary One of the crucial study areas for renewable energy is the output power prediction of photovoltaic (PV) generators under various operating situations. Accurate prediction of maximum power is important for the control and design of grid‐connected PV systems. In this study, a new analytical model of voltage and current at maximum power point in relation to temperature and solar irradiation has been proposed to predict the maximum power of PV modules operating from dawn to dusk under real outdoor environmental conditions. Real‐time monitoring values of PV module temperature and solar irradiation have been used to optimize the analytical model parameters during one reference day and then to forecast the maximum power of the PV module for all other days. To validate our proposed analytical model, experimental data recorded by National Renewable Energy Laboratory for three PV modules from single‐crystalline silicon, multi‐crystalline silicon, and amorphous silicon/crystalline silicon heterojunction with intrinsic thin‐layer technologies have been used. Real‐time experimental and optimized characteristic using the proposed model of voltage at maximum power has been compared to three other analytical models in one reference day. The results have shown a good agreement and the normalized error has not exceeded 1%. Furthermore, the comparison of experimental and predicted curves of peak power point in two other arbitrary days has shown a good agreement and the NRMSE values have not exceeded 0.92%.

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Performance evaluation of IEC 60891:2021 procedures for correcting I–V curves of photovoltaic modules under healthy and faulty conditions

Migan‐Dubois

Delpha

2022

Progress in Photovoltaics

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Correction of PV modules' current-voltage characteristics (I-V curves) is essential before they can be used for performance analysis and fault diagnosis under real-life conditions. IEC 60891 (version 2021) has updated Procedure 2 and proposed a new correction Procedure 4 compared to the 2009 version. This study aims to analyze the performance of these new procedures applied to I-V curves of faulty PV modules. The work is based on an mc-Si PV module considering healthy and four common fault conditions with varying fault severity. The irradiance and temperature measured in the field are used to generate I-V curves. The correction procedures of IEC 60891 (version 2021) based on a single curve (Procedures 1, 2, and 4) are evaluated. Environmental factors such as measurement season and irradiation level on the correction performance are studied. The results show that Procedure 2 is relatively betterwith the relative root-mean-square error of the curve current as 2.6% compared to Procedure 1 (2.8%) and Procedure 4 (4.8%). Experimental tests using real I-V curves also show that Procedure 2 exhibits better robustness of correction. The new Procedure 4, whose correction coefficients are determined dynamically, performs poorly under partial shading and short-circuit bypass conditions. However, it achieves similar or better performance than Procedures 1 and 2 under degraded conditions, where the PV fault is generally not easy to detect, making the I-V correction more necessary. It is, therefore, a promising alternative correction procedure when it is difficult to determine the correction coefficients in advance. Finally, the pros and cons of the procedures are discussed with the suggestion of correction procedures under different conditions. The challenges and prospects are also provided.

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Determining the optimal standard test condition correction procedure for high‐throughput field I–V measurements of photovoltaic modules

Cited by 19 publications

References 13 publications

Sensitivity of accuracy of various standard test condition correction procedures to the errors in temperature coefficients of c‐Si PV modules

Sensitivity of accuracy of various standard test condition correction procedures to the errors in temperature coefficients of c‐Si PV modules

An accurate analytical model for predicting the maximum power of photovoltaic module operating outdoor under varying conditions

Performance evaluation of IEC 60891:2021 procedures for correcting I–V curves of photovoltaic modules under healthy and faulty conditions

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