In relation to the recent published study on MLPE, a study conducted by a researcher who is a previous Danfoss Solar inverter employee (which was acquired by SMA), we believe that there are a number of issues regarding the manner in which the study was conducted.

In relation to the recent published study on MLPE, a study conducted by a researcher who is a previous Danfoss Solar inverter employee (which was acquired by SMA), we believe that there are a number of issues regarding the manner in which the study was conducted.

The testing conditions in the study are stated to be "extreme scenarios" which the study purports to be have been chosen "where optimizers are expected to bring the highest benefits". This is a false expectation and the scenarios are not indicative of real roof top or ground mount PV sites.

Below is further detail on some of the problematic areas of the study which call into question its integrity and conclusions:
• Insufficient test duration: Seasonal variations are not taken into account, which would be required in order to properly quantify the overall effects of shading or orientation variations.
• Exclusion of key data: Data such as PV module power deviations are excluded from the study. This is of particular concern since the standard power deviations (mismatch) of PV modules are actually higher than the differences reported in the test results.
• Handpicking data: The report specifically handpicks days, which misrepresents findings, instead of using averages for the test duration.
• Inadequate testing quantity: Only 14 modules were tested per system in each scenario and the same modules were used in all scenarios. This sample size does not have enough statistical significance to extrapolate meaningful conclusions on the behavior of PV systems.
• Scenarios used in study are not true to life or are unrealistic: For example, the multiple module orientations scenario was simulated by covering only one PV module in a string with a thin cotton sheet. This would not create a different irradiance curve throughout the day, like a different orientated module would in the real world. A second example is the placement of a large pole directly in front of PV modules to cause shading. This simply tests bypass diodes, not module level mismatch.
In addition, we reached out directly to the author of the study, and requested the raw data on which the study is based. He refused to provide the data. In addition, he readily admitted in his reply that, "In this case it is not the added value for the module level optimized pv systems, because the shadow is not effecting the 3 systems equally. Basically the modules with optimizers are firstly effected by the shading and therefore have less yield compared to the other optimizer system and the system without optimizers." This shows that the shade effect on each system that was compared was not identical.
The flaws mentioned, compounded by the author's unwillingness to provide transparency into the data and his admission on the inequality of the test, should cause considerable doubt about how this research was conducted and its conclusions.

The value of power optimizers has been demonstrated by numerous pieces of research conducted by reputable, professional, and objective organizations throughout the years. In addition to these studies, the market continues to recognize the value of DC optimization by choosing SolarEdge, which is why we are the global inverter leader. Some of the studies throughout the years that have reviewed and demonstrated the value of power optimizers include:
• Photon Magazine performed an independent study that showed that power optimizers increase energy yield in both shaded and non-shaded scenarios.
• National Renewable Energy Laboratory (NREL) had PV Evolutions Lab (PVEL) conduct a study that found that the SolarEdge system outperformed a previously-leading standard inverter and microinverter systems.
• Another recent study published by the University of Gayle in 2019, yet again confirmed these findings. In the study, SolarEdge power optimizers demonstrated a 2% energy gain for light shade and up to 8.5% under more severe shading, in comparison to a traditional string inverter system.