1995
DOI: 10.1002/pip.4670030204
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Analysis and control of mismatch power loss in photovoltaic arrays

Abstract: Connecting photovoltaic cells to form an array IN TROD UCTIONhotovoltaic (PV) cells have been developed to the point where they are viable for a range of applications. However, a major problem still affecting the performance and reliability of PV P systems is that of mismatch. Mismatch occurs due to the interconnection of cells with different performance characteristics. This condition results in two detrimental effects: power loss and reliability degradation.When the characteristics of cells within a PV array… Show more

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Cited by 44 publications
(26 citation statements)
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“…It is well known that, in case of mismatch (due to clouds, shadows, dirtiness, manufacturing tolerances, aging, different orientation of parts of the PV field in the so called Building Integrated Photovoltaic Systems etc. ), the P-V characteristic of the PV field exhibits more than one peak, due to the presence of bypass diodes, and MPPT algorithms can fail [8]- [17]. The failure of such MPPT algorithms is due to the fact that they are not able to avoid that the operating point of the PV source may remain trapped in the neighborhood of a relative maximum power point instead that close to the absolute maximum power point.…”
Section: Dmppt By Means Of Power Optimizersmentioning
confidence: 99%
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“…It is well known that, in case of mismatch (due to clouds, shadows, dirtiness, manufacturing tolerances, aging, different orientation of parts of the PV field in the so called Building Integrated Photovoltaic Systems etc. ), the P-V characteristic of the PV field exhibits more than one peak, due to the presence of bypass diodes, and MPPT algorithms can fail [8]- [17]. The failure of such MPPT algorithms is due to the fact that they are not able to avoid that the operating point of the PV source may remain trapped in the neighborhood of a relative maximum power point instead that close to the absolute maximum power point.…”
Section: Dmppt By Means Of Power Optimizersmentioning
confidence: 99%
“…Therefore, since a PV module is equipped with more than one bypass diode, if the module is not uniformly shadowed but, as an example, only one cell is covered by snow or dirt, then the power versus voltage characteristic of the whole PV module may exhibit multiple peaks. In such a case, the MPPT controller of the dc/dc converter associated to such a PV module can lead to a suboptimal operating condition since no MPPT technique is able to correctly face the presence of multiple peaks in the power versus voltage PV characteristic [8]- [17]. Therefore, it is worth noting that DMPPT is fully effective only if each PV module is equipped with as many dc/dc converters as bypass diodes.…”
Section: Dmppt By Means Of Power Optimizersmentioning
confidence: 99%
“…By optimizing the parasitic shunt resistance of the solar cell, the partial shading power loss can be reduced [4]. Normally, we want to maximize this shunt resistance, since it leads to power loss in a fully-irradiated solar panel.…”
Section: Introductionmentioning
confidence: 99%
“…The voltage drop depends on the bandgap of the semiconducting material and the current and voltage ratings of the diode. For high-power Si Schottky diodes on the market, the turn-on voltage is often between 0.4 and 0.5 volts [16]. Here we assume the diode voltage drop is 0.45 volts.…”
Section: Diode In Normal Operationmentioning
confidence: 99%