7.1 Consider PV module A whose characteristics are shown in Table 7.3. Com- pute: The cell temperature if the irradiance is 1000 W/m² and the ambient temperature is 31°C • The short-circuit current, open-circuit voltage, and maximum power if the irradiance is 1000 W/m² and the cell temperature is as computed in the previous part of this problem • The short-circuit current if the irradiance is 500 W/m²

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Table 7.3 Electrical characteristics of PV module A and module B Characteristic at STC Module A Module B Maximum power 350 W 20 W Optimum operating voltage (V*) Optimum operating current (I*) 38.54 V 18 V 9.08 A 1.11 A Open-circuit voltage (Voc) 47.43 V 22.5 V Short-circuit current (Isc) 9.49 A 1.23 A Short-circuit current temp. coeff. (œ¡) 0.040 %/K 0.045%/K -0.34 %/K Open-circuit voltage temp. coeff. (æ,) Мах. power temp. cоeff. (a p) -0.29 %/K -0.38 %/K -0.47 %/K NOCT 45°C 47°C Number of cells 72 (series) 36 (series)

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7.1 Consider PV module A whose characteristics are shown in Table 7.3. Com- pute: The cell temperature if the irradiance is 1000 W/m² and the ambient temperature is 31°C The short-circuit current, open-circuit voltage, and maximum power if the irradiance is 1000 W/m² and the cell temperature is as computed in the previous part of this problem The short-circuit current if the irradiance is 500 W/m2 The power produced using Osterwald's method if the irradiance is 650 W/m² and the ambient temperature is 20°C