Abstract: . . .  the non-insulated single-crystalline panel in this study could be reported as 7.2, 10.4, or 11.8% , as a result of using the aperture, coverage, or cell area in computing efficiency. During the twelve months that the panels have been monitored, the measured midday efficiencies for the non-insulated panels are 10.4, 10.2, 6.5, and 6.1% for the single-crystalline, polycrystal- line, silicon film, and amorphous silicon panels, respectively. The non-insulated single-crystalline, polycrystalline, and . . .
. . .  for Designing Low Energy Buildings,’’ Sustainable Buildings Energy Council, Washington, D.C. 6 IV Curve Tracer, Solar Design Studio, v4.0, Maui Solar Energy Software Corp., Haiku, I, October 2000. 7 King, D. L., 1997, ‘‘Photovoltaic Module and Array Performance Character- ization methods for all System Operating Conditions,’’ Proc. of NREL/SNL Photovoltaics Program Review Meeting, Nov. 1996, Lakewood, CO, AIP Press, New York. 8 Fanney, A. H., and Dougherty, B. P., 2000, ‘‘Building Integrated Photovoltaic . . .
. . .  1997, ‘‘Measuring Solar Spectral and Angle-of-Incidence Effects on Photovoltaic Modules and Solar Irradiance Sensors,’’ 26th IEEE Photovoltaic Specialists Conf., Anaheim, CA. 12 Davis, M. W., Fanney, A. H., and Dougherty, B. P., 2001 ‘‘Prediction of Building Integrated Photovoltaic Cell Temperatures,’’ Proc. of Forum 2001, Solar Energy: The Power to Choose, April 2001, ASES, Washington, DC. Journal of Solar Energy Engineering AUGUST 2001, Vol. 123 Õ 193  . . .
. . .  ‘‘Measuring Solar Spectral and Angle-of-Incidence Effects on Photovoltaic Modules and Solar Irradiance Sensors,’’ 26th IEEE Photovoltaic Specialists Conf., Anaheim, CA. 12 Davis, M. W., Fanney, A. H., and Dougherty, B. P., 2001 ‘‘Prediction of Building Integrated Photovoltaic Cell Temperatures,’’ Proc. of Forum 2001, Solar Energy: The Power to Choose, April 2001, ASES, Washington, DC. Journal of Solar Energy Engineering AUGUST 2001, Vol. 123 Õ 193  . . .
. . .  Solar Spectral and Angle-of-Incidence Effects on Photovoltaic Modules and Solar Irradiance Sensors,’’ 26th IEEE Photovoltaic Specialists Conf., Anaheim, CA. 12 Davis, M. W., Fanney, A. H., and Dougherty, B. P., 2001 ‘‘Prediction of Building Integrated Photovoltaic Cell Temperatures,’’ Proc. of Forum 2001, Solar Energy: The Power to Choose, April 2001, ASES, Washington, DC. Journal of Solar Energy Engineering AUGUST 2001, Vol. 123 Õ 193  . . .
. . .  Premium Power Program and the California Energy Commission for providing financial support for this project. Also recognized for their contributions are Jake Brown of Solar Building Systems for his assistance in the design and fabrication of the BIPV panels. Gratitude is extended to the following NIST personnel who have assisted the authors: Stanley T. Morehouse for his role in fabricating the various facilities de- scribed within this paper; Robert Zarr for calibrating the heat flux transducers, . . .
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