Modelling the influence of atmospheric conditions on the outdoor real performance of a CPV (Concentrated Photovoltaic) module
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Manuel Fuentes | B. García-Domingo | J. de la Casa | Jorge Aguilera | J. Aguilera | J. L. D. Casa | M. Fuentes | B. García-Domingo
[1] Xiaoting Wang,et al. Analysis and Prediction of Energy Production in Concentrating Photovoltaic (CPV) Installations , 2012 .
[2] Wilhelm Warta,et al. Solar cell efficiency tables (version 42) , 2013 .
[3] Alessandro Valli,et al. From a 32 m2 system with 90 CPV modules to a 105 m2 system with 12 CPV modules - Soitec's new CPV system CX-S530 , 2012 .
[4] Zhifeng Wang,et al. An improved temperature estimation method for solar cells operating at high concentrations , 2013 .
[5] K. Araki,et al. A simple rating method for CPV modules and systems , 2008, 2008 33rd IEEE Photovoltaic Specialists Conference.
[6] Eduardo F. Fernández,et al. Outdoor measurement of high concentration photovoltaic receivers operating with partial shading on the primary optics , 2013 .
[7] Eduardo F. Fernández,et al. Quantifying the effect of air temperature in CPV modules under outdoor conditions , 2012 .
[8] César Domínguez,et al. Indoor Characterization of CPV Modules Using the Helios 3198 Solar Simulator , 2009 .
[9] T. Fuyuki,et al. Annual output estimation of concentrator photovoltaic systems using high-efficiency InGaP/InGaAs/Ge triple-junction solar cells based on experimental solar cell's characteristics and field-test meteorological data , 2006 .
[10] Álvaro Gutiérrez,et al. Instituto de Sistemas Fotovoltaicos de Concentración concentration photovoltaics hybrid system first year of operation and improvements , 2013 .
[11] Jen Fin Lin,et al. High-efficiency concentrated optical module , 2012 .
[12] S. Kurtz,et al. Performance of CPV system using three types of III-V multi-junction solar cells , 2012 .
[13] F. Rubio,et al. Comparison of the different CPV rating procedures: Real measurements in ISFOC , 2009, 2009 34th IEEE Photovoltaic Specialists Conference (PVSC).
[14] S. Campbell,et al. Sputtering of metal oxide tunnel junctions for tandem solar cells , 2013, 2013 IEEE 39th Photovoltaic Specialists Conference (PVSC).
[15] S. Askins,et al. Current‐matching estimation for multijunction cells within a CPV module by means of component cells , 2013 .
[16] Antonio J. Rivera,et al. Characterization of Concentrating Photovoltaic modules by cooperative competitive Radial Basis Function Networks , 2013, Expert Syst. Appl..
[17] G. Peharz,et al. A simple method for quantifying spectral impacts on multi-junction solar cells , 2009 .
[18] K. Araki,et al. Validation of energy prediction method for a concentrator photovoltaic module in Toyohashi Japan , 2013 .
[19] Karsten Heuser,et al. Performance results from micro‐cell based high concentration photovoltaic research development and demonstration systems , 2013 .
[20] S. Standard. GUIDE TO THE EXPRESSION OF UNCERTAINTY IN MEASUREMENT , 2006 .
[21] Matthew Muller,et al. Minimizing Variation In Outdoor CPV Power Ratings , 2011 .
[22] Gabriel Sala,et al. Spectral Solar Radiation Measurements and Models for CPV Module Production Estimation , 2010 .
[23] Eduardo F. Fernández,et al. A two subcell equivalent solar cell model for III–V triple junction solar cells under spectrum and temperature variations , 2013 .
[24] John Beavis Lasich,et al. Analysis and Simulation of Performance of CPV Systems with Multi‐Junction Solar Cells , 2010 .
[25] G. Almonacid,et al. High Concentrator PhotoVoltaics efficiencies: Present status and forecast , 2011 .
[26] P. Hebert,et al. Concentrator multijunction solar cell characteristics under variable intensity and temperature , 2008 .
[27] J. Gordon,et al. Basic aspects of the temperature coefficients of concentrator solar cell performance parameters , 2013 .
[28] Marta Victoria,et al. Probing the effects of non-uniform light beams and chromatic aberration on the performance of concentrators using multijunction cells , 2012 .
[29] Eduardo F. Fernández,et al. Temperature coefficients of monolithic III-V triple-junction solar cells under different spectra and irradiance levels , 2012 .
[30] Eduardo F. Fernández,et al. Estimating the maximum power of a High Concentrator Photovoltaic (HCPV) module using an Artificial Neural Network , 2013 .
[31] K. Cen,et al. An improved method of Lambertian CCD-camera radiation flux measurement based on SMARTS (simple model of the atmospheric radiative transfer of sunshine) to reduce spectral errors , 2014 .
[32] Wilhelm Warta,et al. Spectral mismatch correction and spectrometric characterization of monolithic III–V multi‐junction solar cells , 2002 .
[33] G. Peharz,et al. Investigations on the temperature dependence of CPV modules equipped with triple‐junction solar cells , 2011 .
[34] Steve Askins,et al. Power rating of CPV systems based on spectrally corrected DNI , 2012 .
[35] K. Araki,et al. Development of concentrator modules with dome‐shaped Fresnel lenses and triple‐junction concentrator cells , 2005 .
[36] Gerald Siefer,et al. A method for using CPV modules as temperature sensors and its application to rating procedures , 2011 .
[37] Aggelos Zacharopoulos,et al. Chapter 15. Building Integration of High Concentration Photovoltaic Systems , 2015 .
[38] Kenneth W. Stone,et al. Energy prediction of Amonix CPV solar power plants , 2011 .
[39] K. Edmondson,et al. Spectral response and energy output of concentrator multijunction solar cells , 2009 .
[40] Marco Stefancich,et al. Rondine® PV concentrators: Field results and developments , 2009, PVSC 2009.
[41] Andreas Gombert,et al. CPV plants data analysis. ISFOC and NACIR projects results , 2012 .