[1] He K Y, Chen Z Q, Zhong S et al. A solar fiber daylighting system without tracking component[J]. Solar Energy, 194, 461-470(2019).

[2] Sedki L, Maaroufi M. Design of parabolic solar daylighting systems based on fiber optic wires: a new heat filtering device[J]. Energy and Buildings, 152, 434-441(2017).

[3] Song J F, Luo G, Tong K et al. A note on dispersion phenomenon in the fiber daylighting system with the Fresnel lens[J]. Solar Energy, 161, 6-8(2018).

[4] Obianuju O N, Chong K K. High acceptance angle optical fiber based daylighting system using two-stage reflective non-imaging dish concentrator[J]. Energy Procedia, 105, 498-504(2017).

[5] Song J F, Jin Z, Zhu Y et al. Development of a fiber daylighting system based on the parallel mechanism and direct focus detection[J]. Solar Energy, 115, 484-493(2015).

[6] Chong K K, Lau S L, Yew T K et al. Design and development in optics of concentrator photovoltaic system[J]. Renewable and Sustainable Energy Reviews, 19, 598-612(2013).

[7] Bellos E, Tzivanidis C. Alternative designs of parabolic trough solar collectors[J]. Progress in Energy and Combustion Science, 71, 81-117(2019).

[8] Yan S Y, Chang Z, Wang F et al. Effect of dust accumulation on focal energy flux density distribution of trough solar concentrator and concentration optimization[J]. Acta Optica Sinica, 37, 0722002(2017).

[9] Wang Y F, Ji J, Li M et al. Performance analysis and design of multi-plane mirrors linear combination solar concentrator[J]. Acta Optica Sinica, 36, 0422002(2016).

[10] Perini S, Tonnellier X, King P et al. Theoretical and experimental analysis of an innovative dual-axis tracking linear Fresnel lenses concentrated solar thermal collector[J]. Solar Energy, 153, 679-690(2017).

[11] Wu G, Zheng H F, Ma X L et al. Experimental investigation of a multi-stage humidification-dehumidification desalination system heated directly by a cylindrical Fresnel lens solar concentrator[J]. Energy Conversion and Management, 143, 241-251(2017).

[12] Kim Y, Jeong H J, Kim W et al. A comparative performance analysis on daylighting for two different types of solar concentrators: Dish vs. Fresnel lens[J]. Energy, 137, 449-456(2017).

[13] Zhu Z Y, Tang Z F, Ma Y Q et al. A kind of cylindrical line-focused Fresnel solar energy medium-temperature collector system[J]. Solar Energy, 274, 33-37(2017).

[14] Li G Q. Optimization analysis and experimental research of stationary solar concentrator[D]. Hefei: University of Science and Technology of China, 83-94(2013).

[15] Karp J H, Tremblay E J, Ford J E. Planar micro-optic solar concentrator[J]. Optics Express, 18, 1122-1133(2010).

[16] Bouchard S, Thibault S. Planar waveguide concentrator used with a seasonal tracker[J]. Applied Optics, 51, 6848-6854(2012).

[17] Nithyanandam K, Deshpande J, Pitchumani R. Coupled thermal and optical analysis of a planar waveguide concentrator-receiver[J]. Applied Energy, 208, 1576-1589(2017).

[18] Yin P, Xu X P, Jiang Z G. Ray-leakage-free planar solar concentrator featuring achromatic hybrid collectors and innovative secondary optical elements[J]. Optics Communications, 402, 678-689(2017).

[19] Vu N H, Shin S. Optical fiber daylighting system combined with LED lighting and CPV based on stepped thickness waveguide for indoor lighting[J]. Journal of the Optical Society of Korea, 20, 488-499(2016).

[20] Liu W, Mitzi D B, Yuan M et al. 12% efficiency CuIn(Se, S)2photovoltaic device prepared using a hydrazine solution process[J]. Chemistry of Materials, 22, 1010-1014(2010).

[21] Chen H Y, Yu S M, Shin D W et al. Solvothermal synthesis and characterization of chalcopyrite CuInSe2 nanoparticles[J]. Nanoscale Research Letters, 5, 217-223(2010).

[22] Wu H Y, Chu S C. Ray-leakage-free sawtooth-shaped planar lightguide solar concentrators[J]. Optics Express, 21, 20073-20089(2013).