[1] Guney M S. Solar power and application methods[J]. Renewable and Sustainable Energy Reviews, 57, 776-785(2016).

[2] Hafez A Z, Soliman A. El-Metwally K A, et al. Design analysis factors and specifications of solar dish technologies for different systems and applications[J]. Renewable and Sustainable Energy Reviews, 67, 1019-1036(2017).

[3] Coventry J, Andraka C. Dish systems for CSP[J]. Solar Energy, 152, 140-170(2017).

[4] Daneshazarian R, Cuce E, Cuce P M et al. Concentrating photovoltaic thermal (CPVT) collectors and systems: theory, performance assessment and applications[J]. Renewable and Sustainable Energy Reviews, 81, 473-492(2018).

[5] Yan J, Peng Y D, Cheng Z R et al. Moving accumulative computation method for flux distribution of heat absorber in symmetry concentrating solar collector system[J]. Acta Optica Sinica, 36, 0508001(2016).

[6] He Y L, Wang K, Du B C et al. Non-uniform characteristics of solar flux distribution in the concentrating solar power systems and its corresponding solutions: a review[J]. Chinese Science Bulletin, 61, 3208-3237(2016).

[7] He Y L, Wang K, Qiu Y et al. Review of the solar flux distribution in concentrated solar power: non-uniform features, challenges, and solutions[J]. Applied Thermal Engineering, 149, 448-474(2019).

[8] Tan M H, Chong K K, Wong C W. Optical characterization of nonimaging dish concentrator for the application of dense-array concentrator photovoltaic system[J]. Applied Optics, 53, 475-486(2014).

[9] Chong K K, Siaw F L, Wong C W et al. Design and construction of non-imaging planar concentrator for concentrator photovoltaic system[J]. Renewable Energy, 34, 1364-1370(2009).

[10] 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).

[11] Xia X L, Dai G L, Sun C. Numerical simulation on concentrating solar characteristic of multi-dish collector[J]. Acta Energiae Solaris Sinica, 33, 1524-1528(2012).

[12] Mao Q J, Shuai Y, Yuan Y. Study on radiation flux of the receiver with a parabolic solar concentrator system[J]. Energy Conversion and Management, 84, 1-6(2014).

[13] Giannuzzi A, Diolaiti E, Lombini M et al. Enhancing the efficiency of solar concentrators by controlled optical aberrations: method and photovoltaic application[J]. Applied Energy, 145, 211-222(2015).

[14] Zhou Z, Cheng Q, Li P P et al. Non-imaging concentrating reflectors designed for solar concentration systems[J]. Solar Energy, 103, 494-501(2014).

[15] Meng X L, Xia X L, Dai G L et al. A vector based freeform approach for reflecting concentrator of solar energy[J]. Solar Energy, 153, 691-699(2017).

[16] Yan J, Peng Y D, Cheng Z R et al. Correlative characteristics between focal spot of solar dish concentrator mirror unit and posture error[J]. Acta Optica Sinica, 36, 1122003(2016).

[17] Yan J, Peng Y D, Cheng Z R. Optimization of a discrete dish concentrator for uniform flux distribution on the cavity receiver of solar concentrator system[J]. Renewable Energy, 129, 431-445(2018).

[18] Yan J, Peng Y D, Cheng Z R. Mirror rearrangement optimization for uniform flux distribution on the cavity receiver of solar parabolic dish concentrator system[J]. International Journal of Energy Research, 42, 3588-3614(2018).

[19] Yan J, Peng Y D, Cheng Z R et al. Solar concentrator mirror unit supporting-adjusting structure and posture alignment[J]. Acta Optica Sinica, 37, 0522001(2017).

[20] Yan J, Cheng Z R, Peng Y D. Effects of geometrical parameters of a dish concentrator on the optical performance of a cavity receiver in a solar dish-stirling system[J]. International Journal of Energy Research, 42, 2152-2168(2018).