[1] Wick D, Martinez T, Restaino S, Stone B. Foveated imaging demonstration. Optics Express, 2002, 10(1): 60–65.
[2] Curatu G. Analysis and design of wide-angle foveated optical systems. Dissertation for the Doctoral Degree. Florida: University of Central Florida, 2009.
[3] Du X, Chang J, Zhang Y,Wang X, Zhang B, Gao L, Xiao L. Design of a dynamic dual-foveated imaging system. Optics Express, 2015, 23(20): 26032–26040.
[4] Feng C, Chang J, Yang H. Design of dually foveated imaging optical system. Acta Phisica Silica, 2015, 64(3): 034201.
[5] Zhao X, Xie Y, Zhao W. Wide field-of-view foveated imaging system. Chinese Optics Letters, 2008, 6(8): 561–563.
[6] Curatu G, Harvey J E. Lens design and system optimization for foveated imaging. In: Proceedings of the Society for Photo- Instrumentation Engineers. 2008, 7060: 70600P-1–70600P-9.
[7] Curatu G, Harvey J E. Analysis and design of wide-angle foveated optical systems based on transmissive liquid crystal spatial light modulators. Optical Engineering (Redondo Beach, Calif.), 2009, 48 (4): 043001.
[8] Peng Q, Chang J, Feng S, Wang R. Reflective foveated optical imaging system based on liquid crystal spatial light modulator. In: Proceedings of the Society for Photo-Instrumentation Engineers. 2010, 7849: 7891l-1–7891l-7.
[9] Xie Y, Zhu S, Hu S, Zhao H, Zhena M A, Chen R, Qiu Y, Gao W, Fan X, Zhao B, Li Y. Space-based telescope with variable resolution at any field angle by active optical zoom. Guangzi Xuebao, 2011, 40 (11): 1619–1624.
[10] Love G D. Wave-front correction and production of Zernike modes with a liquid-crystal spatial light modulator. Applied Optics, 1997, 36(7): 1517–1520