[1] Chen Zhongjian, Li Xiaoyong, Ji Lijiu, et al. A novel low power 64×64 CMOS snapshot readout structure for focal plane array[J]. Chinese Journal of Semiconductors, 2001, 22(11): 1450-1457.
[3] Li Yu, Bai Piji, Wang Bo, et al. 384×288 focal plane ROIC with pixel accumulation[J]. Infrared and Laser Engineering, 2011, 40(11): 2110-2113.
[7] Bai Tingzhu, Jin Weiqi. Principle and technology of photoelectric imaging[M]. Beijing: Beijing Institute of Technology Press, 2006: 54-64.
[8] Tan Heping, Xia Xinlin, Liu Linhua, et al. Numerical calculation of infrared radiation and transmission-calculation of thermal radiation[M]. Harbin: Harbin Institute of Technology Press, 2006: 11-12.
[9] Guellec F, Peizerat A, Tchagaspanian M, et al. A 25 μm pitch LWIR focal plane array with pixel-level 15 bit ADC providing high well capacity and targeting 2mK NETD[J]. SPIE, 2010, 7660: 76603T.
[10] Bisotto S, Borniol E, Mollard L, et al. A 25 μm pitch staring LWIR focal plane array with pixel-level 15 bit ADC ROIC achieving 2 mK NETD[J]. SPIE, 2010, 7834: 78340J.
[11] Tyrrell B, Berger R, Colonero C, et al. Design approaches for digitally dominated active pixel sensors: Leveraging Moore′s Law scaling in focal plane readout design[J]. SPIE, 2008, 6900: 69000W.
[12] Kelly M, Berger R, Colonero C, et al. Design and testing of an all-digital readout integrated circuit for infrared focal plane arrays[J]. SPIE, 2005, 5902: 105-115.
[13] Kayahan H, Yazici M, Ceylan , et al. A new digital readout integrated circuit (DROIC) with pixel parallel AD conversion and reduced quantization noise[J]. Infrared Physics & Technology, 2013, 63: 125-132.
[15] Li Chunlai, Wu Gang, Liu Yinnian, et al. Study of cryogenic optics system′s radiation characteristic[J]. Laser & Infrared, 2006, 36(12): 1146-1148.
[16] Wu Limin, Zhou Feng, Wang Huaiyi. Study on the relationship between the infrared detectors background limit detectiviy and the optical systems work temperature[J]. Spacecraft Recovery & Remote Sensing, 2010, 31(1): 36-41.