[1] Blevin W R. Optical radiometry-one hundred years after Stefan and Boltzman,Preceedings of the 2nd International conference held,eds., N. P. Fox, D. H. Nettleton. 1988. 1～9

[2] Gentile T R, Houston J M, Hardis J E et al.. The NIST high accuracy cryogenic radiometer. Appl. Opt., 1996, 35: 1056～1068

[3] 姚和军. 陷阱式探测器的结构、性质及其在计量学中的应用. 博士论文, 清华大学电子工程系, 2001

[4] Zheng Xiaobing, Haoyu Wu, Junping Zhang et al.. High-accuracy primacy and transfer standards for radiometric calibration.Chinese Science Bulletin, 2000, 45: 2009～2012

[5] 郑小兵, 吴浩宇, 章骏平 等. 不确定度<0.03%的高精度光谱辐射功率标准. 光学学报, 2001, 21(6): 749～752

[6] King M, Greenstone R et al.. 1999 EOS Reference Handbook, EOS Project Science Office, NASA, 1999

[7] Migdall A L, Datla R U, Sergienko A et al.. Absolute detector quantum-efficiency measurements using correlated photons.Metrologia, 1996, 32: 479～483

[8] Louisell W H, Yariv A, Siegman A E. Quantum fluctuations and noise in parametric processes. Phys. Rev., 1961, 124:1646～1649

[9] Burnham D C, Weigberg D L. Observation of simultaneity in parametric production of optical photon pairs. Phys. Rev. Lett., 1970, 25: 84～87

[10] Klyshko D N. Utilization of Vacuum Fluctuations as an optical brightness standard. Societ J. Quant. Electron., 1977, 7: 591～599

[11] Bowman S R, Shih Y H, Alley C O. The use of Geiger mode avalanche photodiodes for precise laser ranging at very low light levels: an experimental evaluation. Proc. SPIE, 1986, 663: 24～32

[12] Rarity J G, Ridley K D, Tapster P R. Absolute measurement of detector quantum effiency using parametric downconversion.Appl. Opt., 1987, 26: 4616～4619

[13] Penin A N, Sergienko A V. Absolute standardless calibration of photodetectors based on quantum two-photon fields. Appl.Opt., 1991, 30: 3582～3588

[14] Ginzburg V M, Keratishvili N, Korzhenevich E L et al.. Absolute measurement of photodetector quantum effiency based on the parametric down-conversion effect.Opt. Eng., 1993, 32: 2911～2914

[15] Kwait P G, Steinberg A M, Chiao R Y et al.. Abolute effiency and time-response measurements of single-photon electors.Appl. Opt., 1994, 33: 1844～1851

[16] Migdall A L, Datla R U, Sergienko A et al.. Absolute detector quantum-effiency measurements using correlated photons.Metrologia, 1995, 32: 479～483

[17] Brida G, Castelletto S, Degiovanni I P et al.. Quantum effiency and dead time of single-photon counting photodiodes:a comparison between two measurement techniques. Metrologia, 2000, 37: 625～628

[18] Brida G, Castelletto S, Degiovanni I P et al.. Towards an uncertainty budget in quantum-effiency measuments with parametric fluorescence. Metrologia, 2000, 37: 629～632

[19] Hong C K, Mandel L. Theory of parametric frequency down-conversion of light. Phys. Rev. A, 1985, 31: 2409～2418

[20] Brida G, Castelletto S, Novero C et al.. Quantum-effiency measurement of photodectors by means of correlated photons. J.Opt. Soc. Am. B, 1999, 16: 1623～1627

[21] Mandel L, Castelletto S, Degiovanni I P et al.. Intercomparison of a correlated-photon-based method to measure detector quantum effiency. Appl. Opt., 2002, 41: 2914～2922

[22] Sergienko A V, Penin A N. Absolute calibration of analog photondetectors with a biphoton field. Phys. Rev. Lett., 1986, 12:328～331

[23] Migdall A V, Datla R U, Sergienko A et al.. Measuring absolute infrared spectral radiance with correlated visible photons:technique verification and measurement uncertainty. Appl. Opt., 1998, 37: 3455～3463