[1] [1] B. Stann,W. Ruff,Z. Sztankay. A practical low-cost high-range-resolution ladar [C]. SPIE,1995,2472:118-129

[2] [2] B. Stann,W. Ruff,Z. Sztankay. Intensity-modulated diode laser radar using frequency-modulation/ continuous-wave ranging techniques [J]. Opt. Eng.,1996,35(11):3270-3278

[3] [3] B. Stann,M. Giza,D. Robinson et al.. Scannerless imaging ladar using a laser diode illuminator and FM/cw radar principles [C]. SPIE,1999,3707:421-431

[4] [4] I. Aguroka,B. Stann,Z. Sztankay. An extremely low beam divergence illumination system for laser radar applications [C]. SPIE,2000,4035:334-345

[5] [5] B. Stann,A. A. Auf',W. Ruff et al.. Line imaging ladar using a laser diode transmitter and FM/cw radar principles for submunition applications [C]. SPIE,2000,4035:192-203

[6] [6] B. Stann,K. Aliberti,D. Carothers et al.. A 32×32 pixel focal plane array ladar system using chirped amplitude modulation [C]. SPIE,2004,5412:264-272

[7] [7] B. Redman,B. Stann,W. Ruff et al.. Anti-ship missile tracking with a chirped amplitude modulation ladar [C]. SPIE,2004,5413:113-124

[8] [8] B. Redman,W. Ruff,B. Stann et al.. Anti-ship missile tracking with a chirped AM ladar-update design,model predictions,and experimental results [C]. SPIE,2005,5791:330-341

[9] [9] B. Redman,B. Stann,W. Lawler et al.. Chirped AM ladar for anti-ship missile tracking and force protection 3D imaging:update [C]. SPIE,2006,6214:62140O

[10] [10] B. Stann,B. C. Redman,W. Lawler et al.. Chirped amplitude modulation ladar for range and Doppler measurements and 3-D imaging [C]. SPIE,2007,6550:655005

[11] [11] J. R. Boyd,E. H. Young,S. K. Yao. Design procedure for wide bandwidth acoustooptic modulator[J]. Opt. Eng.,1977,16(5):452-454

[12] [12] H. P. Layer. Acoustooptic modulator intensity servo[J]. Appl. Opt.,1979 ,18(17):2947-2949

[13] [13] D. L. Flannery,A. M. Biernacki,J. S. Loomis et al.. Real-time coherent correlator using binary magnetooptic spatial light modulators at input and Fourier planes[J]. Appl. Opt.,1986,25(4):466-466

[14] [14] J. D. Downie,B. P. Hine,M. B. Reid. Effects and correction of magnetooptic spatial light modulator phase errors in an optical correlator[J]. Appl. Opt.,1992,31(5):636-643

[15] [15] Y. Nihei,A. Harada,K. Kamiyama. Bulk periodically poled MgO:LiNbO3 with high optical damage resistance [C]. Conference on Lasers and Electro Optics,2000,5:632-633

[16] [16] K. Noguchi,O. Mitomi,K. Kawano et al.. Highly efficient 40 GHz bandwidth Ti:LiNbO3 optical modulator employing ridge structure [J]. IEEE Photon. Technol. Lett.,1993,5(1):52-54

[17] [17] D. Miller,D. Chemla,Schmitt Rink. Relation between electro-absorption in bulk semiconductors and in quantum wells:the quantum-confined Franz-Keldysh effect[J]. Phys. Rev. B,1986,33(10):6976-6982

[18] [18] Masahiro Aoki,Hirohisa Sano,Makoto Suzuki. Novel structure MQW electroabsorption modulator DFB-laser integrated device fabricated by selective area MOCVD growth [J]. Electron. Lett.,1991,27(7):2138-2140

[19] [19] S. Kaneko,M. Noda,Y. Miyazaki. An electroabsorption modulator module for digital and analog applications [J]. J. Lightwave Technol.,1999,17:669-676

[20] [20] G. L. Li,P. K. L. Yu. Optical intensity modulators for digital and analog applications [J]. J. Lightwave Technol.,2003,21:2010-2030

[21] [21] Li Tongning,Jin Jinyan,Luo Yi et al.. Monolithic integrated DFB-LD/EA for 2.5 Gbit/s optic fiber communication system [J]. Study on Optical Communications,1999,(3):42-46

[22] [22] Hou Guanghui,Wen Jimin,Huang Hengpei et al.. High frequency characterization measurement of electroabsorption modulated-integrated distributed-feedback laser module[J]. Chinese J. Lasers,2007,34(10):1427-1430

[23] [23] I. McCulloch,H. Yoon. Fluorinated NLO polymers with improved optical transparency in the near infrared [J]. Polymer Sci. A,1995,33(7):1177-1183

[24] [24] Y. Shi,W. Lin,D. J. Olson et al.. Electro-optic polymer modulations with 0.8 V half-wave voltage [J]. Appl. Phys. Lett.,2000,77(1):1-3

[25] [25] L. Mark,K. Howard,E. Christoph et al.. Broadband modulation of light by using an electro-optic polymer [J]. Science,2002,298(5597):1401-1403

[26] [26] Liu Zilong,Zhu Daqing. Electro-optic polymer modulators modulated only in cladding and its theoretical analysis [J]. Acta Optica Sinica,2004,24(11):1516-1520

[27] [27] Wang Zhi,Zhang Jinlei,Meng Qinwen. Effect of the electrodes in an electro-optic polymer modulator on waveguide characteristics [J]. Chinese J. Lasers,2007,34(3):379-382

[28] [28] R. Winston. Dielectric compound parabolic concentrators [J]. Appl. Opt.,1976,15:291-292

[29] [29] J. R. Hull. Dielectric compound parabolic concentrating solar collector with a frustrated total internal reflection absorber[J]. Appl.Opt,1989,28(1):157-162

[30] [30] J. M. Gordon. Complementary construction of ideal non-imaging concentrators and its applications[J]. Appl. Opt.,1996,35(28):5677-5682

[31] [31] Lan Xinju. Laser Technology [M]. Beijing:Science Press,2000. 8-22

[32] [32] Http://www.newfocus.com

[33] [33] R. J. Mears,L. Reekie,I. M. Jauncey et al.. Low-noise erbium-doped fibre amplifier operating at 1.54 μm [J]. Electron. Lett.,1987,23(19):1026-1028

[34] [34] E. Desurvire,J. R. Simposon,P. C. Becker. High-gain erbium-doped traveling-wave fiber amplifier [J]. Opt. Lett.,1987,12(11):888-890

[35] [35] Xin Guofeng,Chen Guoying,Feng Rongzhu et al.. InGaAs/ AlGaAs semiconductor laser 2-D arrays [J]. Chinese J. Lasers,2003,30(8):684-686

[36] [36] Xin Guofeng,Qu Ronghui,Chen Chen et al.. Characterization of a 2D array high power semiconductor laser module [J]. Chinese J. Lasers,2006,33(4):447-450

[37] [37] Lu Wei,Wang Qi,Jiang Peng. A technique and corresponding device for broadband amplitude modulating high-power laser [P]. China Patent,2009,10119749.7