[1] QU Y C,REN D M,HU X Y,et al.. A monolithic microprocessor controlled turing and triggering system of TEA CO2 laser for differential absorption lidar [J]. SPIE,2003,4893:377-383.

[2] PILTINGSRUD H V. CO2 laser for lider application,producing two narrowly spaced independently wavelength-selectable Q-switched output pulses [J]. Appl. Opt.,1991,30(27):3952-3963.

[3] PEARSON GRYE B J. Frequency fidelity of a compact CO2 Doppler lidar transmitter[J]. Appl. Opt.,1992,31(30):6475-6484.

[4] SUN C W. Laser Irradiation Effect [M]. Beijing: National Defence Press,2002.(in Chinese)

[5] TIAN Z S,CHENG X Y,WANG Q. Developments of electric-optically Q-switched CO2 laser[J]. Laser Technology,2003,27(3):208-213.(in Chinese)

[6] WANG T J. Studies on mid-infrared tunable lasers[CB/OL]. (2007-09-12).http://dlib.cnki.net/kns50/detail.

[7] LI J J,WANG R F,CHEN W Y. An acousto-optic Q-switched CO2 quasi-waveguide laser[J].Chinese Journal of Lasers,1995,A22(3):195-198.(in Chinese)

[8] LETALICK D,RENHOM I. CO2 waveguide laser with programmable pulse profile [J]. Opt. Eng.,1989,28(2):172-179.

[9] LAN X J. Laser Technology[M]. Beijing:Science Press,2005:83-117.(in Chinese)

[10] BRIDGES T J,CHEO P K. Spontaneous self-pulsing and cavity dumping in a CO2 laser with electro-optic Q-switching[J]. Appl. Phys. Lett.,1969,14(9):262-264.

[11] JACOBS R R,PETTI-PIECE K J. Rotational relaxation rate constants for CO2[J]. Appl. Phys. Lett.,1974,24(8):375-377.

[12] CHEO P K,LEVINE A K,DEMARIN A J. Relaxation Phenomena in Gases[M]. New York:Maroel Dekker,1971:121-184.

[13] SOUEIKH M,ABDUL GHAIN B. Mathematical modeling of TEA CO2 laser [J]. Opt. & Laser Tech.,1998 (30):451-457