[1] [1] Ruan Chenli, Dong Yuliang. Millimeter Wave They Technology[M]. Chengdu: University of Electronic Science Technology Press, 2013. (in Chinese)

[2] Han Yusheng, Yao Ling, Wang Shuo. Jamming and counter technology of millimeter guidance weapon[J]. Infrared and Laser Engineering, 36, 444-448(2007).

[3] Xiao Qin, Li Yinbo, Li Yan, et al. 8 mm focal flane array imaging technique[J]. Telecommunication Engineering, 48, 97-100(2008).

[4] Qian Chongsong, Li Xinguo. Overview of passive millimeter wave image[J]. Guidance & Fuze, 24, 29-33, 36(2003).

[5] Yin Ximei, Feng Pengpeng. Status and prospect of terminal sensitive technology[J]. Journal of Detection & Control, 39, 1-6(2017).

[6] Nie Jiangying, Li Xingguo, Lou Guowei. Analysis and calculation of coating stealth targets with passive millimeter wave detection system[J]. Opto-Electronic Engineering, 37, 1-6(2010).

[7] Nie Jiangying, Li Xingguo, Lou Guowei. Coating-stealth target radiation transmission characteristics[J]. Chinese Journal of Radio Science, 27, 733-738(2012).

[8] Hu Taiyang, Xiao Zelong, Xu Jianzhong. Method of anti-coating-stealth ground based metal targets by millimeter-wave radiometric detection[J]. Telecommunication Engineering, 50, 1-6(2010).

[9] Xing Yexin, Lou Guowei, Li Xingguo, et al. Millimeter wave passive detection for stealth air target[J]. Journal of Nanjing University of Science and Technology, 35, 289-293(2011).

[10] Zhang Anhua. Study on surface treatment of carbon fiber and its composite material performance[J]. Chemical Management, 31-32(2020).

[11] Li J, Chen X, Wang Y, et al. Burning and radiance properties of red phosphorus in Magnesium /PTFE/Viton(MTV)-based compositions[J]. Infrared Physics & Technology, 85, 109-113(2017).

[12] Chen Minghua, Ma Haimei. Influence of carbon fiber on burning rate infrared radiation intensity of Mg/PTFE infrared composition[J]. Laser & Infrared, 38, 1008-1010(2008).

[13] [13] Li Xingguo, Li Yuehua. Millimeter Wave Shtrange Detection Technology Foundation[M]. Beijing: Beijing Institute of Technology Press, 2009. (in Chinese)

[14] Calcote H F, Keil D G. Ion-molecule reactions in sooting acetylene-oxygen flames[J]. Combust and Flame, 74, 131-146(1988).

[15] Goodings J M, Bohme D K, Chun-Wai Ng. Detailed ion chemistry in methane-oxygen flames. I. Positive ions[J]. Combust and Flame, 36, 27-43(1979).

[16] Chen B, Wang H, Wang Z, et al. Ion chemistry in premixed rich methane flames[J]. Combust and Flame, 202, 208-218(2019).

[17] Dong G, Feng Z, Li L, et al. The effect of electron ambipolar diffusion on the ion current signals in a premixed methane flame[J]. Fuel, 256, 115813(2019).

[18] Fukuyama T, Mukai N, Togawa G. Dynamic behaviours of a flame as plasma in a strong electric field[J]. Scientific Reports, 9, 15811(2019).

[19] [19] Peng Ru. The combustion name radiating millimeter wave radiation mechanism based on pyrotechnic materials[D]. Nanjing: Nanjing University of Science Technology, 2015. (in Chinese)