[1] Yunxia LI, Wen MENG, Lihua MA et al. Passive locating technology(2009).

[2] Xiaoning FU, Bingjian WANG, Di WANG. Electro-optic ranging & countermeasure(2012).

[3] Tingzhu BAI. Electro-optic imaging technology and system(2016).

[4] Dapeng WANG, Zhuokun WU, Dongfeng WANG. Principle and technology of infrared countermeasure(2021).

[5] Xiaorui WANG. Electro-optic imaging system: modeling, simulation, tesing and evaluation(2017).

[6] Tong LÜ, Chenwei ZHANG, Jia LIU et al. Research progress in metamaterial absorber. Acta Materiae Compositae Sinica, 38, 25-35(2021).

[7] W LI, W HUANG, X WANG et al. Metamaterial absorbers: from tunable surface to structural transformation. advanced materials, 34, 2202509(2022).

[8] K ZHANG, Z HOU, S BI et al. Modeling for multi-resonant behavior of broadband metamaterial absorber with geometrical substrate. Chinese Physics B, 26, 127802(2017).

[9] F DING, Y CUI, X GE et al. Ultra-broadband microwave metamaterial absorber. Applied Physics Letters, 100, 103506(2012).

[10] Mingbo PU. Study on the broadband frequency response of subwavelength metamaterial(2013).

[11] Han XIONG. Research on the application of electromagnetic metamaterial in microwave absorber and antenna(2014).

[12] X LI, L YU, W ZHAO et al. Prism-shaped hollow carbon decorated with poly aniline for microwave absorption. Chemical Engineering Journal, 379, 122393(2020).

[13] X CHEN, Z WU, Z ZHANG et al. Ultra-broadband and wide-angle absorption base don 3D-printed pyramid. Optics & Laser Technology, 124, 105972(2020).

[14] Y ZHANG, L PAN, P ZHANG et al. Gradient multilayer design of Ti3xC2Tx MXene nanocomposite for strong and broadband microwave absorption. Small Science, 22000(2022).

[15] Z HUANG, H CHEN, Y HUANG et al. Ultra-broadband wide-angle terahertz absorption properties of 3D graphene foam. Advanced Functional Materials, 28, 1704363(2018).

[16] D XIAO, M ZHU, Q WANG et al. A flexible and ultra-broadband terahertz wave absorber based on graphenevertically aligned carbon nanotube hybrids. Journal of Materials Chemistry C, 8, 7244-7252(2020).

[17] X CHENG, R HUANG, X XU et al. Broadband terahertz near-perfect absorbers. ACS Applied Materials & Interfaces, 12, 33352-33360(2020).

[18] Ligang TAN, Mingwei LUO, Jie LI. Wide-band terahertz absorbing structure whit graphene based on dual-scale four separation layers optimization. Journal of Applied Optics, 44, 6-16(2023).

[19] Y X CUI, J XU, K H FUNG et al. A thin film broadband absorber based on multi-sized nanoantennas. Applied Physics Letters, 99, 253101(2011).

[20] Y X CUI, K H FUNG, J XU et al. Ultrabroadband light absorption by a sawtooth anisotropic metamaterial slab. Nano Letters, 12, 1443(2012).

[21] Nan ZHANG. Research on infrared metamaterial absorbers and their thermal eadiation controlling based on surface plamsmon polaritons(2015).

[22] Rui FENG. Study on nearly perfect absorption of infrared periodic micro-structure(2015).

[23] Qizhen WANG. Infrared absorption characteristics analysis for square loop nanostructure of Al substrate(2015).

[24] Y ZHOU, Z LIANG, Z QIN et al. Small-sized long wavelength infrared absorber with perfect ultra-broadband absorptivity. Optics Express, 28, 1279-1290(2020).

[25] Zheng QIN, Zhongzhu LIANG, Xiaoyan SHI et al. Mutimode resonance triple-band metamaterial absorber from mid-infrared to very long wavelengths. Infrared And Laser Engineering, 51, 78-82.(2022).