[1] ZHANG H.Development of ammunition for the demand and promotion of fuze technology [J]. Journal of Ordnance Equipment Engineering, 2018(3): 1-5. (in Chinese)
[4] FAN W M, LIU SH J, WANG L SH, et al..Application of MEMS accelerometer in antiaircraft missile fuze [J]. Journal of Ordnance Equipment Engineering, 2018(3): 75-82. (in Chinese)
[5] MA B H. Control function and characteristics of modern fuzes [J].Journal of Detection & Control, 2008, 30(1): 1-5. (in Chinese)
[6] HUANG D Y, ZHANG SH L. Design of new type of depth bomb fuze arming mechanism [J]. Journal of Ordnance Equipment Engineering, 2017(1): 47-50. (in Chinese)
[7] DEFENSE TECHNICAL INFORMATION CENTER. OSD RDT&E project justification (R2a exhibit) [EB/OL].http: //www.ditc.mil/descriptivesum/Y2012/OSD/0603225D8Z.pdf, 2012.02.
[8] MCENTIRE R S, BUTLER P. Fuzing & firing systems at sandia national laboratories [C]. NDIAs 58rd Annual Fuze Conference, 2014.
[9] JOHN D H. Evolving requirements for the use of logic devices in the implementation of safety features or an update to the DoD Fuze Engineering Standardization Working Groups (FESWG) technical manual for the use of logic devices in safety features [C]. 55th Annua1 Fuze Conference, 2011.
[10] BEAMESDERFER M, CHEN S P, DEVOE D, et al.. Analysis of an optical energy interrupter for MEMS based safety and arming systems [J].SPIE, 1999, 3880: 101-111.
[11] SHAN T Q. Research on the State Control Technology of Fuze Electronic Safety System Based on MOEMS [D]. Shijiazhuang: Ordance Engineering College, 2016. (in Chinese)
[12] BLAIR P, MCMILLAN D, PODLECKI J, et al.. MEMS hybridisation-bridging the free-space gap [J].SPIE, 2001, 4407: 193-201.
[13] TI Q SH, XING L Q. Analysis and design of a high power laser interrupter for MEMS based safety and arming systems [J]. Microsystem Technologies, 2016, 26: 382-401.
