Analysis and Application Research on Baseband Code Characteristics of Inductive Setting System for Smart Ammunition

doi:10.3969/j.issn.1000-1093.2016.06.005

Abstract

Abstract: In order to meet the requirements of large amount of data, high transmission rate, high reliability of smart ammunitions, and realize the data setting of smart ammunitions, 6 baseband coded formats, such as unipolar non-return-to-zero code, unipolar return-to-zero code, Miller code, Manchester code, mark inversion code and modified miller code, are theoretically analyzed and simulated from three aspects of inductive setting system, such as energy transmission efficiency, power spectrum and bandwidth, and the influence of symbol synchronization on bit error rate, and are compared with the experimental results. The simulation and experimental results show that the modified Miller code with low level gapfactor=0.3 has the better energy transmission efficiency, abundant clock timing information, and lower bit error rate, and it is suitable for the transmission channel; the Manchester code is a kind of self-synchronous phase encoding code, which has a relatively rich clock timing information and a very low bit error rate, and it is suitable for the feedback channel. The laboratory experimental results are consistent with the theoretically simulated results.

Key words: ordnance science and technology, smart ammunition, fuse inductive setting, baseband code, energy efficient transmission, power spectrum density, bandwidth, symbol synchronization error, bit error rate

CLC Number:

V211

CHANG Yue, SHEN Xiao-jun, LI Jie, HU Jun-ming, ZHANG Feng. Analysis and Application Research on Baseband Code Characteristics of Inductive Setting System for Smart Ammunition[J]. Acta Armamentarii, 2016, 37(6): 996-1005.

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