Design and efficient implementation of airborne shock signal process chip based on FPGA

De Rong Chen; Zhi Qiang Li; Xu Ping Cao

Design and efficient implementation of airborne shock signal process chip based on FPGA

De Rong Chen^*, Zhi Qiang Li, Xu Ping Cao

^*Corresponding author for this work

School of Mechatronical Engineering

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Design, implementation and application of a three-channel airborne shock signal process chip based on FPGA is described. Pipeline processing can ensure the time of computing the peak acceleration for a single-degree-of freedom system. It provides good conditions for optimizing the design parameters of the whole device because the power consumption of the device and processing accuracy of MaxiMax Shock Spectrum mainly depend on the sampling frequency, at the same time both are conflicting. After lots of tests, airborne processors with the chip have been applied to several experiments. As a result, bandwidth of shock signals is greatly compressed by processing shock signal on board. In addition signal peak detection error is reduced and measurement dynamic range is extended. Moreover, verification of the data becomes much easier on the ground.

Original language	English
Pages (from-to)	1661-1664
Number of pages	4
Journal	Xi Tong Gong Cheng Yu Dian Zi Ji Shu/Systems Engineering and Electronics
Volume	27
Issue number	9
Publication status	Published - Sept 2005

Keywords

Data process
FPGA
Missile
Shock
Shock response spectrum

Cite this

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AU - Chen, De Rong

AU - Li, Zhi Qiang

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N2 - Design, implementation and application of a three-channel airborne shock signal process chip based on FPGA is described. Pipeline processing can ensure the time of computing the peak acceleration for a single-degree-of freedom system. It provides good conditions for optimizing the design parameters of the whole device because the power consumption of the device and processing accuracy of MaxiMax Shock Spectrum mainly depend on the sampling frequency, at the same time both are conflicting. After lots of tests, airborne processors with the chip have been applied to several experiments. As a result, bandwidth of shock signals is greatly compressed by processing shock signal on board. In addition signal peak detection error is reduced and measurement dynamic range is extended. Moreover, verification of the data becomes much easier on the ground.

AB - Design, implementation and application of a three-channel airborne shock signal process chip based on FPGA is described. Pipeline processing can ensure the time of computing the peak acceleration for a single-degree-of freedom system. It provides good conditions for optimizing the design parameters of the whole device because the power consumption of the device and processing accuracy of MaxiMax Shock Spectrum mainly depend on the sampling frequency, at the same time both are conflicting. After lots of tests, airborne processors with the chip have been applied to several experiments. As a result, bandwidth of shock signals is greatly compressed by processing shock signal on board. In addition signal peak detection error is reduced and measurement dynamic range is extended. Moreover, verification of the data becomes much easier on the ground.

KW - Data process

KW - FPGA

KW - Missile

KW - Shock

KW - Shock response spectrum

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Design and efficient implementation of airborne shock signal process chip based on FPGA

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