基于现场可编程门阵列与Labview的脉冲电源控制系统设计
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摘要
介绍了基于现场可编程门阵列(FPGA)的等离子体磁约束脉冲电源控制系统的设计与实现。该控制系统采用了虚拟仪器技术、嵌入式控制技术、串行通信技术、光电隔离技术等,提高了系统抗干扰性能以及可编程性,实现了多个脉冲电源模块开关器件间的逻辑互锁、参数设置以及远程监控等功能。控制系统具体由实验室虚拟仪器集成环境(Labview)编写的上位机界面、由硬件语言Verilog HDL编写的下位机以及专用的光电隔离转换电路组成,用于实现多个脉冲电源充放电的时序控制。实验证明了系统在复杂电磁环境下,运行稳定,性能良好。
The design and implementation of pulse power control system for magnetic confinement plasma,using the field programmable gate array(FPGA) technology are presented. Virtual instrument technology,embedded control technology, serial communication technology, and optical isolation technology are used to improve the system's anti-jamming performance and programmability, and to realize logic interlock, parameter setting and remote monitoring among multiple pulse power modules. The control system is specifically composed of the upper computer interface programmed by Labview(Laboratory Virtual Instrument Engineering Workbench),lower-level machine programmed by Verilog HDL(Hardware Description Language) and dedicated photoelectric isolation conversion circuit, which is used to implement timing control of multiple pulse power supply and discharge. The experiment proves that the system is stable and has good performance under complex electromagnetic environment.
The design and implementation of pulse power control system for magnetic confinement plasma,using the field programmable gate array(FPGA) technology are presented. Virtual instrument technology,embedded control technology, serial communication technology, and optical isolation technology are used to improve the system's anti-jamming performance and programmability, and to realize logic interlock, parameter setting and remote monitoring among multiple pulse power modules. The control system is specifically composed of the upper computer interface programmed by Labview(Laboratory Virtual Instrument Engineering Workbench),lower-level machine programmed by Verilog HDL(Hardware Description Language) and dedicated photoelectric isolation conversion circuit, which is used to implement timing control of multiple pulse power supply and discharge. The experiment proves that the system is stable and has good performance under complex electromagnetic environment.
引文
[1]蒋成玺.脉冲强磁场电源系统设计及实现[D].武汉:华中科技大学, 2013.
[2]夏宇闻. Verilog数字系统设计教程[M].北京:北京航空航天大学出版社, 2008.
[3]陈欣波.AlteraFPGA工程师成长手册[M].北京:清华大学出版社, 2012.
[4]陈正涛.光纤HFBR-1414发射器的驱动电路设计[J].国外电子测量技术, 2010, 29(5):79-81.
[5]潘圣民,许留伟,廖燕川,等.高电压强电磁干扰下的电压光纤传输[J].微计算机信息,2008,24(14):273-275.
[6]陈树学,刘萱.Labview宝典[M].北京:电子工业出版社, 2011.
[2]夏宇闻. Verilog数字系统设计教程[M].北京:北京航空航天大学出版社, 2008.
[3]陈欣波.AlteraFPGA工程师成长手册[M].北京:清华大学出版社, 2012.
[4]陈正涛.光纤HFBR-1414发射器的驱动电路设计[J].国外电子测量技术, 2010, 29(5):79-81.
[5]潘圣民,许留伟,廖燕川,等.高电压强电磁干扰下的电压光纤传输[J].微计算机信息,2008,24(14):273-275.
[6]陈树学,刘萱.Labview宝典[M].北京:电子工业出版社, 2011.
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