核电子仪器及其抗干扰设计
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摘要
随着我国当前社会发展进程的不断加快,各项新型技术的不断创新和研发,核电子仪器设备也得以广泛运用。针对核电子仪器设备来讲,确保其运用可靠性,是针对电子仪器设备的工作性能加以衡量的关键指标。确保核电子仪器设备的可靠性,更是确保其能够实现精准数据测量的关键。由此本次研究展开对核电子仪器及其抗干扰设计的研究,着重探究电子仪器运用抗干扰,提出进一步电子仪器抗干扰优化设计策略。
With the rapid development of the current social development process in China,the continuous innovation and research and development of various new technologies,the nuclear electronic instruments and equipment are also widely used.To ensure the reliability of nuclear electronic equipment,it is a key index to measure the performance of electronic equipment.Ensuring the reliability of nuclear electronic equipment is the key to ensure accurate data measurement.In this study,the research on nuclear electronic instruments and their anti-interference design is carried out,and the application of anti-jamming in electronic instruments is emphasized,and the strategy of optimizing the anti-jamming design of electronic instruments is put forward.
With the rapid development of the current social development process in China,the continuous innovation and research and development of various new technologies,the nuclear electronic instruments and equipment are also widely used.To ensure the reliability of nuclear electronic equipment,it is a key index to measure the performance of electronic equipment.Ensuring the reliability of nuclear electronic equipment is the key to ensure accurate data measurement.In this study,the research on nuclear electronic instruments and their anti-interference design is carried out,and the application of anti-jamming in electronic instruments is emphasized,and the strategy of optimizing the anti-jamming design of electronic instruments is put forward.
引文
[1]丁爱峰,廖望,胡胜云,等.某车型电子仪表抗干扰研究与优化设计[J].汽车电器,2016,(9):56-58.
[2]黄华,权金虎,梁耀,等.核电厂辐射环境监测系统的组网技术[J].核电子学与探测技术,2013,(8):972-976.
[3] YAN Hai,LI Guohui,CAO Yuan,et al. Design and Implementation of Radar Anti-jamming Ability Evaluation System[J].Modern Radar,2014,36(5):6-9.
[4]代刚,高平,贾兴,等.纳秒级数字延时同步机的设计与实现[J].高能量密度物理,2012,(1):43-45.
[5]武永鹏,甄国涌,侯卓.弹射试验用地面检测单元长线传输接口的抗干扰设计[J].科学技术与工程,2013,13(26):7847-7850.
[6]许兴明,刘国伟.数字多用表抗干扰能力自动测试装置的设计[J].电子测量技术,2012,35(10):95-98.
[7]林志雄,黄剑航,江永增,等.一种双端固定音叉式天平数字滤波的设计与实现[J].廊坊师范学院学报(自然科学版),2013,13(6):33-36.
[8]林志雄,江永增,黄剑航,等.一种双端固定音叉式高精度电子天平设计[J].贵州大学学报(自然版),2014,31(1):52-56.
[9]黄利荣.电子程序逻辑设计与抗干扰方案[J].电子技术与软件工程,2017,(17):90-91.
[10] ZHANG Yuan,ZHU Kang,LIN Rongsheng. Anti-jamming Circuit Design for Vehicle Reversing Images[J].Automation and Instrumentation,2017,(10):58-59.
[11]张媛.核电子仪器抗干扰设计策略研究[J].军民两用技术与产品,2017,(20).
[12]毛炳妹.电子通信工程中设备抗干扰接地策略研究[J].科技展望,2017,(13).
[13]熊欣,韩大伟.浅谈电子通信工程中设备抗干扰接地措施[J].电子制作,2013(2x):12-12.
[14]曲君国.电子通信工程中的设备抗干扰接地措施探讨[J].中国新通信,2016,18(15):26-26.
[15]徐健.浅析电子通信工程中设备抗干扰接地的有效方法[J].通讯世界,2016,(9):43-44.
[16]刘犁.通信电子设备工程中抗干扰接地措施及应用[J].数字通信世界,2015.
[2]黄华,权金虎,梁耀,等.核电厂辐射环境监测系统的组网技术[J].核电子学与探测技术,2013,(8):972-976.
[3] YAN Hai,LI Guohui,CAO Yuan,et al. Design and Implementation of Radar Anti-jamming Ability Evaluation System[J].Modern Radar,2014,36(5):6-9.
[4]代刚,高平,贾兴,等.纳秒级数字延时同步机的设计与实现[J].高能量密度物理,2012,(1):43-45.
[5]武永鹏,甄国涌,侯卓.弹射试验用地面检测单元长线传输接口的抗干扰设计[J].科学技术与工程,2013,13(26):7847-7850.
[6]许兴明,刘国伟.数字多用表抗干扰能力自动测试装置的设计[J].电子测量技术,2012,35(10):95-98.
[7]林志雄,黄剑航,江永增,等.一种双端固定音叉式天平数字滤波的设计与实现[J].廊坊师范学院学报(自然科学版),2013,13(6):33-36.
[8]林志雄,江永增,黄剑航,等.一种双端固定音叉式高精度电子天平设计[J].贵州大学学报(自然版),2014,31(1):52-56.
[9]黄利荣.电子程序逻辑设计与抗干扰方案[J].电子技术与软件工程,2017,(17):90-91.
[10] ZHANG Yuan,ZHU Kang,LIN Rongsheng. Anti-jamming Circuit Design for Vehicle Reversing Images[J].Automation and Instrumentation,2017,(10):58-59.
[11]张媛.核电子仪器抗干扰设计策略研究[J].军民两用技术与产品,2017,(20).
[12]毛炳妹.电子通信工程中设备抗干扰接地策略研究[J].科技展望,2017,(13).
[13]熊欣,韩大伟.浅谈电子通信工程中设备抗干扰接地措施[J].电子制作,2013(2x):12-12.
[14]曲君国.电子通信工程中的设备抗干扰接地措施探讨[J].中国新通信,2016,18(15):26-26.
[15]徐健.浅析电子通信工程中设备抗干扰接地的有效方法[J].通讯世界,2016,(9):43-44.
[16]刘犁.通信电子设备工程中抗干扰接地措施及应用[J].数字通信世界,2015.