阴极是真空微电子器件的核心部件之一。
Cathode is one of the core components of vacuum microelectronic devices.
阐述了真空微电子触觉传感器的工作原理。
This paper describes principle of vacuum micro electron tactiles sensor.
介绍了真空微电子中金属尖阴极的制备方法。
This paper describes the method of metal tip fabrication for vacuum microelectronics.
提出了一种带过载保护功能的真空微电子压力传感器。
A vacuum micro-electronics pressure sensor with the function of overloading protection is brought forward.
阐述了真空微电子压力传感器阵列的工作原理和工作波形。
The working principle and working wave shape of the vacuum micro electronic pressure sensor is described.
提出和完成了自保护功能的真空微电子压力传感器的结构设计。
The design of overload protection is put forward in the vacuum micro electronic pressure senor.
本文介绍了真空微电子器件场发射金属尖阵列阴极的制备工艺技术。
This paper describes a fabrication technology of metal tip field emission arrays (FEA) for the vacuum microelectronic devices.
研究了真空微电子压力传感器的力学和电学特性、传感器结构及相应的计算与模拟。
The mechanical property and electricity property of the vacuum micro electronic pressure sensor is studied and relevant computation and simulation are carried out.
场发射阴极作为各种真空微电子器件的核心,其性能的好坏将直接决定着场发射器件的总体性能。
The whole performance of device depends on the capability of field emitting cold cathodes which act as the kernel of all kinds of vacuum micro-electronics device.
采用许瓦兹-克里斯托福变换,求得了以椭圆锥为发射体的真空微电子二极管区域的电位分布的解析解。
In this paper, a conformal mapping analysis of a vacuum microelectronic diode is presented, which uses an elliptic cone conductor as its cathode.
真空微电子器件相对于半导体器件来说,有着更高的工作频率和输出功率,正常工作温度范围也相对较大。
Compared with semiconductor devices, vacuum microelectronic devices can work with higher frequency and larger power at a wider range of temperature.
场发射阵列阴极(FEA)作为真空微电子学的核心内容,其性能的好坏直接影响着场发射器件的总体性能。
As the core content of vacuum microelectronics, the performance of field emitter array (FEA) directly influences the whole performance of field emission device.
本文介绍了利用半导体硅材料制作的真空微电子器件的核心部件,场致发射硅锥阴极,的工艺研究及实验结果。
A process for the fabrication of Si cone cathode for the build up of vacuum microelectronic devices is proposed and its experimental results are given.
以场致发射理论为基础的真空微电子器件,因其具有功耗低、电流密度大、频率高等诸多优点而倍受人们关注。
Vacuum micro-electronics devices, which are based on field emission theory, are more and more widely applied, because of their low power consumption, high current density and high frequency.
本文介绍了我们最近开发的真空微电子平板数码管工艺,主要包括阳极支柱(阵列)的制作和平板透明真空封装。
The process developed recently for vacuum microelectronic flat-panel nixie is introduced, including mainly how to fabricate the anode pillars(array)and the transparent flat-panel vacuum packages.
简要介绍场致发射与真空微电子的一般情况,尔后着重介绍应用真空微电子原理制作的场发射平板显示器(FED)。
After a brief introduction to field emission and Vacuum microelectronics, the author focuses on field emission display (FED), which is made according to principle of Vacuum microelectronics.
简要介绍场致发射与真空微电子的一般情况,尔后着重介绍应用真空微电子原理制作的场发射平板显示器(FED)。
After a brief introduction to field emission and Vacuum microelectronics, the author focuses on field emission display (FED), which is made according to principle of Vacuum microelectronics.
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