每一单元储存不多于一个单一电荷储存状态。
Each cell stores no more than a single charge storage state.
目的:研究紫外消毒对驻极体电荷储存稳定性的影响。
Objective: To investigate the effect of ultraviolet radiation on the stability of electret storing electric charge.
因此,合理地调控薄膜厚度,可以有效地优化驻极体的电荷储存能力及电荷稳定性。
Therefore, the charge storage capability and charge stability can be optimized by reasonably regulating the thickness of the sample.
实验结果表明,经过化学表面修正后,驻极体薄膜在高湿环境中的电荷储存稳定性显著提高;
The results show that the charge storage stability of film electret increases remarkably in high humidity surroundings after chemical surface modification.
结果显示,ETFE薄膜驻极体具有优良的电荷储存稳定性,负极性ETFE的电荷稳定性明显优于正极性样品。
It is found that the charge stability of ETFE electret is very good, and the stability of negatively charged ETFE is much better than that of positively charged ETFE.
具有栅极的二极管非易失性存储单元,其具有电荷储存结构,包括具有额外栅极端的二极管结构、与位于二极管节点之间的扩散阻挡结构。
A gated diode nonvolatile memory cell with a charge storage structure includes a diode structure with an additional gate terminal and a diffusion barrier structure between the diode nodes.
电容会在一个给出的电压值下储存一定的电荷。
For a given voltage a capacitor will store a certain amount of charge.
当导体有电压差值时,电荷就能被储存。
If there is a voltage difference between these conductors, electric charge is stored.
超级电容中分离电荷之间的距离越小,形成电场的越大,储存能力也就越大。
The shorter distance between those separated charges in an ultracapacitor translates to a larger electric field—and much more energy storage capacity.
振荡频率由电容储存电荷的能力,以及线圈生成磁场的能力所共同决定。
The frequency of this oscillation is controlled by the capacitor's ability to store charge and the coil's ability to produce a magnetic field.
组合后的衣服不仅可以储存很多电荷,还可以在多次使用后,依然保持它放电以及充电的能力。
The resulting cloth not only stores a lot of charge, it also retains its ability to discharge and recharge itself over many cycles of charging and discharging.
为了尽量减小这种效应产生的电流,重要之点在于消除绝缘子上的机械应力并使用压电效应和储存电荷效应最小的绝缘材料。
To minimize the current due to this effect, it's important to remove mechanical stresses from the insulator and use insulating materials with minimal piezoelectric and stored charge effects.
在实际工作中,区分储存电荷效应(在绝缘体中)和压电效应可能是相当困难的。
In practice, it may be quite difficult to distinguish stored charge effects (in insulators) from piezoelectric effects.
本文通过分析电荷控制方程得到了更精确的表达式,并用这种方法计算了储存电荷法的公式。
This paper obtains a more accurate expression by analyzing charge-control equation and calculates expression of stored charge.
为了能储存大量电荷,电容器通常用大面积的金属板来制造。
Usually the capacitor is made up of plates of large area so that large electrical charges may be stored.
压电或储存电荷效应:由于机械应力产生的电荷不平衡(从而产生了电流或电压偏置)。
Piezoelectric or stored charge effects: the creation of charge unbalances (and thus current flow or voltage shift) due to mechanical stress.
由于电荷耦合组件能够储存电荷,它们可以当作记忆装置,但比随机存取内存慢。
Because they can store electrical charges, CCDs can be used as memory devices, but they are slower than RAMs.
任何储存电荷的装置都叫电容器。
Y device that stores up electric charge is called an electric capacitor.
第16周点电荷系的能量;带电电容器储存的能量;电场的能量和能量密度;应用举例。
Week 16 Energy of point charges system, energy of electric field in capacitor , energy and its density of electric field.
与电压测量不同,电荷测量可能是破坏性测量,换言之,进行测量的过程可能会消除被测器件中储存的电荷。
Unlike a voltage measurement, a charge measurement can be a destructive measurement. In other words, the process of making the measurement may remove the charge stored in the device under test.
在读取操作期间,该读取晶体管被激活以产生指示储存在该浮置栅极节点中的电荷的输出信号。
During a read operation, the read transistor is activated to produce an output signal indicative of the charge stored in the floating gate node.
当存储器单元结构的其它部分储存不相关的信息时,读取作业将不同部分的电荷捕捉结构之间的耦合减少。
When the other parts of the memory cell stores irrelated information, read operation reduces the coupling between charge capturing structures of different parts.
当存储器单元结构的其它部分储存不相关的信息时,读取作业将不同部分的电荷捕捉结构之间的耦合减少。
When the other parts of the memory cell stores irrelated information, read operation reduces the coupling between charge capturing structures of different parts.
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