We deduced a expressions for threshold voltage temperature coefficient of short channel MOST.
推导了了一个短沟道MOST阈值电压温度系数表达式;
Voltage Reference in the design, how to achieve high-precision, low temperature coefficient is a major difficulty.
在基准电压源的设计中,如何实现高精度、低温度系数是一大难点。
The zero reading may also vary as the ambient temperature changes. This effect is usually referred to as the temperature coefficient of the voltage offset.
仪器的零点读数也会随着环境温度的变化而变化。这种效应通常称为电压偏置温度系数。
Therefore, we get the bandgap reference voltage with very small temperature coefficient.
由此得到温度系数很小的带隙基准电压。
However, to be useful, they must be characterized for capacitance value, voltage rating, temperature coefficient, and leakage resistance.
然而,要使用电容器就必须明白其特性:包括电容值、额定电压值、温度系数以及泄漏电阻等。
Positive temperature coefficient (PTC) thermistor and triple frequency harmonic filter can reduce zero sequence voltage when a nonlinear resistance is used to prevent ferroresonance.
在非线性电阻消谐方式下,正温度系数(PTC)热敏电阻和三次谐波滤波器可以较好地解决零序电压偏高的问题。
Bandgap Reference can provide stable voltage with nearly zero temperature coefficient and larger PSRR, and also are process unrelated.
带隙基准可提供近似零温度系数和大的电源电压抑制比的稳定电压基准,且与工艺基本无关。
It USES the traditional principle of bandgap reference together with the self-bias structure and startup circuit to get the stable voltage output and good temperature coefficient.
它利用带隙基准的基本原理,结合自偏置结构以及适当的启动电路,获得了相对稳定的电压值以及较好的温度系数。
Based on the basic principle of bandgap reference, design a high precision, high power supply rejection ratio (PSRR) and low temperature coefficient (TC) bandgap voltage reference.
基于带隙基准的基本原理,设计了一种高精度、高电源抑制比(PSRR)、低温度系数(TC)的带隙基准电压源。
Based on the basic principle of bandgap reference, design a high precision, high power supply rejection ratio (PSRR) and low temperature coefficient (TC) bandgap voltage reference.
基于带隙基准的基本原理,设计了一种高精度、高电源抑制比(PSRR)、低温度系数(TC)的带隙基准电压源。
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