微分增益

Parameter RESOLUTION Offset Error Gain Error Differential Nonlinearity Integral Nonlinearity TEMPERATURE DRIFT Offset Error Gain Error POWER SUPPLY REJECTION RATIO ANALOG INPUTS1 Differential Input Voltage Range Differential Input Resistance Differential Input Capacitance Input Bandwidth VSWR 2 POWER SUPPLY 3 Supply Current IAVCC (AVCC = 5.0 V) IEVCC (EVCC = 3.3 V) IVDD (VDD = 3.3 V) Total Power Dissipation 4

参数解决方案偏移误差增益误差微分非线性积分非线性温度漂移偏移误差增益误差电源抑制比1模拟输入；差分输入电压范围差分输入电阻电容输入带宽差分输入电压驻波比2电源3电源电流IAVCC（AVCC = 5.0五）IEVCC（EVCC = 3.3伏） IVDD（VDD的= 3.3伏）总功率耗散4

The calculation of relative variation of the negative feedback amplifier by differential method results in some errors under certain condition, so there was certain limitation in this method.

摘要利用求微分的方法计算负反馈放大器增益的相对变化量，由于在一定的条件下计算出的结果存在一定误差，因而使用这种方法具有一定的局限性。

The peak time detecting circuit which is composed of full-wave rectification circuit and differential circuit can detect the reach time of echo signal accurately.

采用时间增益补偿技术，补偿超声波在空气中的衰减，减少回波信号的起伏；由有源全波整流电路和微分电路等组成峰值时间检测电路，可正确检测回波的峰值到达时间。

Based on a graphical stability criterion in parameter space, the range of proportional-gain is given.

基于参数空间的图解稳定性准则，在已知比例增益范围的前提下，针对稳定和不稳定开环对象，直接在积分-微分参数空间绘制和确定稳定区域，避免了复杂的数学计算。

Measurement results indicate that, by changing the control bits in the gain control circuit and differential circuit, the 3-step peak-to-peak voltage amplitudes are 240, 170 and 115 mV and the center frequency of the impulse can be tuned from 3.2 to 4.1 GHz.

测试结果得到通过改变增益控制和微分电路中的控制位，3级输出脉冲电压峰峰值分别为240 mV、170 mV和115 mV，频谱中心频率可调范围为3.2 GHz 至4.1 GHz。

It is quick and precise in measuring and getting the analysis results,displays the parameters of phase and amplitude value of signals in imaging way,and has friendly man-machine interface,and all of these offer an intuitive and convenient means for the real-time monitoring and the analysis of the parameters of differential gain distortion and differential phase distortion in video chroma vector signals.

形象地显示信号相位、幅值等参数的方式和友好的人机界面的设计，为实时监控、分析色度矢量信号的微分增益失真和微分相位失真等参数，提供了直观、便捷的测量手段。

Under the assumption that a differential Riccati equation is solvable, an exponential reduced-order observer is developed by means of coordinate transformation and the gain matrix of the proposed observer depends on the solution of the differential equation.

在一微分Riccati方程有正定解的前提下，通过坐标变换方法对该类系统提出了一种指数型降维观测器设计方法，该观测器的增益矩阵取决于微分Riccati方程的正定解。

Based on a graphical stability criterion in parameter space, the range of proportional-gain is given. For both stable and unstable open-loop plants, the stabilizing region in integral derivative space is plotted and determined directly, not to be calculated mathematically.

基于参数空间的图解稳定性准则，在已知比例增益范围的前提下，针对稳定和不稳定开环对象，直接在积分－微分参数空间绘制和确定稳定区域，避免了复杂的数学计算。

The relationship between the error signal and gain parameters of PID controller is nonlinear, and , a normal controlled system＇ s step response figure , under the condition of ideal change of the three PID gain parameters in the different time , PID con troller.

但是，目前使用的PID控制器大多仍是传统的线性PID 控制器，其控制信号是通过将参考输入与被调节量的偏差及其微分、积分进行简单的线性组合来生成的，而且PID控制器的增益参数在系统动态响应过程中是固定不变的，不能反映偏差信号的变化l2j。

When applying this model to build movement differential equation and deduce the stable oscillation angular velocity gain formula, existing literature has made many hypotheses, neglection or simplification, which have many insufficiencies.

现有文献在应用该模型建立运动微分方程并推导稳态横摆角速度增益公式做了许多假定、忽略或简化，有很多不足。

DET detector：探测器,检波器

DEMOD demodulation解调 | DET detector探测器,检波器 | DG differential gain微分增益

DG：微分增益

如微分增益(DG)、微分相位(DP)、色度和亮度信号的交调失真,色度增益的非线性失真,色度和亮度的增益差与时间差. 编码后视频信号本身也易于失真,由于色差信息位与视频频谱的高端,这些高频信号需有高放大倍数,

differential galvanometer：差动电流计

differential gain 微分增量微分增益 | differential galvanometer 差动电流计 | differential gap 中间区

differential galvanometer：差动检流计,差动电流计

differential gain 微分增益 | differential galvanometer 差动检流计,差动电流计 | differential gap 切换差

KP：比例增益

答:比例增益(KP)值太高或PID扫描时间(TS)太长(对于快速响应PID的回路),可以降低增益(Gain)值或选择短一些的扫描时间. 2)没有微分,可能是增益(Gain)值太高

magnification：放大倍数

放大倍数(Magnification):表示被摄物与图像之间的尺寸差异的数字. 通常以焦距为1英寸镜头和靶面尺寸为1英寸的传感器为基准(放大倍数=M=1). 焦距为2英寸的镜头的放大倍数为M=2. 微分增益(Differential gain):当载有 3.58 -Mhz 彩色次载波的图像信号从消隐电平变成白色电平时,

infinite voltage gain：无穷大电压增益 feedback component 反馈元件

phase reversal 反相 | infinite voltage gain 无穷大电压增益 feedback component 反馈元件 | differentiation 微分

derivative action time：微分作用时间

derivative action gain,微分作用增益 | derivative action time,微分作用时间 | derivative differential thermal analysis,导数差示热分析

derivative action time：微分作用时间,微分动作时间

derivative action gain ==> 微分作用增益 | derivative action time ==> 微分作用时间,微分动作时间 | derivative control ==> 导数调节

deriatie action time：微分作用时间

deriatie action gain,微分作用增益 | deriatie action time,微分作用时间 | deriatie differential thermal analysis,导数差示热分析