第三部分是对偏置电路的设计与测试。
设计了信号偏置电路和伺服阀驱动电路。
Designing the sign transfer board and the driver board of electric and hydraulic servo mechanism.
偏置电路采用自举基准源,具有良好的电源抑制比。
A bootstrap MOS circuit is introduced for bias, which shows a good performance in power supply reject ratio.
利用径向传输线理论对微波有源网络的扇形偏置电路进行了分析。
The analysis of sector bias circuit for microwave active networks is made by means of the theory of radial transmission line.
该功率放大器同时包括动态控制偏置电路和完全集成的功率检测器。
The power amplifier contains dynamic control bias circuits and a fully integrated power detector.
半导体集成电路具有静电型致动器、检测电路、存储电路及偏置电路。
A semiconductor integrated circuit comprises an electrostatic actuator, an estimation circuit, a storage circuit and a bias circuit.
本文介绍了一种扇形微带宽频带的短路元件的设计方法及其在偏置电路中的应用。
This paper describes a design method of microstrip elements with wide-band short-circuits, and their applications in the bias circuits.
电路运用带隙温度补偿技术,采用共源共栅电流镜,两级运放输出用于自身偏置电路。
The technology of temperature compensation and cascade current mirror was used, and the output of two stage amplifier was used for the bias of itself.
接收电路设计给出了完整的解决方案,解决了高压偏置电路、前置放大器的设计等技术难题。
A complete solution was given in the receiving circuit design to solve the technical problems such as high-voltage bias circuit and the pre-amplifier design.
因此介绍了一种采用自偏置低压共源共栅电流源的带隙基准电路结构,用两个电阻代替了偏置电路。
This paper introduces a low supply voltage band -gap reference circuit which used a self-bias cascode current mirror.
上述偏置电路根据上述存储电路存储的上述检测结果,使用于驱动上述静电型致动器的驱动电压变化。
The bias circuit changes, on the basis of the estimation result stored in the storage circuit, a drive voltage to drive the electrostatic actuator.
导出了扇形阵偏置电路的目标函数,此目标函数用于计算机辅助设计宽带微带偏置电路,取得了很好的效果。
The objective function of the sector array bias circuit is constructed, which is applied to CAD of the broad-band microstrip bias circuit with a good result.
许多文献都对这种自适应偏置技术进行了研究,然而,对于多种自适应线性化偏置电路比较和分析的文章尚未见报道。
Many papers have focused on the research of these adaptive bias circuits, but none has reported on the comparison and analysis of these bias circuits.
最后针对S波段接收机前端设计了偏置电路,并按LTCC工艺要求对该接收机前端进行了布局布线和最后的仿真验证。
Finally, bias circuits are designed for the S-band radar receiver LTCC module, the layout and simulated validation are carried out with the LTCC technics requirement.
其设计特点是采用了共源共栅电流镜,运放的输出作为驱动的同时还作为自身的偏置电路;其次是采用了带隙温度补偿技术。
The cascade current mirror was used in the circuit, and the output of the OPAMP was used for the bias of itself and to drive the next stage.
基准源模块广泛的应用于模拟和混合电路中,如A/D、D/A转换器,电压调谐器,电压表,电流表等测试仪器以及偏置电路。
Reference sources are widely used in analog and mix-mode circuits, such as A/D, D/A converters, voltage regulators, measurements, instrumentation circuits, and bias circuits.
该运放采用了折叠式共源共栅放大结构、连续时间共模反馈电路以及低压宽摆幅偏置电路,以实现在高稳定性下的高增益带宽、大输出摆幅。
A new CMFB circuit is used to stabilize the common mode level of the output; Effected measures are used to constrain the wing of the output of the pre.
本文重点进行了光模块主要的电路包括传输线、LD偏置电路与APC电路、低噪声高线性射频电路、FSK调制与解调功能电路与监视控制功能电路的设计。
The module design contains transmission line, bias and APC circuit of LD, low noise and high linearity RF circuit, FSK modern, monitor and control circuit design and PCB layout.
仪器内部电路和内部的偏移电压会在仪器的输入端引起输入偏置电流。
The input bias current flows at the instrument input due to internal instrument circuitry and the internal bias voltage.
完成电路连接之后,接通偏置电压,在没有离子束电流的情况下进行电流测量,以验证系统能够正常工作。
After the connections are made, verify the system is working properly by turning the bias voltage on and taking a current measurement with no ion beam current.
此限幅放大器由输入缓冲、主放大单元、输出缓冲、偏置补偿电路四部分组成。
This limiting amplifier composed of an input buffer, amplifier cells, output cells, and offset cancellation circuit.
虽然输入偏置电流是这种误差的常见来源,但是外电路产生的电流在源电阻上形成的电压降也能引起误差。
Although input bias current is a common source of this type of error, currents generated by external circuits can also result in errors due to voltage drops across the source resistance.
这些误差源包括热电动势、由射频干扰(RFI)经过整流而产生的偏置量以及电压表输入电路中的偏置量。
These sources include thermoelectric EMFs, offsets generated by rectification of RFI (radio frequency interference), and offsets in the voltmeter input circuit.
然而,电路中的若干误差源可以引起非零的电压偏置量。
However, a number of error sources in the circuit may be seen as a non-zero voltage offset.
提出了一种能够自产生基准电压和偏置电流,并且锁定阈值电压和迟滞量稳定的新型欠压锁定电路。
A novel under-voltage lockout circuit is proposed which could generate reference voltage and bias current itself, and could stabilize lockout threshold voltage and hysteresis quality.
随着电子技术的飞速发展,模拟信号的调整电路可以通过超量化输入信号,并且利用DSP调整增益和偏置的方法来实现。
According to the high-speed development of electronic technology, the adjust circuit of analog signal can be accomplished by the over quantization input signal and using DSP for gain and offset.
记住校准算法需要每个电路的增益和偏置特性。
Remember that calibration algorithms require gain and offset characterization for each circuit.
记住校准算法需要每个电路的增益和偏置特性。
Remember that calibration algorithms require gain and offset characterization for each circuit.
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