1·It is, in fact, one of several op amp myths.
它实际上是,几个运算放大器的神话之一。
2·Q. How does capacitive loading affect op amp performance?
电容负载是如何影响运算放大器的性能的?
3·The output amplitude by adjusting the op amp to complete the feedback factor.
输出幅度通过调节运算放大器的反馈系数完成。
4·This wide input common-mode range is obtained with standard low voltage op amp supplies.
这种宽输入共模电压范围是用标准低压运算放大器电源实现的。
5·In this case, you might want to place bypass capacitors directly on the output of an op amp.
这里,我们通过旁路电容直接在运算放大器的输出端旁路。
6·The low voltage burden (V1) and corresponding fast rise time are achieved by the high gain op amp, which forces V1 to be nearly zero.
电路的低输入端压降以及相应的快速上升时间是由高增益运算放大器实现的。此运算放大器迫使V1接近于0。
7·The earliest IC op amp OUTPUT stages were NPN emitter followers with NPN current sources or resistive pull-downs, as shown in Figure 1.6.
最初的集成运算放大器的输出级是NPN电流源的NPN放射追随器或通过电阻下拉,如图1.6所示。
8·The principle and related technique are also presented to Compensate the finite gain effects of op amp by diminishing negative feedback.
提出了降低负反馈以补偿这些影响的原理及实现方法。
9·For example, choosing the negative rail as the ground reference may optimize the dynamic range of an op amp whose OUTPUT is designed to swing to 0v.
例如,选择负轨作为地参考也许能够优化一个输出可以至0运放的动态范围。
10·A nonlinear model of op amp based on Volterra series theory in complex frequency domain is proposed. The comparison of theory and experiment is given.
本文提出了一个运算放大器复频域非线性模型的建立方法,并且将该方法所建立的运算放大器模型与实验测量的传递函数特性作了比较。