Welcome to our site! EDAboard.com is an international Electronics Discussion Forum focused on EDA software, circuits, schematics, books, theory, papers, asic, pld, 8051, DSP, Network, RF, Analog Design, PCB, Service Manuals... and a whole lot more! To participate you need to register. Registration is free. Click here to register now.
Connect the op-amp to unity-gain configuration. Input a square wave signal and run transient analysis. The settling time is where your output square waveform start to rise until it settle to constant level. Settling time shows how fast your op-amp can react for a given input. For higher frequency operataion the op-amp should have fast settling time.
Connect the op-amp to follower configuration. Input a square wave signal (insure it is a small signal and the opa is in the linear region )and run transient analysis,plot the out wave. Pls see the picture!
Connect the op-amp to follower configuration. Input a square wave signal (insure it is a small signal and the opa is in the linear region )and run transient analysis,plot the out wave. Pls see the picture!
What you mean by saying a small signal and the opa is in linear region. Do you mean that the input pulse signal need to be small swing (and not as like rail to rail in the slew rate measurement) and the linear means keep the opamp in saturation?
You always gives a good explanation with pics, that is good. Keep it up.
What you mean by saying a small signal and the opa is in linear region. Do you mean that the input pulse signal need to be small swing (and not as like rail to rail in the slew rate measurement) and the linear means keep the opamp in saturation?
Linear means the out of opa have the same shape as the input of opa and the output transistor of opa is operating in amplify region. Pls see the transfer characteristic of opa.
This site uses cookies to help personalise content, tailor your experience and to keep you logged in if you register.
By continuing to use this site, you are consenting to our use of cookies.
