139N. High frequency: transfer functions, lower pass and high pass response.
HTML-код
- Опубликовано: 23 дек 2024
- Analog Circuit Design (New 2019)
Professor Ali Hajimiri
California Institute of Technology (Caltech)
chic.caltech.ed...
© Copyright, Ali Hajimiri
@46:00 the correct expression is: p1~ -1/b1 and p2~-b1/b2.
it's out of topic but, this video is uploaded on 21 Mar 2019, how this comment can be done "2 weeks ago"?? Before publishing it! I'm confused!
It was written at the time of original upload, not the time of public release.
The best mathematical interpretation of electronics. I wish there were lecturers like him back the times I was undergrad. Thanks a lot for the useful content
Thank so much sir. I wish many professors can teach like you. God bless you and your family.
@42:20 the expresssion for b2 after dominant pole approx. , that seems dimenionally inconsistent ryt? in the expression derived for general purpose its of the form 1/PiPj and after approx is (p2/p1) which doesn't have any dimension .
I have the same wonder. It does not match the general expression of b2 = sigma sigma (1/PiPj)
From 8"10 ~ 9"10, you are explaining time invariance through system causality; these are two different concepts. Anyway, the course is very good, congrat!
Hello Professor. Quick question. What is the proof that our coefficients a & b are real? Thanks!
Can't wait to go back and study Volterra Series.
Very good explanation 👍
@15"04, The expression : H(s) = L{h(t)} is true if the Initial conditions (IC) are equal to zero.