I was searching the practical connection of system response so long. Really glad to see this amazing video. Thank you very much for connecting theoretical concept with practical example..!!
Thanks Brian. For a second order system, you can find in one of your references (Lecture 21) that you'll introduce overshoot by choosing zeta < 1, which corresponds to having two complex conjugate poles. For zero overshoot, the poles must both be real, with the smallest rise time achieved when they are coinciding (zeta = 1, the critically damped case). What would you derive for the pole locations of a higher order system if zero overshoot (or ultimately, critical damping) was a requirement?
Terrific series, Brian. A criticism on this video--you could have mentioned overdamped conditions if zeta gets too large. Good vs worn out shock absorber analogies work well conveying the idea.
Hi, thanks for the video, it's very helpful. I have a question, when you are doing the step response of the closed loop, with what parameters is the PID working (kp,ki,kd)?
I have to solve a control problem, I have a closed-loop transfer function and I should find natural frequency, damping ration and peak overshoot, my transfer function does not exactly look like a second order form, it is (4s+24)/(s^2+8s+24) so what should I do? and I also should find C(t) for unit step input.
Can anybody solve my querry.....stepinfo command give different info and same values from bilevel measurment given diff value of overshoot settling time....why...which should we consider
How is Brian able to explain these concepts so succintly? Thank you, Sir.
Brian is always here to help. Thank you once again, you are saving many lives.
I see Brian, I click!!
Thanks!
Same. Saw notification on phone, opened PC right away.
@@BiancaDianaT are you an engineer?
@@hunainaghai3342 no, we use Step Response of the system in our Ceramic Art classes
@@BiancaDianaT wow. I didn't know that it's used in ceramic art classes. Do you study mathematics?
a hidden gem, thank you mathworks, and Brian!
Brian you did an excellent job explaining the step response. Also thank you for the two links in the description.
I was searching the practical connection of system response so long. Really glad to see this amazing video. Thank you very much for connecting theoretical concept with practical example..!!
❤So helpful! Really brings the concepts around step response together and gives some practical intuition for the math. Thank you!
Thanks Brian. For a second order system, you can find in one of your references (Lecture 21) that you'll introduce overshoot by choosing zeta < 1, which corresponds to having two complex conjugate poles. For zero overshoot, the poles must both be real, with the smallest rise time achieved when they are coinciding (zeta = 1, the critically damped case). What would you derive for the pole locations of a higher order system if zero overshoot (or ultimately, critical damping) was a requirement?
Really well explained! Kudos
Great Brian, there is no one explains control as you do. I wonder what circumstances produced such a product !
Terrific series, Brian. A criticism on this video--you could have mentioned overdamped conditions if zeta gets too large. Good vs worn out shock absorber analogies work well conveying the idea.
Sir, how do you plot this one? 13:48
Thank you Uncle Brian. You are the bes.
Hi, thanks for the video, it's very helpful. I have a question, when you are doing the step response of the closed loop, with what parameters is the PID working (kp,ki,kd)?
Is that possible the settling time of the underdamping faster than critical damping
great video............hats off Sir...God bless
Hello, maybe I’m mistaken. But I think you have the high pass and low pass filters flipped?
I don't see where I did. Could you provide a time stamp and I'll check it out? Thanks!
I have to solve a control problem, I have a closed-loop transfer function and I should find natural frequency, damping ration and peak overshoot, my transfer function does not exactly look like a second order form, it is (4s+24)/(s^2+8s+24) so what should I do? and I also should find C(t) for unit step input.
You can get help from MATLAB Answers if you post your question there. www.mathworks.com/matlabcentral/answers/index
I mean there could be no one who can dislike this video
doesn't matter nowdays does it
Another awesome video
Do you have the same video about frequency requirement?
bless this man it all makes sense
is it possible to have a improper function as the system ?
Can anybody solve my querry.....stepinfo command give different info and same values from bilevel measurment given diff value of overshoot settling time....why...which should we consider
Brilliant! Huge thank you
plot the step response to a 10° ???????? Pls 😢😢😢
Thank you Sir
Thank you 🌹
This is awesome
Thank you!
Amazing as usual, keep talking :))
I want to explain pid controller
Thank You
I am a fan! Go eagles!
Wao. Thank you very much!