I will go ahead and say it , this has taught me more than 15 hours of binge studying and watching lectures. I love you so much for this! Thank you!

This half-hour video is a better PID design video than my prof's 10 hours of lectures.

Thank you very much MAAM for your service, much appreciated. God bless

You are a savior I spent almost a full day trying to figure this out. Thank you so much !!! This was EXACTLY what I needed haha. You're the best!

You make root locus design easy. Great lessons. Thank you very much!

hi, i'm from brazil !!! very clear and ellegant way of describing and solving the problem, very thankful for this video !

Absolutely perfect pure education.. I cannot thank you enough. God bless you

I am so grateful for finding this video, as I've been seeking for awnsers to this specific case and exercise! Thanyou really much for producing such great content and videos!!

Thank you so much for your efforts, I completed successfully my final exam thanks to you

Im a girl and I think your voice is sooooo cute and soothing! And youère a great professor too! From Canada!

You save my day. I nailed a really harsh test thanks to you!!!

more useful than my professor that said teaching is a passion for him

you are a life saverrrrrr, My teacher just says draw by scale and use a ruler to guess haha

I Don't know how many times I have to say thank you 🙏. THANK YOU 😊

Love from VN

Great effect at 8:28 - 8:34

Your voice and explanation are perfect! Ty so much

Thanks for your videos! Very clear explanation and u answered all of my questions :)

Thank you so much! watched pretty much all your videos and I cannot thank you enough!!! :D

I really loved you. You did save my life

Perhaps you can make a similar video for a unit ramp response as well? This was super helpful thank you

Final tomorrow, you are the greatest

Incredible explanation, Thank you very much.

i just love it. great work.. wanna more videoes.. ♥ from Bangladesh

Really good explanation! Ty

Just wanted to say: Thank you

May I know how would you get the angle of the poles if the poles are complex numbers such as -1+1.73i. Is is still the same as imagining a horizontal line on the pole and calculating its angle anticlockwise?

This is great! Thank you

you just saved my life

Amazing video! Thank you so much

Very well explained. Thank You

Hi if you're still responding to comments on this video, i'm in a situation where i have to tune a PI controller of a third order system. using the dominant poles method, this had first order dominance and so was reduced to only one OL pole in the raw root locus. Question 1: will i need to add another pole to this in the design as it doesn't break away as the desired poles are in the complex plane? Question 2: Is there any way to just tune a PI controller from this or would it have to be PID with the need to place a zero someplace to the left of this to allow it to pass through the desired CL poles. Thanks.

please make video for complex poles as well

and the desired pole answer is 40 . . . 2 (hitchhiker's guide to the galaxy) quote

Thank you so much for such nice explanation!! Can u pls tell what this method is called? Pole placement method or something else?

We need more videos like this! Thank you very much ^.^

Thank you very much for sharing! I was wondering if this can be used for third or higher order systems. Also, how would affect having a pre-compensator. Thanks again!!

thanks you saved my life

Thanks! From 🇸🇦

Thank you thank you thank you❤😍❤😍❤❤❤❤❤i needed this so much,u are an angel😙😘

damn thats a clean video

Isn't it required to close the loop prior to the maths? Sometimes it gets really confusing wheter or not the system should be in close or open loop. Very nice example, though.

You two look really good :-)

I am from India, thanks you very much

How did you take the desired poles @ -40+- 42 i , that is confusing for me.

Hello, great video. Why didn't you solve another angle for the pole at zero?

How would you separate the PI and PD controller processes? Such as when just designing a PI controller with no settling time but given a steady-state error due to a step percentage?

Thank you so much.

Does anyone know what 'In' for zeta equation is? 1:46

Mam for implementation in simulink we need kp,pi and kd.for this we need to calculate these parameters.Can you plz help me, how to calculate the kp,ki and kd value from the derived pid equation.

So how would you find the desired/dominant poles for the PID controller after getting the location of all poles and zeros? I tried to use the angle condition, but I am not getting the correct values.

what if we only have damping ratio? will we use hit and trial method to find Wn or is there any other way?

Excellent !!!!

is it for open loof system?? not close loof?

What does the equation you're writing for zeta say? The one where you include the overshoot.

amazing!

do you have a video where you do this example ( or similar) with the characteristic eqn and the K = 1 / GH ???

It didn't work for my system. 492.61e6 / (s^2 + 10^3s + 12.195e6) I wonder why?

Can you use this for a first order system?

hi ma'am what happened to the single 's' at the denominator s(s+1)(s+2) @11:07 when solving for the angles? Thanks!!

You’re the real MVP 😤

what if ive got 16/S^2 + 0.2S +1 as my plant transfer function? my roots will be -0.1+-0.995i

Amazing! :)

incredable

why you put a-42 for theta 1 and the ones before you put 40 -1 and 40 -2?

is there a way to decrease that 17% overshoot to 5%? because that is our requirement.

Please, why you put two zeros? How did you know it was going to be two zeros? I've seen methods that use only one zero and one pole. Are there different ways of doing thae same PID design?

Why there is nothing very interesting information during most replayed part ??

hello may i ask how to find desire pole for 3rd order system? :(

thank you

3 hours left for my final I got the basics now or never if I will understand this video I can maybe pass that shit

GJ

thank you mam :*

thanks for posting the video some doubts I have can you share your contact info

I find a gold 🥇

why cant you write clear :) ,cant understand what have you wrote ? when you calculated zeta from max overshoot of 5 %.

This video doesn't reflect reality. It is easy to make formulas have a settling time of 0.1 seconds, but the control output is limited so the control output will saturate. The response will not be as desired. In reality the controller and amplifier only have so much power. The zeros are creating the overshoot. The zeros can be eliminated by having the PID gains act on the changes in the actual state only, not the error. Zeros can be placed too.