Obtaining the small signal transfer function of resonant LLC converters by PSIM - revised

Thanks a lot. I tried the simulation in PSIM. It works as you showed. Really beautiful.

Thank you very much for this valuable presentation.

Great video! Thank you for sharing your knowledge!

Thank you for the video. It gives an understanding of control in llc Can you please do video about small signal analysis of llc converter without simulation. The methodology also the background knowledge needed to derive the small signal equivalent off llc when it is frequecy controlled or fixed frequecy duty controlled..The main idea beyond extended describing function.

Thanks for the video! It made me understand what happens when we do a small signal analysis of a converter. Now that the transfer function is determined how would we do the control? On the internet they say the closed loop bode plot should have
-20db/Dec at the crossover frequency and a lot of papers I found just did a control that delivered a bode plot with -20db/Dec for the whole small signal frequency range
It's pretty hard to find a reasonable explanation how to implement the control

Gr8 video, thank you sir.

Dear Sam, thanks a lot for this valuable video, I appreciated a lot. I work in designing of LLC converter since many years, but I focus on resonant tank and I'm not used to design the loop controll, that for LLC seem stronger than others converters topologies. I have a question that coming out from your sentence at 5:22 (video time) where you say that the small signal changes the frequency, this is true in closed loop conpensation, correct? if so, from the picture I see that the small input noise makes noise on the output voltage, and in same time this menas that the loop is open... can you help to understand me in what I'm wrong?
Thanks a lot in advance for your reply
BR/Roberto

Thanks for the informative video! I'm trying to simulate myself but encountered some issues:
1. I have noticed you are obtaining the transfer function for a converter with 100kHz resonant frequency around the DC operating point of 80kHz. Is this method applicable for all operating conditions of the converter (even in very low output power where the current to the output is not continuous).
2.As you have pointed out, prior to running the AC sweep i performed a few simulations to make sure the excitation results in a "clean" sinusoid at the output - which for some reason i could not get as you have at slide 15. I have a feeling it have something to do with the time-step (1nsec) which has a pretty strong effect on the results. Can you please comment on this?
3. The values of the simulation do not add up to me, Q=0.085 , R=50 , can you please confirm
Thank you!

Professor thank you very much for your great explanation. Is there any chance to design a controller based on the obtained graph for the LLC converters. How the output of controller must be connected to the suggested modulator?

This video gives an intuive explanation about major aspects. Congrats.
The thing I'm missing is the "-1" in the Voltage Vontrolled Current Generator. Is there a specific meaning for that? Thanks and regards prof.

I believe there is a misstype in the expression for FM modulation on slide 14.
I think there is a cosine function missing in the expression.

Hi Sir, first of all thank for your videos with high educative content.
I still don't get the difference between the 'static' transfer function and the 'dynamic' one.
Why can't we say that linearizing the circuit (diodes and mosfets) by doing the ac analysis using PSIM is equivalent to injecting a small signal at a specific bias point and then measuring the output with respect to the input?
Thank you again!

Sir, how does one get the static transfer function using psim ?

As a comment, I would like to add , that Simetrix/SIMPLIS can do this much faster.
For example, for LLC circuit it take only 4 second to obtain Bode Plot for a range of 10Hz to 100kHz with 20points per decade.
And it even can be done by free student version of Simetrix/SIMPLIS.