Interesting.... When I finalise component choices for my solar battery charger, I'll try this test!

Very interesting and useful, thank you Fesz!! I Will also try to measure loop response when I get the necessary equipment. Keep working like this!!

Amazing as always! Thank you

Very good video. Thank you.

I like to implement power supplies with a single integrator. Stability is guaranteed with any load and start-up is clean, with no overshoot.

Good job)

My favorite SPICE simulator is Microcap 12. It`s freeware since a few years ago. A side from that it has an extra stability simulation which works pretty good. For anyone interested take a look at the reference manual its documentation also is pretty good. By the way great video as always :)

Great, thank you very much. Very useable info.

Fantastic video, will be following this when I finally get around to designing my own lab PSU (for fun). Where did you get the "good" margins from? I.e. 45/60 degrees and the gain?

Nice Video❤

Thanks.

It's easier if you measure the output impedance and group delay of the DUT. See the white paper at Omicron Labs "Non Invasive Measurement of Power Supply Stability"

What IC did you use ? asking since i wander if we can find 100khz in the datasheet since they mist have tested for this , also this may be lowered but the PCB design and part values but it would be interesting to see IRL value vb theoretical datasheet values. Also here is an idea: boost or buck converters on a shared output how to stabilize this .

Great video. Is this method related to the philosophy behind the new .fra directive in LTspice 17.1?

There is a "small" problem here. Your reasoning on the open loop is correct but you are doing your measurement in closed loop, i.e you are fighting the regulator that is trying to cancel the error and the transfer function is not the same. On top of that by changing the excitation with frequency you are adding a pole and a zero to the system. So you are not measuring the performance of the original design but a simulated combo system with virtual components. An effect of that is the spike seen in the phase response. You should bias a constant operating point with an auxiliary power source and open the loop, then perhaps add a corrector circuit based on the open loop measurements. BTW, a 30deg phase margin will give an "optimal" speed response with a single bump damped overshoot for a system with 2 dominant complex poles. Nice channel though, continue the effort, I see progress over time, and quite often learn a trick or two.🙂

Hi! Some questions... 1. What are those 2 gaps in the phase shift plot on lower frequencies? Aren't those mean also stability problem? 2. Output seems to oscillate even before applying the load step (even before ringing starts), or do I see wrong? 3. How these measurements show exactly the bandwidth of the power supply? What bandwidth of supply really mean? Thanks!

Which transformer was used to inject noise?

Thanks for an interesting video. Can you please mention something about the transformer itself? How can a transformer be suitable for such a wide frequency span, wont the magnetisation current run away for low frequencies? What about the flatness of the transformer characteristics? /Tomas

this is a measurement that can also be done on a digital power supply, correct?