Some regulator series (for example *1117 from SOME manufacturers) require ESR of capacitors on the output to be within some range, for example 0.1 ohm -- 1 ohm. In such scenario, using an electrolytic capacitor can be better than using a ceramic capacitor. If using a ceramic capacitor is required due to size constraints or other reasons and a better regulator is not possible, then one could add a resistor in series with the capacitor to introduce some ESR into the circuit. Also, some datasheets say something similar to "a 10uf tantalum capacitor is enough" ... keep in mind they may say tantalum because the ESR of tantalum capacitors was usually quite low (in the hundreds of mOhm) but not as low as ceramics and way back then on the first revisions of those datasheets electrolytic capacitors may have been much worse specs wise, so if you want to use electrolytic or polymer capacitors instead, you may have to go with a slightly higher capacitance value. Tantalums are often more expensive and they have some drawbacks, like potentially burning up / exploding on overvoltage (hence it's often recommended to use tantalum capacitors rated for at least 50% more than regular expected voltage)

+1 would love to learn more about output capacitance on switching regulators

great subject, great watch. Even though I understand these principals beforehand, it is still appreciated to see the real-world waveforms as it actually saves considerable amounts of time performing these experiments on ones own.

Careful the Audiophool Mafia will be after you :D

Ha ha. That audiophile effort, as with the rest of the quackery that goes on in that industry, is hilarious. In response to your question of whether we'd like to see more detail on smps filtering, I for one would be very interested. I'm particularly interested in the implications of driving high current solenoids (about 4A). Thanks for your intelligent videos. Much appreciated.

Yes pls do a video such as this for switchers. 👍🏽

This was an excellent video.

Excellent, thanks…

Very interesting. Also suprising to see that having a smaller/lower ESR capacitance is not necessarily better for a linear regulator.

Great vid. It is good to have visual confirmation and explanation of the conclusions I have drawn after many experiments where adding more capacitance never seemed to have the desired effect. Thanks. +1 switching output cap discussion

Great video..........often ignored subject.

Great tutorial, I for one would love more like this...cheers.

Nice video , this it is a useful information .

Well, any reactance on the output introduces a pole which in the worst case violates the Nyquist stability criterium. You showed nicely the impact on transient load changes where oscillatory behavior became apparent already. In principle a regulator is as you say just the equivalent to an op-amp. With the proper compensation you can achieve better slew rates than just with the .20dB/dec response. In a power supply you want to enforce stability which as you demonstate can easily be destroyed. Anyway in your drawing looks like that likely by mistake you switched the inputs of the op-amp - thus adding the compensating capacitance to the non-inverting input and output which surely causes instability given its value.

Learned something new today! Thanks.

I tend to have been using LDO's for their efficiency and tend to use about 10uf ceramic in parallel with the local and bulk decoupling. I only know 1000uf's are only required after rectification for smoothing. Other than large fast loads like you mentioned.

Good video. For linear regulators, such as 78xx, it is not recommended to put low esr capacitors at the output. This can cause generation. As well as high-capacity capacitors. But if you need a large capacitor capacity in the circuit, and it stands after the linear regulator, then a 4.7-15 ohm resistor must be installed between them.

Great Info! Thanks

Great video as always

Great episode 👏👏👏👏

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At 5:22 the +- inputs of the op amp are inverted.

I would have liked to see also a test with datasheet recommended values and cap types

As always, then, follow the spec sheet! I'd be very interested to see exactly the same, but for LDO regulators. How is all this affected by the distributed supply capacitance in a complex circuit with local decoupling on multiple devices? Do we simply rely on the local supply inductance to allow the regulator the freedom to regulate?

Great video !!!

good video

The ESP8266 is a difficult IC. 3.3 volts and a few mA, but high spikes when it connects to the wifi. Not every linear regulator can do this. Usually the 3.3 volt is generated from a 5 volt. That's why I put enough uF in front of the 3.3 volt regulator as a buffer. In the project I had a 24-30 volt supply voltage, from which a stepdown generated 5 volts, then the 3.3 volt linear regulator.

ive had the issue several times with a classic 78 79 dual rail supply and opamps that the positive rail wont start and just sits at -0.5V or something

This topic never gets old. The question is why is there so much misconception?

You didn't test the regulator noise under load, which is I think why they do add excessive output capacitors.

I have an electronic/mechanic background, although most of the electronics were plug and play. I am now wanting to build and design my own projects now that I'm retired. Some of this was over my head for where I'm at understanding wise. Could you suggest some videos that may start more with laymen terms? I think you do a great job, just some of it's over my head..

I might be wrong but I'm sure XraytonyB had some problem with ringing in a tone circuit when he changed the electrolytics for ceramics and was asking if anyone knew what the reason was for it, is this a related issue as he changed them back and the ringing stopped.

Excelent video, very well demonstrated, the capacitor in your diagram, inbetween the opamp output and the non-inverting input, what is it used for. Also could a similar test setup be used to get an estimation of the Phase Margin of the feed back loop by observing the oscilations on the step impulse at the output of the regulator. Thanks again, a great video.

4:20 this looks like one of that retarded "fever level" audiofool regulator/filter module from Ali ;D

What value was the ceramic capacitor you used? The mlcc waveform looked horrible though the conventional wisdom is to put small ceramic capacitors on the output.

Nice video. Is there a general rule on Input:Output cap ratio? - datasheets typically show between 3:1 to 10:1 from memory.

Nice video. Regarding ringing with the ceramic capacitor on the output, I think you said it was due to the low ESR, but to solve it you increased the capacitance as well as using an electrolytic. Could you instead have added some resistance in series with the ceramic capacitor, would that have worked?

Without all the output caps the inrush current will have no where to go. ;-) an often forgotten part of regulators is the input ripple rejection within the audio band.

The solution is to put a number of different caps on both the input and output lines.

2:40 Can anyone pls explain Q11?

Say if you were Photonicinduction and wanted to blow a 5kA fuse you'd want a large cap bank ROFL!

I use 0.1uf+47uf output of 7805

First. :-)