Very clear explanations of concepts with practical demonstrations. No possible doubts. I like your videos very much.

Excellent proof of the design points that you make. I had not thought about prioritizing inputs over outputs. That's a good point and I will add it to my bag of tricks.

This is better then many videos I've seen on EEVblog or even w2aew!!! This is fundamental knowledge!

Thank you for explaining and proving those important principle so clearly

very useful and relevant to so many circuits - thanks for all the thought, wisdom and work you are putting into everything you do.

Great demonstration. This video make me thinking of my DIY Class AB audio amplifier back in 1985. I solved the Hum noise issue by placing the PCB in vertical position near power transformer. The circuit loops is in parallel to the magnetic fluxes emitted from the power transformer.

dude this channel needs WAY more subs. Ive been doing this stuff for over a decade and im always learning something here.

Thanks for posting. Production values are great in this video 📷.

Happy to discover your tutorials. They are of very high quality.

So, in summary, to make a circuit more immune to external noise: · Use shorter wires/traces and make loops smaller. · Use PCBs instead of wires. · Use surface-mounted components instead of through-hole components. · Shielding the circuit.

Wow very well explained

Great content, as usual. Thanks !

Very informative! Thanks

Very nice and practical explanation - this is much more intuitive compared to traditional teaching of loop areas and EMC in general. Good work and inspiring for my future electronics videos :)

I've got an idea of making circuit as 'sandwich' of PCBs can further reduce loop area, because the whole circuit becomes less 'spread'/flat and more compact in volume.

you can decrease more noise by choosing lower value for resistor too, and screening too , make trace guard at high input impedance will also decrease noise

Great video

Great video .. Thank you so much for such deep analysis and sharing with us . I noticed you twisted your power supply wires does it make any difference? Do they reject common mode noise 🤔

I would have loved to see the effect of a gnd plane, even if it was on a single layer. Great content, as always!

Really interesting, thanks.

An important issue in high gain (sensitive) amplifiers is maintaining proper order of the ground connections. You don't want to put a decoupling capacitor, or the output ground conection, in the same loop as the amp's input ground connections. It's ideal to keep the different sections grouped, and then "star grounding" (or at least, first group the sections (input, output, filters), then bring them together at a common ground point. In this way, the differences in ground impedances do not induce unwanted signals in the input/neg. feedback path

Your deep analog knowledge shines. Can you do a video about track impedance matching?

Thank u Sir ...

thank you!

Hi great video, did this circuit work with a MCP6021?

I have a lot of broken cores from SMPS pcbs. Can I crush them into a power and use very little epoxy, to tamp the mixture in to a mold and make new cores?

If you have a 2 layer board, have the return path overlapping the forward path on adjacent layers would make for absolute min loop area.

What about the induced signal on your cables? I see they are twisted pairs but is it enough?

Why am only learning about this great channel now, from Hackaday? Do better, KZbin :-(

The use of both sides of the pcb and a ground plane would gain a bit more attenuation.

You put a lot of work in these videos, they are really good. Have you tried the effect of the pcb material. The ratsnest one couples to your inductor through air, that gives a certain capacity. Probably to small to have much effect, but if you would glue it to a piece of FR4 in theory the very small capacity becomes a lot bigger. I never tried to measure this but I think it will perform worse as the ratsnest alone. You really could use a VNA for your experiments. I have done a lot of experiments like you but then with the SDRkits VNWA, back then the only affordable VNA. I learned so much from experimenting with it. (made some tutorials about using a VNA, you can find them on my website ( pa4tim.nl) )

How is the input floating, when its connected via a 100K resistor to 1/2 the input voltage?

Can a box made of iron-oxide film provide shielding against electrical and magnetic fields?

6:35 Is this a Hall Effect sensor? Can you also induce a current in the inductor by passing a current through the loop (instead of a magnetic field)? Or am i talking about the same thing: magnetic field generated by a current? Is it correct that it also works with DC? Isn't that similar to a Rogowski AC Current Sensor? Why must a Rogowski be a coil instead of a simple loop? Why does the Hall Effect work with both AC and DC, but the Rogowski only AC? Thx! circuitdigest.com/article/how-to-measure-current-in-a-circuit-with-different-current-sensing-techniques

At 1:07 "a single stage amplifier with 101 gain is not that practical". Why is that?

What is use of R1 ?

are you trapped inside a football? (referring to your background) xD

*empties coffee machine into prevailing wind* GROUND LOOP!!!! meh. the first stage is the most critical, and as everything after that is amplified, targeting SNR here has the largest effect. one also must consider the mains earth grounding and the amplifier grounding... the circuit should reference to the chassis at one point only, and that point should be the input jack. rebuilding old guitar tube amps, i find so many ground loops and complete disregard of basics that it makes one want to scream... a big one is all plugs/jacks and pots being "grounded"... a really bad habit, does more harm than good. unfortunately the old school metal jacks are already grounded and need isolating bushes... except that ONE input jack. a recent one... someone had added a "ground lift" switch... by switching the main earth... tch tch! thats dangerous... deadly dangerous... if you must have a "ground lift"... its to isolate the CIRCUIT from the chassis... never, EVER remove the mains grounding! the "ground lift" is for when you have unavoidable ground loops due to chaining things like foot pedals and PAs together... theyre all hooked up to the mains earth as well as the "signal ground"... ONE is for safety. you dont mess with it. EVER. im not even going to start on general grounding basics...

This experiment cannot be relied upon to arrive at any conclusions about the relationship between a system’s susceptibility to RFI/EMI without further testing. Measuring at 2kHz only fails to tell us anything about how the induced noise in the circuits will vary as the frequency is swept through various ranges. Being that each circuit is basically acting as a tuned antenna, My guess is that each circuit and particular footprint has a resonant frequency where it will become most susceptible to particular frequencies. So, drawing any conclusions about size vs immunity to noise based on this experiment alone seems to be either ignorant of the truth, simplistic, or outright disingenuous. Maybe I am the ignorant one. That is possible, as I am not an expert in this filed, but this is how I see it.