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if the power supply is earth ground referenced and you connect to a device that is earth ground referenced, good or bad things can happen

@@IMSAIGuy thank you!

Your scope, if AC powered, will have the returns on the scope referenced to the Earth or safety ground. So if you are measuring something referenced to the earth or safety ground the scope has to have the Ground connection tied to this earth ground.

Google it.

Use the CT transformer and a bridge with two filter capacitors.

You can, if you are expecting a reasonably balanced loading between the positive and negative sides, use the center tap of the transformer as your ground reference. You'd have separate filtering and regulation for each side.

One of the leads on a 'scope or multimeter probe will be the "reference" lead. This is the "ground" clip on a 'scope or the black/negative lead on a multimeter. The voltage shown on the 'scope or meter is relative to the reference lead. So if you put the red lead on +12V on a PSU and the black lead on ground, the multimeter will show +12 V; if you reverse the two probes it will show -12 V. _All_ voltages in a system are relative; you just pick some arbitrary point in a circuit to call "ground" and then everything is relative to that. That was the point being made near the end of the video. Actually, you don't even need to pick a particular point in a circuit; I can just arbitrary label something run from a 12 V PSU as having +112 V and +100 V power inputs, and nobody can say I'm wrong (though they may not be able to find any point in the circuit that actually measures 0 V relative to my 0 V reference. But even at "112 V" and "100 V", my two power inputs are still 12 V apart.

@@Curt_Sampson Oh, I totally get that part - earth is just a reference, just like someone standing next to a passing train, or someone on the train. My question was HOW does it(the meter/scope) know it's positive or negative.

@@GeorgeGraves For the multimeter the reference is always the "common" input, into which you usually plug the black lead. for the 'scope the reference is the "ground" pin. The voltage each shows is relative to that reference and that reference only. In other words, the instrument has no idea what _you_ may have chosen as the system reference voltage for your board. If you want to figure out what the "real" voltage is by that reference, you need to subtract the instrument reference from your system reference. E.g., if you put the black lead on your -5 V bus, and measure your +5 V bus, the meter will show 10 V, and you have to subtract -5 V from your 0 V ground reference, to get 5 V, and then subtract that from the 10 V measured at the read lead to see that it's measuring 5 V relative to your system ground. I have the feeling that this explanation may not work very well, since it doesn't seem very different from what I said before, but I hope it helps. The key is to remember that the meter is measuring only _one_ voltage, and that's the voltage difference between the black and red leads, regardless of where you place them on the board.

@@Curt_Sampson Thanks. I guess you're describing how to use a multimeter. I'm asking how it works - specifically how it knows a negative is a negative, and a positive is a positive.

@@GeorgeGraves If the red probe is at a spot higher in potential than the black probe, the voltage is positive; if the red probe is at a spot lower in potential than the black probe, the voltage is negative. Or are you asking how a voltage meter works internally? That differs for analogue and digital meters. An analogue meter has a moving coil through which a little bit of current tapped off the circuit passes; this causes the meter to move right (for positive voltages) or left (for negative voltages) .With an analogue meter you (usually) cannot measure negative voltages because the rest point of the coil is at (nearly) full left deflection of the indicator needle. (In this case, if you see the needle "bump" left, you need to reverse the leads and read the deflection rightwards as a negative voltage.) But some voltmeters have a rest position in the centre, allowing you to read either positive or negative voltage directly off the needle over the scale. A digital meter uses an ADC (analogue to digital converter) to compare the input voltage to a carefully calibrated constant voltage source; these are complex and I won't go into the details here. But the principle is the same. They can either have the "zero voltage difference" point in the middle of the ADC, so that half the resolution is positive and half negative or could, presumably do two reads with the second doing a virtual "swap" of the lead; one reading will be zero or max scale, and the other will be the voltage difference. But it's probably cheaper just to add one more bit of resolution to the ADC than to build the circuitry to do this swap.

It's leading somewhere

Fine I'll be second then. Lol

third

No one cares. These comments scream loser.

Sorry, I am late today.