BigEd wrote:
Do you also have a circuit-level electrolytic at the point where power is brought into the circuit?
Indeed I do. There is a 100uF electrolytic with an ESR of 0.03 ohms. In fact, the power is applied through it leads.
So here a some scope images of the event. As a note, I also tried a scope probe from a different manufacturer and the results were exactly the same.
This with the just 6 CMOS loads:
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CMOS_P copy.jpg [ 65.81 KiB | Viewed 749 times ]
Note how the voltage rises slowly after the rigning settles down.
This is with the 6 CMOS loads and a 10K resistor:
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CMOS_10K copy.jpg [ 65.86 KiB | Viewed 749 times ]
The rise time and dip are the same, but the voltage does not increase after the ringing settles down.
This is with 6 LS TTL loads:
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LSTTL copy.jpg [ 64.55 KiB | Viewed 749 times ]
The rise time is a tad slower, but the dip is much reduced. The voltage reached (3.7V) is not as high as with the CMOS loads, but we do get the slow rise. Note that we can no longer reach 0V. It looks like about 0.05V at the lowest.
This is with 6 TTL loads:
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TTL copy.jpg [ 66.2 KiB | Viewed 749 times ]
Rise time to 3.5V is quite a bit slower (3-4ns). The dip is not as bad as the CMOS loads but worse than the LS TTL loads. We reach the same 3.7V as with the LS loads but we don't get the slow increase. Low voltage has increased to 0.15V
This is with the 6 CMOS loads but the power (Vdd) removed from the CMOS IC:
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CMOS_NP copy.jpg [ 64.67 KiB | Viewed 749 times ]
This is strange and unexpected. The dip is gone, but the maximum voltage reached is reduced to 3.6V and the time to reach 3.5V has increased by 10ns!? There is no slow rise.
And this is with no IC, just the circuitry load (~12pF):
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NOCHIP copy.jpg [ 65.27 KiB | Viewed 749 times ]
Again no dip and rise time is increased over having a device load.
I am more confused than ever now.