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Okay, this is weird. But it's late, so hopefully I'm just over tired and I'm overlooking something dumb.
This should be quick and easy.. but unfortunately i'm the one who's telling the story, so there goes any hope for "quick", but I'll try.....
I'm doing some testing on my output stage, right. I removed the DC coupled cathode followers, and wired it to be driven from the plates of the LTP (as used in more traditional configurations). I want to honestly ditch the driver stage if I don't think it adds anything tonally or in the response of the amp. I don't want to fall in love with an idea just because I'm invested in it. I'm ready to put the meat of the design on the chopping block and change it, or call it a failure and start something fresh.
(oh, refer to the schematic below. I drew it up quick but the values are pretty standard, so I didn't include them for time considerations)
Anyways, I was running a simple test tonight to set it up for using global feedback, and without feedback. With feedback engaged, I fed the input of the amp with a sine wave, and was monitoring the voltage driving the grid of the phase inverter. It was relatively arbitrary, but I adjusted the volume control so the voltage at the input of the LTP was 1VRMS. Nice clean sine wave. Normal right?
For testing purposes, I wanted to compensate the non-feedback PI drive voltage to be the same as with feedback, so I installed a 1M5 potentiometer in series with the 470k grid leak and kept all controls the same. So, when I removed the feedback. The voltage at the grid (test point #1) of the inverting triode was a little lower with the pot at minimum resistance? (basically out of circuit). I was like "what?"
Then I thought, "well, the negative feedback input is at the non-inverting grid, so maybe I need to test the signal at the non-inverting grid.
Here's where it gets weird: I confirmed that the feedback signal coming from the 8Ω tap was not open. So, while monitoring the signal (test point #2) at the non-inverting grid with feedback engaged, I pulled the feedback and the signal voltage cut in almost half!?? I did it again, and there is clearly a drop in voltage without the feedback signal.
So, the simple answer would be that the phase is reversed and I'm not using negative feedback at all and it's positive. Wouldn't that cause crazy oscillation?
And if the feedback was positive, why would the presence control works as it should with the global feedback connected.
What. the. hell. is going on?
This should be quick and easy.. but unfortunately i'm the one who's telling the story, so there goes any hope for "quick", but I'll try.....
I'm doing some testing on my output stage, right. I removed the DC coupled cathode followers, and wired it to be driven from the plates of the LTP (as used in more traditional configurations). I want to honestly ditch the driver stage if I don't think it adds anything tonally or in the response of the amp. I don't want to fall in love with an idea just because I'm invested in it. I'm ready to put the meat of the design on the chopping block and change it, or call it a failure and start something fresh.
(oh, refer to the schematic below. I drew it up quick but the values are pretty standard, so I didn't include them for time considerations)
Anyways, I was running a simple test tonight to set it up for using global feedback, and without feedback. With feedback engaged, I fed the input of the amp with a sine wave, and was monitoring the voltage driving the grid of the phase inverter. It was relatively arbitrary, but I adjusted the volume control so the voltage at the input of the LTP was 1VRMS. Nice clean sine wave. Normal right?
For testing purposes, I wanted to compensate the non-feedback PI drive voltage to be the same as with feedback, so I installed a 1M5 potentiometer in series with the 470k grid leak and kept all controls the same. So, when I removed the feedback. The voltage at the grid (test point #1) of the inverting triode was a little lower with the pot at minimum resistance? (basically out of circuit). I was like "what?"
Then I thought, "well, the negative feedback input is at the non-inverting grid, so maybe I need to test the signal at the non-inverting grid.
Here's where it gets weird: I confirmed that the feedback signal coming from the 8Ω tap was not open. So, while monitoring the signal (test point #2) at the non-inverting grid with feedback engaged, I pulled the feedback and the signal voltage cut in almost half!?? I did it again, and there is clearly a drop in voltage without the feedback signal.
So, the simple answer would be that the phase is reversed and I'm not using negative feedback at all and it's positive. Wouldn't that cause crazy oscillation?
And if the feedback was positive, why would the presence control works as it should with the global feedback connected.
What. the. hell. is going on?
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