Transformer balancing the output of a Blue Clipper? Output Z question...

Started by therecordingart, December 07, 2014, 04:40:30 PM

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therecordingart

http://www.beavisaudio.com/schematics/Images/Dan-Armstrong-Blue-Clipper-Schematic.png

I'm being an idiot and could use some help. I want to put a balanced out on a Blue Clipper, but am having a brain fart and can't figure out the output impedance. Is it as simple as adding up the series resistance? (18.2k when the volume is dimed?) I have an Edcor 10k/600 transformer that I'm thinking might work, but need help from someone smarter than me.

PRR

You fergot the 50K.

Looks like 13.3K when not clipping, near 8K when clipping, and much lower for anything over 400Hz due to the large capacitor.

10K:600 is not wrong; you are taking more than 4:1 loss (4:1 in transformer, plus loading loss) so output is more mike-level than line-level.

It really just uses one half of a two-opamp chip? Then rig the other half as unity-gain buffer, add 100 ohms series on the output, and use that to whack the transformer better. You can probably run 600:600 and get a fine line level. Or 10K:600 and pot-down a bit for a mike-level. Either way the low-low source impedance swamps much of the transformer's faults, and sucks-up more crap picked-up on long lines.

Are R1 and R2 supposed to be very different values? And R1 so small? Seems like R1 could be 10X bigger.
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therecordingart

Quote from: PRR on December 08, 2014, 01:51:58 AM
Are R1 and R2 supposed to be very different values? And R1 so small? Seems like R1 could be 10X bigger.

I've built a bunch of variations of this, and I like to bias it at half supply (R1 and R2 are 1M). So is the output Z the sum of the pot, R5, and R6? So put a buffer on the end of this -> series 100R resistor -> 600:600 xfmr?

Here is a crude Windows Paint drawing:

http://i.imgur.com/xWwMFiZ.png

I appreciate the help!

duck_arse

" I will say no more "

PRR

> is the output Z the sum of the pot, R5, and R6?

Pot is parallel to the others.

It's too cold here to teach basic series/parallel resistance networks. There are books with more patience than me. Boylestead may be one; many others.

> put a buffer on the end

AND some DC biasing/coupling to account for your single supply.

http://i.imgur.com/T670gSH.gif
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