Actually, ALL transformers are victims of magnetization, not only permanent but also that generated by the actual circulation of current through the windings (H field).
Yes, but to apply significant DC current to a Transformer with Mu-Metal cores not explicitly designed to operate thusly causes permanent, practically irrecoverable deterioration of performance.
A xfmr "specified for DC current" is just one the designer defined an acceptable deterioration of performance.
Not quite. It is one that is DESIGNED EXPLICITLY to withstand the specified DC current while the deterioration of performance is within the specified paramebters.
A transformer "specified for DC current" by manufacturer X maybe unacceptable by manufacturer Y or client Z. It's all a matter of expectations.
A transformer specified for x mA DC should provide rated performance at this level of DC, so it is not a question of expectation, but of reading the datasheet, presuming there is one that is adequate.
No common xfmr is actually 100% ungapped.
In 2024 many are made on gapless amorphous/nanocrystalline toroid cores. Nagra uses these, for example.
And no xfmr "specified for DC current" is actually immune to the effects of DC.
Any transformer designed explicitly to handle a specified level DC will perform as designed with this level of DC and performance will deteriorate at greater levels of DC.
If it is explicitly designed to handle 0.00 mA than applying ANY DC will degrade performance.
Perhaps the degradation and the permanent degradation of performance is acceptable, but it needs to be warned against.
Finally, as I am critiquing the SimpleP48 circuit for being too simple, it does behoves me to show an alternative that addresses somebunall of the grosser shortcomings.
Both this and the original circuit share the same shortcomings. Absolutely awful HD approaching 10% at 124dB SPL (assuming a -40dB sensitivity Capsule), poor cable capacitance handling, really, there is nothing whatsoever to recommend either the original 2 component circuit or this one when we have better options.
Yes, either version will work and some sound will come out. Which may be enough for some.
For the rest...
The 10nF and smaller Capacitors should be C0G (in 0603 to fit the BM-800 PCB which uses lower grades) or film. For the 100n C0G are preferred as well, but X7R will probably not be the end of the world. 1uF need to be X7R.
The BSS84 need to have matched threshold voltages. The ones I had so far from a reel all matched so well, no extra action was needed.
The bias chain (given 1% resistors) will have > 35dB suppression of Audio across all frequencies, the lowpass filter effect adds ~ -60dB @ 20Hz, so any audio will be attenuated by at least 95dB @ 20Hz, with a 60dB/decade slope.
As shown here, we have
40V 35V bias, not 60V, which will take
3.5dB 4.7dB of the sensitivity, so a -34dB/pa @ 60V sensitive LDC capsule will produce
-37.5dB/pa -38.7dB/pa or 11.7mV/94dB to convert into modern money. Using P68 instead of P48 and adjusting R16 (switchable?) would recover this sensitivity, but it is unlikely to improve SNR materially.
4Hz-100kHz -3dB with an option for a HF roll-off (increase C2) to limit how bright mic's are.
Predicted is an unweighted
14dB 20dB self noise 20Hz-20kHz, so perhaps
10dB(A) 16dB(A) without accounting for Brownian Motion Noise and acoustic resistances etc. I would say "low enough for music recording" but not phantastically low. About
30dB 36dB worse than -20.3dB(A).
With a 2.2k Mic Pre input load we can handle
+35dB/pa or 129dB at ~ 0.2% THD +40dB/pa or 134dB at < 0.5% THD (H3 dominates) with a -34dB/pa @ 60V bias capsule.
Higher loads allow more SPL.
As mentioned before, this will easily be able to be realised on the BM-800 PCB with a few cut's & jumps.
Add the favoured AliExpress K47 or whatever capsule plus saddle, a true studio grade recording LDC is done.
Anway, enough from me.
Thor
)
