I'm just sharing something that may be of interest. In the recent FET noise thread , a cascode circuit emerged as an input stage capable of lower noise and equal or greater gain than a classic triode (12ax7) input stage. In pursuing the FET circuit further, it has another benefit that may be useful. Turns out that the FET cascode can be extended with a current mirror to achieve a very high power supply ripple rejection of almost 70db. This performance depends on the high drain impedance of the cascode circuit, so a similar current mirror doesn't do much for a triode or pentode stage. The circuit below shows three current mirror arrangements (many mirror circuits are possible) and they all perform equally well so the choice of mirror circuit seems non critical.
Current mirrors are common in opamps and SS power amps. I'm unaware of any used in guitar preamps, but I wouldn't be too surprised if it has. Anyone have a pointer to one?

A power supply with 120Hz ripple added (upper right) and a 1k/10uf RC filter that produces ~1v peak ripple (0 db) to power the 3 FET circuits. A standard triode input stage powered with 1v peak ripple would have horrible hum. The triode stage (on the left) therefore has an additional 10K/100uf filter. This additional filter is what is needed to make the triode stage hum comparable to the FET stages powered by the full 1v peak ripple.



Some waveforms illustrate what's going on. The PS ripple at C4 is ~1v peak (below). This powers the three FET cascode stages.



With all stage inputs grounded, the PS ripple visible at R17 (the leftmost cascode circuit output) is ~0.35mv peak (waveform below). This is ~ 69 db down from the PS rail ripple.



A PSRR curve of the R17 signal shows ripple rejection over varied freq's (below). Since the 120Hz PS ripple level was set to at 0db, the output levels are absolute stage PSRR values. The dip at 120 HZ is interesting. It is set by adjusting the value of C7 (and similar in other stages). I haven't fully grasped why there's a dip there, but it seems related to the parasitic cap's of the two FET stages and the fact that the rail ripple feeds the upper FET gate. Some "magic" level and phase shift of ripple at that Q13 gate leads to the dip. A 470nf C7 value moves the dip to 60Hz, which is what voltage-doubler and tripler supplies produce and is harder to filter with rail caps.



The output of the tube stage is ~0.4mv peak at R41 (shown below) - similar to the cascode output above. However, the additional RC filter of 10K (R42) and 100uf (C16) is needed to produce this ripple level from the tube stage. The RC filter reduces the PS ripple at C16 to ~1.3mv peak. The triode stage has a ripple rejection ratio of only about 10 db.



The source-follower FETs (Q6 and Q9) are not strictly needed, but the output impedance of the mirrors is high, so I added them to see if they impact things. Other than buffering the output, they seem benign.

OK - so does it matter? After all, you can simply add bigger RC filters to a supply to get any level of hum reduction you need. Better rejection means that fewer/smaller/more reliable filter caps can be used. Whatever filtering you have, it can't hurt to lower ripple by 60 db. Perhaps small (~1uf) mylar/poly caps are sufficient filtering in the preamp. It's another option for circuit designers to explore.

As for tone, there is no measure for that. I do know that I've tested the rightmost FET circuit and it behaves as the simulation predicts to the best of my measurement capabilities. It also sounds very clean, as the simulation predicts. That means that "tube color" will have to be added in later stages - but now the signal is 5-10v peak (stage gain is ~70-100 depending on values) with lots of headroom and very low hiss and hum. As a physically small circuit (no bottle or sockets), it can be located right at the input jack, with minimal lead length/dress issues.