I always seem to be sticking my foot into it this way, so I'll take a swing.

It looks like it's a deceptively-drawin JFET constant current source. A MOSFET hooked up that way would not do anything until its breakdown voltage on the drain was exceeded. If you mentally sketch in a JFET, it makes perfect sense as a constant current source.

I was somewhat thunderstruck at seeing this thread here, as I had just popped into put up some more MOSFET Heresies, extending the line at GEO.

Those of you who read GEO know about my theories and the practical proofs of them in using power MOSFETs as substitutes for cathode followers. There seem to have been a number of successful applications of that as tone stack drivers and as follower drivers for output tubes.

I toyed with the idea of a MOSFET phase inverter but put it aside because I thought the larg-ish Cgss would severely limit frequency response in a voltage-gain situation.

I finally got around to simulating this. I put a pair of IRF820 2A/800V MOSFETs in the sim in a standard diffamp-style inverter and checked their frequency response. It was as expected disappointing, down 6db at 340Hz. But the low frequency gain was over 60db, which amazed me.

I remembered something about linearizing diffamps by reducing the transconductance of the devices with unbypassed source resistors, so I put in 510R resistors in each source before the 6.8K joint resistor to ground. Response was now down to about 35db - useful in a PI. But what was really astonishing was that the high frequency -6db point was now over 140kHz.

It appears that trading unnecessarily high gain for input impedance lets you use a power MOSFET as a gain sub in a diffamp-style phase inverter.

There's a lot more work to do to get the thing right, but it looks like this is another place where MOSFETs can free up a tube to make good tube sounds otherwise. Promising anyway.

The circuit was a diffamp with 100K drain resistors to +300V, 510R source resistors joined at at 6.8K resistor to ground. The gates were tied to a variable DC bias source, which turned out to need about +22Vdc on it, and the second gate was tied to the bias voltage with 10nF across its 1M bias resistor. Input was through 50K (to fake a driving tube's plate resistance) and a 100nF cap.

Then there's the uC to set and rebias output tubes. That worked pretty much first time. Reads the cathode current, outputs a positive voltage that's inverted and supplied to the grid resistors by a high voltage inverting amplifier.

Then there's the power on sequencer/tube saver.

Using a MOSFET switch in the B+ line, you delay power on for long enough for the tubes to get hot. Then turn on the B+. Slowly.

Whenever cathode current goes over X you turn off B+ to save the tubes, OT and PT.

The uC also reads a thermistor for internal cabinet temp and turns on a fan. Very slowly at first, more if temp doesn't go down.

Do you mean an N-channel JFET, which would have a symbol like this?

I'm still confused by this, as I don't know where R13 in the diagram above (150R resistor) would connect to a JFET. As you said, its kind of deceptively drawn. Is R13 connected to a body connection? If so, can the device be a JFET? (I thought they had no body connections.)


The schematic lists the part as Q1 1038, but it doesn't say anything more. The parts list for the amp only lists the amp maker's internal part number of 30011016, and no generic part number. The parts list only has a description of "(SS) FET, Green/White/Blue." Interestingly, Q1 and Q2 have the same part number, though Q2 is listed as Q2 1036 in another location on the schematic. The part could be either "1036" or "1038" if one of them is a typo.

From this information, can you come up with the real/generic name for the part? I haven't had much luck, but then I don't know diddly about JFETs.

Well, if the truth be told I was trying to get your attention without having to resort to private messages.

As it turns out, I have been planning on using a 12BH7 CF driver to drive the 3 P-P pairs of 6550 that will be used in the output section of each channel of the 100W Class A amp. I've been planning on using a CF driver primarily out of my desire to match impedance, and partly out of my desire to eliminate the problems of Class B bias shift and grid current clipping. (I'd rather have the output tubes driven into plate saturation than have to listen to grid current limiting.)

Being open minded about this, I suppose it might be worth looking into trying out a MOSFET for this sort of application if I had a little help. I know that the MOSFET will take care of the Class B bias shift and the grid current clipping. Am I correct in assuming that it would also be capable of driving the low impedance that's presented by the 3x6550 grids in parallel?

By any chance, did the diagram that I posted above (that uses an unbypassed source resistor) help you along the road to this realization? Or was that just a coincidence?

Another thing I thought I'd ask is whether MOSFETs are better than JFETs in this sort of application, because JFETs have higher transconductance.

you know what they say -- a picture is worth 1000 words. <schematic hint>

My interest along these lines isn't based so much on the desire to eliminate tubes with SS devices as a cost-saving measure. To some extent, that's what led us all down the path to SS amps in the first place. What I'm more interested in personally is using SS devices to enhance the performance of tubes in performing their intended duties. To that extent, it would be very helpful if I could wrap my mind better around what's really going on with Q1 in that schematic snippet that I posted up at the top of this page. Admittedly, my knowledge of SS components is the weakest link in this discussion, and any help that anyone could offer would be greatly appreciated.

Pardon my ignorance -- uC?

Regarding protection against bias failure -- this reminds me of an old method of bias protection: you use an extra triode and hold it at cutoff by connecting its grid to the bias supply voltage, and then wire the triode in series with a relay, so that the relay could shut down the circuit in the event of a bias failure. All that's missing from this design and your MOSFET suggestion are the explosive bolts.

micro-controller

Yes, I meant n-channel JFET.

My speculation on it being a JFET is based on the fact that a MOSFET as drawn simply cannot work. It struck me as I looked at it that if you put a JFET in there where the MOSFET is and connected drain to drain, gate to gate, and source to source, that a JFET would in fact work. I therefore made the otherwise unsubstantiated leap that someone put an erroneous symbol in the schematic and it was really a JFET. I have seen a JFET used as a CCS in the source of MOSFETs before for high voltage operations, and this seems to fit well.

It's probably not going to be any help. Those are in-house part numbers, and they won't help you at all unless you can get the manufacturer's cheat sheet for in-house to industry part types. Makers do this for two reasons:
1. They get to control and select what parts are used, which is a real and valid reason to do this.
2. They get to charge extra for their preselected parts in repairs.

You can think of a JFET as a low voltage but higher current version of a pentode. In common with tubes, JFETs with no reverse bias from gate to source conduct heavily. In common with tubes, you can bias them with a resistor from source to ground to cause a voltage drop from channel conduction. NOT in common with tubes is the fact that JFET current will pinch off at a value called Idss (current from drain to source with gate-source shorted). JFETs make near-perfect constant current sources with their gate and source shorted. You can make them variable CCSs by putting a resistor in series with the source and tying the gate to the far end. Varying the resistor varies the current down from Idss.

The CCS apps largely don't work with triodes and poorly with pentodes. But the biasing is similar.

JFETs usually have drain-source breakdowns from 20V-50V.

Yes. A typical high voltage power MOSFET has a transconductance of about 0.5 to 2 amperes per volt. I'm not sure what the forward biased impedance of a 6550 grid is, but if it's as low as 1K, a typical IRF820 will only need enhancement of a fraction of a volt to pump that much current. The 820 is a 2A continuous device; the pulsed channel current is much larger. And both higher current and gainy-er devices are available. Put it this way - if a tube can drive it, the MOSFET won't even notice it, at least in terms of current drive.

It was coincidence, but that's what was so striking.

They each have their own speciality. JFETs have interelectrode capacitances which are small enough to use directly with tubes without dramatic high frequency losses. Power MOSFETs have a very high Cgss (grid-source capacitance) which is crippling in some applications. It's like having a high-transconductance tube with a 1000pF cap from grid to cathode that you can't get rid of.

JFETs have high gain, low capacitance. On the down side, they are low voltage devices and have only a few milliamperes of current.

MOSFETs have monster current capabilities, high voltage, but the ugliness of a high Cgss. Actually, Zetex makes some TO-92 devices that are 450V and 0.7A/900mW and only have Cgss of 50pF. I expect that these could make a really high frequency capable PI.

Tubes have high voltage, low-ish capacitances; but low current limits, and that funny grid-cathode conduction thing.

Yeah, yeah, I'll go draw it up. 8-)

I'll take a look and see if I can write something up.

You see, I always did want to design something with explosive bolts in it... 8-)

Thanks Enzo.

Well, I'm still trying to figure out how to interpret that non-standard drawing and match up the leads on a JFET to those in the original schematic snippet.

Looking at my original schematic snippet, does R12 connect to the Gate, R13 to the Source, and R10 to the Drain?

Is that to say that the variable CCS apps *do* work with triodes and pentodes?