Need suggestion for tube MC pre-pre
I have a strange idea: make a pre - preamplifier with a triode ( instead the normal step-up or solidstate stage).
My target is a linear gain of about 4-6 times with the less noise as possible:angel:
Thus I need a lower-mu triode I believe with high transconductance, right?
The circuit will be a basic common cathode. Output impedence is unimportant, microphonics tubes has to be avoided of course.
With these carachteristic I have no idea of what tube I can considerate
to make a little experimentation:confused:
Every suggestion will be very appreciated!:)
santa madonna, you have a 'strange' idea indeed. A challenging one and judging from all the commercial offerings, not a good one ;-) Actually I have been thinking about an tube MC-phono stage, and I did some calculations. I concluded it made no sense, whatever tube you use. Let me explain. For MC phono you foremost need low noise. In tube terms this means rugged, low microphonic and especially high transconductance. You could think of e.g. E88CC or E182CC.
Now on to the numbers I came up with. My cartridge is a Benz Micro ACE (low). Its source resistance is 12 ohm, and the output @ 5 cm/s movement of the tip is 400μV (400 millionth of a Volt). With the appropriate bandwith (a bit more than 20 kHz), the source resistance can be 'translated' into 67 nV of noise (67 billionth). This means the signal to noise distance is 20*log(400,000/67) dB, or 75.5 dB. Now with an ideal amplifier you don't add any noise... However, Antonio, if you like to amplify the small MC signal with tubes, some noise is introduced. With an E188CC biased at 10 mA, I calculated a noise figure (NF) of 13.2. This means the S/N distance would be decreased by that number. OUCH, let's face it 62.3 dB S/N is not enough!!
You could improve a little by paralleling four E188CC triode sections, the NF becomes 7.8. With a hybrid approach you have much better starting point: for an JFET (e.g. the popular 2SK170 @ 10 mA) the NF would be 3.9. The best result however can be obtained with a special low-noise BJT: with the 2SC3329, again biased @ 10 mA, I calculate a NF of 1.4.
If you really hate solid state, you can do worse than opt for a built-in step-up transformer in your phono-amp. I calculated (for my microbenz ACE) a NF of 3.4 if you were to use a Lundahl LL1681 (1:13).
I hope you can now understand why I decided to do myself a favour, and go the hybrid route with the 2 SC3329.
:D :D :D
you are lucky: our Asaka Linn is only 0,25mV !!:bawling:
I understand your point, numbers are crude but realistic!
Now hear this:
suppose I take a E288CC, two sections paralleled.
Expectded gain will be about 12-14 ( without cathode bypass).
Now I become heretic and apply 12 dB of feedback!:devilr:
new gain will be 3-3,5 times and input impedence will be 1/4 , am I right?
What do you think about it?:rolleyes:
forgot a thing:
I am also interested in your alternative
Is it a sort of Hiraga le pre-pre schematics or more simple again?
what is your gain?
what is your voltage rails?
you show real commitment to the tube cause! And hey, the E288CC is a very, very nice tube. I am sorry to let you know, this one won't save you either.....
Just crunch the numbers: a Linn Asaka is low output. I found confusing numbers ranging from 0.1 to (your) 0.25 mV. I guess the 200μV @ 5cm/s in some test is the most dependable (?). The 5 Ω source resistance seems OK. We can now calculate the basic S/N of the source as 20*log(0.2mV/43nV)= 73.3 dB.
Then on to the amplification options: using a parallel doublet of E288CC triode sections, biased at 20 mA each, gives a noise figure of 11.3. This would result in 62 dB of S/N distance: TOO little! You propose to amegliorate the situation by using negative feedback. But to obtain the (local) feedback, you need resitors that, in practical terms, are bigger than the source resistance.... I am afraid this route won't bring you much good. In general, for low noise it is realy much better to have the largest amplification in the first section of the amp.
The other alternative inputs for the Asaka:
a singlet (1) of SK170BL @ 12 mA bias current: Noise Figure (NF) 7.3 dB
a triplet (3) of SK170GR @ 4 mA each: NF 5.3 dB
This JFET (or multiple) can very nicely be used in a circuit like Allen Wright's Vacuum State FVP5:
You could also opt for a step-up transformer with relatively low internal resistance. As an example the Lundahl LL 9206 (1:20) would give a NF of just 2.8 dB. Respectable at such input level! You would just have to loose some amplification further downstream. ;)
And if you want to go all the way, consider the circuit of (agian Allen's, also to be found on the same site) RTP3C, using a special low-noise bipolar junction transistor such as the 2SC3329. The biasing requirements of bipolars make a differential (in this case balanced) circuit preferable... More complicated, but it pays off, look at the numbers:
A single 2SC3329 per leg of the differential pair @ 12 mA per leg: NF = 4.0 dB
a triplet 2SC3329s @ 4 mA each: NF = 3.0 dB.
The phonostage I built uses the RTP3C scheme, with a quartet of mentioned BJTs per differential leg. With a regulated rail voltage of 330 V this circuit gives me 57 dB amplification in one stage. Oh yeah, I apply 3 dB of emitter degradation (local feedback) to improve linearity and to get the right amplification to go from 400μV to -10dBV (standard for consumer line level). This is about as far as I could go :cool:
remember to listen to lots of music!
kind regards, Mark
I used a tube MC pre-preamplifier with "success". It consisted of both halves of an E88CC parallel, no cathode resistor, Vp about 50V. The input grid resistor was 100 ohms for my cartridge, and the anode resistor in the kohm order. It was a bit noisy but very nice sound... I also tried an SRPP arrangement without resistors, it worked also well. I measured about 60 dB S/N (A-weighted), and I think it is quite difficult to obtain > 60 dB with tubes if the input signal is in the order of 0.2 ... 0.3 mV. I think the transformer or transformer+tube is the way to go.
Your math is like terminator here!:hot:
Very helpful, thanks!:)
I have to reflect a lot now before make some "disaster"!:D
P.S.: Indeed, my problem is that I listen too much hours/day with outrageous hi-end system. I am totally obsessed by hi-fi and need always better...:rolleyes:
Add the fact my ear is prodigious and I am not rich, so you can imagine because I must DIY only and avoid accurately audio-shop! :D
At the moment, we are thinking to hybrid- cascoding the first stage of our A. Loesch phono preamp.
Some times will be required ( mine friend is so slow! He is 68, eh!)
I have another idea for buiding a MC amplifier. The idea is that an MC cartridge needs low load impedance. This is why a step-up transformer is used, but what about this topology:
I tried it with a current-output DAC, but haven't tried with an MC cartridge yet. Also the turns ratio must be figured out.
Re: Re: Commitment
Hi Paolo and Laszlo (and all other phono-lovers),
I have been thinking a little about Paolo's situation. What would be a satisfying way forward?
1) Sowter 8055 1:10 with OCC wire (goood!) @ €80,= approx
2) Lundahl LL1681 1:13 @ €85,= approx
3) Lundahl LL1931 (real high end! :D ) 1:8 @ €155,= approx
The lundahls could be used parallel: parallel to better match the very low output resistance of the asaka cartridge. This is normally not rcommended practise, because of the limited magnetic coupling. At very low inputlevels though, it's useable with fine effect: wired parallel to parallel, the 1681 would be low noise (noise figure 2.4 dB) while the the 1931 would be stellar (noise figure 1.3). Of course one would need two transformers per stereo pre-pre :)
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