In part 1 we looked at design of the 2A3 output stage of this amplifier, that was a very, very long time ago. Now we'll look at the D3a driver.
The Driver Stage
Output Stage Recap
If you remember, our operating point is 250V and 60mA, with a grid bias of -43.5V.
As this is a class A1 design the 2A3's grid should remain negative at all times (i.e. to the right of the red curve) so for full output the grid swings down from its bias point of -43.5V to 0V (and up to -87V). The driver is a common cathode stage, so the driver needs to swing + and - 43.5V on its anode, which is coupled to the 2A3 grid via a capacitor. Capacitors block DC voltage - we'll talk about this capacitor later.
Driver Stage Considerations
And we perhaps might prefer a little more sensitivity than + or - 2.83V, and + or - 1V gives us plenty of "welly" on the volume control. So let's aim for an overall gain in the region of 40.
It's not just a question of choosing a valve with the appropriate amplification factor, it has to be able to actually swing those volts too! And ideally we'd like it to have plenty of headroom i.e. some more swing in hand so it's not up against its limits and clip.
We also want to minimise distortion so might want to aim for areas of the anode curves with equally spaced grid voltage curves. (However, as the amplifier is the result of two stages, both stages have to be considered together as a combined system if we want to fine tune minimum distortion. But that would need some test equipment and is beyond the scope of this blog.)
And of course we need to obey the safe operating characteristics of the valve.
The D3a
So back to the D3a. It's a "special quality" pentode that was used for telecommunications. Here's the datasheet. Pentodes are generally newer than triodes (which is somewhat relative these days!) but can make good drivers as they typically have higher gain than triodes. Sometimes too high. But they can be wired as triodes with lower gain, and some think they can sound better this way.
Not all pentode datasheets contain triode connected info but fortunately the D3a does. Looking at page 3 the triode amplification factor is given as 77, so ~70% is a real world gain of about 50, which is nice. Now let's look at the second graph on page 7 for the average anode characteristics.
The curves look rather like the 2A3, but the values of voltage and current are very different. That's because this is a signal valve rather than an output valve.
The Operating Point
So let's look at the operating point and start with the safe operating requirements, see page 5 of the datasheet. Helpfully the maximum anode power dissipation of 4.5W is already shown on the datasheet graph. In addition we want to stay to the right of the 0V grid line, and not exceed the maximum anode voltage of 220V and maximum anode current of 30mA. So here's the graph again, with the safe operating zone shown.
Now we can choose our operating point. We want to swing 2 x 43.5 = 87V peak to peak on the anode, and we want a nice place on the grid voltage curves with equal spacing to minimise harmonic distortion. But also, unless we're going to have a separate power supply we need to bear in mind the B+ supply voltage that we determined in our output stage design.
Now if we go back to our 2V RMS input voltage from a CD player, which is 5.66V peak to peak, if we look at the curves above we can't adequately bias our valve for this swing - the grid voltage curves only go as far as -3V. In reality we would need a meatier driver.
But it's not necessary to swing the full 5.66V - music rarely reaches the full 2V RMS. If we go for 2V peak to peak then the amp will have decent sensitivity. So let's bias the valve to the right of the 1V curve. This does mean of course that there is the potential danger that at full bore the amp could overdrive, but in reality the volume control would never be turned up that high to permit the full 2V RMS swing in a well balanced setup system.
Now it's an iterative process of looking at operating point and anode loadline. An operating point of 150V and 20mA, which is a grid voltage of approximately -1.38V, looks a decent compromise. You can see I've sketched in the approximate -1.38V line at the operating point.
Loadline and Anode Load
When we looked at the output stage we went with the datasheet loadline of 2500 ohms, which is approximately 3x the anode resistance. Our choices for a driver are slightly different as the higher the load resistance generally the better as it will tend to reduce distortion. But the higher the load resistance (i.e. the larger value of the anode resistor) the more voltage will be dropped across it, which in turn means the higher the required B+ voltage.The datasheet for a triode connected D3a gives the internal resistance as 1900 ohm. If we apply the 3 x rule: 3 x 1900 = 5700 ohms. So we're looking for a resistor of at least 5700 ohms, and ideally we want to use a standard value with suitable rating. So 6800 ohms looks pretty good, and the power dissipated in it will be the current squared x the resistance, so 0.02^2 x 6800 = 2.7W. We derate by 3 x to 5 x, so we actually want a 6800 ohms resistor rated between 8W and 13W, maybe a nice 12W Mills again.
The loadline is shown in magenta, and the thicker section shows the swing about the operating point - up to a maximum of -2.56V where the maximum allowable anode voltage of 220V occurs. As the grid voltage can swing up from -1.38V to -2.56V (1.18V) it therefore swings down to -1.38 - -1.18 = -0.2V.
Now if we look at the anode voltages at these points on the grid voltage we can see the anode voltage will swing up to 220V and down to 75V i.e. -75V and +70V from the operating point. Ideally those values would be the same as the difference reflects a little distortion - that's the consequence of unequally spaced grid lines. But a difference of 5V is pretty good in reality.
If we now think back to our 2A3 we need + and - 43.5V swing on its grid, and the D3a as we have it configured here can swing +70V and -75V, more than actually required. But as most music is recorded with less than 2V RMS, in reality we'll be able to use more of the volume control, without needing a pre stage. And if the music is too loud so the driver stage starts to clip it will sound a little unpleasant and the volume will inevitably be turned down.
Cathode Resistor
Cathode Resistor Bypass Capacitor
Right, time for some more maths again. First let's work out the cathode resistance (check back to the 2A3 page for more explanation):
rk = (ra + Rl) / (mu +1) = (1900 + 6800) / (77 + 1) = 112 ohms
So R = 1 / ((1 / rk) + (1 / Rk)) = 1 / (1/112 + 1/68) = 1 / (0.0089 + 0.0147) = 42.4 ohms
As this is a driver stage and earlier in the reproduction chain we should aim for a much lower f-3 frequency than the output stage as once the bass frequencies have been lost they can't be magiced back. 1Hz isn't unusual.
And therefore C = 1 / (2 x pi x f-3 x R) = 1 / (2 x 3.142 x 1 x 42.4) = 3754uF.
Which is a big capacitor. But I had some Panasonic 2200uF electrolytics which gives an f-3 of less than 2Hz. Still lots of uF, but not unreasonable.
As the voltage at the cathode is approximately 1.38V a capacitor rating of 5V is fine.
Grid Leak Resistor
The datasheet suggests 500k ohms as a maximum, I went with 100k ohms, 1W is more than adequate.
Grid Stopper and Screen Tie Resistors
There are two more resistors that are very important. The first is called a grid stopper and is soldered as close to the valve socket pin for the control grid (G1) as possible. This stops valves oscillating. Higher gain valves, like the D3a have a habit of oscillating which is a bad thing. You might not audibly recognise oscillation but it will affect the sound to some degree. Sometimes it can be present but at very high frequencies, much higher than we can hear, but it can still have an affect on the music. A value somewhere between 300R and 2200R usually does the job. I used 1000R, and half a watt will be adequate.
The other resistor ties the screen grid (the middle of the three in a pentode) to the anode. This is what make the valve work like a triode rather than a pentode. 1000R half watt again.
Capacitor Coupling the Two Stages
Now we have the basic design of the driver stage we need to consider how we couple the driver stage to the output stage. The signal is taken from the anode of the D3a so we know the voltage there is 150V (our D3a operating point) plus the voltage we have raised the cathode by (1.38V) so ~151V. If we were to attach the anode of the D3a directly to the grid of the 2A3 there would be 151V on the 2A3 grid, which would be a very bad thing. Remember, from our 2A3 design there's 0V on the grid, -45V relative to the cathode, so applying 151V wouldn't do the 2A3 any good at all.
So we need a way to ensure this doesn't happen. The three usual methods are capacitor coupling, interstage transformer coupling, and direct coupling. Capacitor coupling is the most common, and for good reason; it's the easiest to implement. And whilst some say other methods sound better others are inclined not to agree; you need to build for yourself and see what you think. Capacitor coupling works in this application because capacitors block constant voltage but allow changes in voltage to pass, so using a capacitor blocks the 151V but allows the signal to pass to the 2A3 grid. We just need to work out how big a capacitor we need.
Whilst almost any capacitor would block the 151V on the D3a anode the coupling capacitor forms a high-pass filter with the 2A3 grid resistor, so if the value is too low the f-3 corner frequency could be too high and we would lose our bass again.
The high pass filter capacitor value is given by:
Using the 40Hz f-3 we designed the 2A3 stage for gives:
C = 1 / (2 x 3.142 x 40 x 100000) = 0.4uF
0.4uF isn't a common value, but 0.47uF is. And it has the advantage that as it is slightly larger it drops the f-3 frequency to around 34Hz. Whilst beneficial as it drops the high pass filter a few Hz it also doesn't compound high pass filters at the same frequency, which wouldn't be ideal in some respects.
Capacitor Coupling the Two Stages
Now we have the basic design of the driver stage we need to consider how we couple the driver stage to the output stage. The signal is taken from the anode of the D3a so we know the voltage there is 150V (our D3a operating point) plus the voltage we have raised the cathode by (1.38V) so ~151V. If we were to attach the anode of the D3a directly to the grid of the 2A3 there would be 151V on the 2A3 grid, which would be a very bad thing. Remember, from our 2A3 design there's 0V on the grid, -45V relative to the cathode, so applying 151V wouldn't do the 2A3 any good at all.
So we need a way to ensure this doesn't happen. The three usual methods are capacitor coupling, interstage transformer coupling, and direct coupling. Capacitor coupling is the most common, and for good reason; it's the easiest to implement. And whilst some say other methods sound better others are inclined not to agree; you need to build for yourself and see what you think. Capacitor coupling works in this application because capacitors block constant voltage but allow changes in voltage to pass, so using a capacitor blocks the 151V but allows the signal to pass to the 2A3 grid. We just need to work out how big a capacitor we need.
Whilst almost any capacitor would block the 151V on the D3a anode the coupling capacitor forms a high-pass filter with the 2A3 grid resistor, so if the value is too low the f-3 corner frequency could be too high and we would lose our bass again.
The high pass filter capacitor value is given by:
capacitance (farads) = 1 / (2 x pi x corner frequency f-3 (hertz) x resistance (ohms))
C = 1 / (2 x pi x f-3 x R)
C = 1 / (2 x 3.142 x 40 x 100000) = 0.4uF
0.4uF isn't a common value, but 0.47uF is. And it has the advantage that as it is slightly larger it drops the f-3 frequency to around 34Hz. Whilst beneficial as it drops the high pass filter a few Hz it also doesn't compound high pass filters at the same frequency, which wouldn't be ideal in some respects.
But you could also choose to use a 1uF coupling capacitor which would drop f-3 to 17Hz. This is perhaps a nicer place to be, but it requires a bigger value capacitor, and some audibly prefer smaller. More capacitance generally costs more too.
There is roughly 151V across this capacitor so the capacitor needs a higher voltage rating. Generally, you want to be using a nice film capacitor here. Some swear by paper in oil, others prefer PP. But most film capacitors used in valve amplifiers are rated for 630V, some 250V, so more than adequate.
There is roughly 151V across this capacitor so the capacitor needs a higher voltage rating. Generally, you want to be using a nice film capacitor here. Some swear by paper in oil, others prefer PP. But most film capacitors used in valve amplifiers are rated for 630V, some 250V, so more than adequate.
Volume Control
This just leaves the volume pot. There is a balance to be struck here, 50k is pretty good but others can be used.
And now it's confession time. It's so long since I first started preparing these two blogs I've lost the drawing file somewhere on an old computer which had the circuits and values :-(. But if you've made it this far then you have enough persistence to fill the values in for yourself :-). So no final glory shot of the full amp circuit, but who knows, maybe in another seven years I might do a blog about the power supply...
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