HP Hewlett Packard Power Supply Stereo 9 Pin PCB User Manual

Aikido Stereo 9-Pin PCB  
Revision C  
USER GUIDE  
Introduction  
Overview  
Schematics  
Recommended Configurations  
Tube Lists  
Assembly Instructions  
05/29/2008  
GlassWare  
AUDIO DESIGN  
Copyright 2006-2008© All Rights Reserved  
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2
Introduction to the Aikido  
The Aikido amplifier delivers the sonic goods. It offers low distortion, low output  
impedance, a great PSRR figure, and feedback-free amplification. The secret to its  
superb performance— in spite not using global feedback— lies in its internal symmetry,  
which balances imperfections with imperfections. As a result, the Aikido circuit works  
at least a magnitude better than the equivalent SRPP or grounded-cathode amplifier.  
For example, the Aikido circuit produces far less distortion than comparable circuits by  
using the triode’s own nonlinearity against itself. The triode is not as linear as a resistor,  
so ideally, it should not see a linear load, but a corresponding, complementary, balancing  
non-linear load. An analogy is found in someone needing eyeglasses; if the eyes were  
perfect, then perfectly flat (perfectly linear) lenses would be needed, whereas imperfect  
eyes need counterbalancing lenses (non-linear lenses) to see straight. Now, loading a  
triode with the same triode— under the same cathode-to-plate voltage and idle current  
and with the same cathode resistor— works well to flatten the transfer curve out of the  
amplifier.  
B+  
C
Rgs  
6922  
Rk  
6922  
Rk  
R15  
out  
in  
Rgs  
Rg  
6922  
Rk  
6922  
Rk  
R16  
Aikido Amplifier  
In the schematic above, the triodes are so specified for example only. Although they  
would never fit on the printed circuit board (PCBs), 211 and 845 triodes could be used  
to make an Aikido amplifier. The circuit does not rely on 6922 triodes or any other  
specific triodes to work correctly. It’s the topology, not the tubes that make the Aikido  
special. (Far too many believe that a different triode equals a different topology; it  
doesn't. Making this mistake would be like thinking that the essential aspect of being a  
seeing-eye dog rested in being a Golden Lab.)  
The Aikido circuit sidesteps power supply noise by incorporating the noise into its  
normal operation. The improved PSRR advantage is important, for it greatly unburdens  
the power-supply. With no tweaking or tube selecting, you should easily be able to get a  
-30dB PSRR figure (a conventional grounded-cathode amplifier with the same tubes  
and current draw yields only a -6dB PSRR); with some tweaking of resistor R15’s value,  
-60dB or more is possible. Additionally, unless regulated power supplies are used for  
the plate and heater, these critical voltages will vary at the whim of the power company  
and your house’s and neighbors’ house’s use, usually throwing the once fixed voltage  
relationships askew. Nevertheless, the Aikido amplifier will still function flawlessly, as it  
tracks these voltage changes symmetrically.  
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Remember, tubes are not yardsticks that never change, being more like car tires— they  
wear out. Just as a tire’s weight and diameter decrease over time, so too the tube’s  
conductance. So the fresh 6DJ8 is not the same as that same 6DJ8 after 2,000 hours of  
use. But as long as the two triodes age in the same way— which they are inclined to do,  
as they do the same amount of work and share the same materials and environment—  
the Aikido amplifier will always bias up correctly, splitting the B+ voltage between the  
triodes. Moreover, the Aikido amplifier does not make huge popping swings at start  
up, as the output does not start at the B+ and then swing down a hundred or so volts  
when the tube heats up, as it does in a ground-cathode amplifier.  
This circuit eliminates power-supply noise from the output, by injecting the same  
amount of PS noise at the top and bottom of the two-tube cathode follower circuit.  
The way it works is that the input stage (the first two triodes) define a voltage divider  
of 50%, so that 50% of the PS noise is presented to the CF's grid; at the same time the  
100k resistors also define a voltage divider of 50%, so the bottom triode's grid also  
sees 50% of the PS noise. Since both of these signals are equal in amplitude and phase,  
they cancel each other out, as each triodes sees an identical increase in plate current  
(imagine two equally strong men in a tug of war contest).  
If the output connection is taken from the output cathode follower's cathode, then the  
balance will be broken. The same holds true if the cathode follower's cathode resistor  
is removed. (Besides, this resistor actually makes for a better sounding cathode  
follower, as it linearizes the cathode follower at the expense of a higher output  
impedance. Unfortunately, it should be removed and the bypass capacitor C3 should  
be used when driving low-impedance headphones, 32-ohms for example. When used  
as a line stage amplifier, no cathode resistor bypass capacitors should be used, as these  
capacitors are very much in the signal path and very few do not damage the sound,  
unless high quality capacitors are used.)  
How do I wire up a rotary switch for switching between the two coupling  
capacitors? We need a four-pole, three-position switch and some hookup wire. All  
four coupling capacitors attach to the input contacts and the two channels of output  
can receive either coupling capacitors C1’s or C2’s or both capacitors’ outputs. The  
drawing below shows the knob on the faceplate and the rotary switch from behind.  
(The switch is shown on the "C1 + C2" position.)  
Right Output  
C1  
Lt C2  
Rt C1  
Switch Rear  
C2  
Lt C1  
Rt C2  
C1 & C2  
Left Output  
Switch Front  
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Heater Issues  
The board assumes that a DC 12V power supply will be used for the heaters, so that  
6.3V heater tubes (like the 6FQ7 and 6DJ8) or 12.6V tubes (like the 12AU7 or 12AX7)  
can be used. Both types can be used exclusively, or simultaneously; for example 6GC7  
for the input tube and a 12BH7 for the output tube. For example, if the input tube (V2  
and V3) is a 12AX7 and the output tube is a 6H30 (V1 and V4), then use jumpers J1, J5  
and J6.  
6V Heater Power Supply Although designed for a 12V power supply, a 6V heater  
power supply can be used with the PCB, as long as all the tubes used have 6.3V heaters  
(or 5V or 8V or 18V power supply can be used, if all the tubes share the same 5V or 8V  
or 18V heater voltage). Just use jumpers J1 and J4 only. Note: Perfectly good tubes with  
uncommon heater voltages can often be found at swap meets, eBay, and surplus stores  
for a few dollars each. Think outside 6.3V box. (A 25V heater power supply can be  
used, if only 12.6V tubes are used. Just use the jumper settings that are listed on the  
PCB for 6V use. For example, if the input tube [V2 and V3] is a 12AX7 and the output  
tube is a 12AU7 [V1 and V4], then use jumpers J1 and J4. )  
AC Heaters An AC heater power supply (6.3V or 12.6V) can be used, if the heater  
shunting capacitors C7, C8, C9, C10 are left off the board, or are replaced by 0.01µF  
ceramic capacitors.  
Filament Jumper Wire Schedule  
-H +H  
J3  
J1 J2  
J6  
4
J5  
V1  
V2  
V3  
V4  
5
4
5
4
5
5
4
J4  
C10  
C7  
C8  
C9  
With a 6.3V PS  
Use J2, J3, J5, and J6 only  
and all tubes must be  
6.3V types.  
With a 12.6V PS  
Output Tubes V1 and V4:  
If tubes are 6V, use J1 only.  
If tubes are 12V, use J2 and J3 only.  
Input Tubes V2 and V3:  
If tubes are 6V, use J4 only.  
If tubes are 12V, use J5 and J6 only.  
Do not use capacitors, C7, C8, C9, or C10 with an AC heater PS  
Since one triode stands atop another, the heater-to-cathode voltage experienced differs  
between triodes. The safest path is to reference the heater power supply to a voltage  
equal to one fourth the B+ voltage; for example, 75V, when using a 300V power supply.  
The ¼ B+ voltage ensures that both top and bottom triodes see the same magnitude of  
heater-to-cathode voltage. The easiest way to set this voltage relationship up is the  
following circuit:  
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B+  
B+  
DC  
Heater  
PS  
300k  
2W  
300k  
2W  
AC  
B+  
4
B+  
4
0.1µF  
250V  
0.1µF  
250V  
100k  
1/2W  
100k  
1/2W  
Alternatively, you might experiment with floating the  
heater power supply, by “grounding” the heater power  
supply via only a 0.1µF film or ceramic capacitor. The  
capacitor will charge up through the leakage current  
between heater and cathodes. Not only is this method  
cheap, it is often quite effective in reducing hum.  
100  
100  
B+  
4
Power Supply  
The power supply is external to the Aikido PCB and can be mounted in, or outside,  
the chassis that houses the PCB. The optimal power supply voltage depends on the  
tubes used. For example, 6GM8s (ECC86) can be used with a low 24V power supply,  
while 6FQ7s work better with a 250-300V B-plus voltage. The sky is not the limit here,  
as the heater-to-cathode voltage sets an upward limit of about 400V.  
The genius of the Aikido circuit is found in both its low distortion and great PSRR  
figure. Nonetheless, a good power supply helps (there is a practical limit to how large a  
power-supply noise signal can be nulled). I recommend you use at least a solid, choke-  
filtered tube or fast-diode rectified power supply. If you insist on going the cheap  
route, try the circuit below, as it yields a lot of performance for little money. FRED  
rectifiers are expensive, but make an excellent upgrade to the lowly 1N4007.  
.01µF  
1KV  
.01µF  
1KV  
100mA  
high-DCR  
.01µF  
1KV  
.01µF  
1KV  
All Diodes = 1N4007  
All Resistors = 1 ohm 1/2W  
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Jumper J7 connects the PCB’s ground to the chassis through the top centermost  
mounting hole. If you wish to float the chassis or capacitor couple the chassis to ground,  
then either leave jumper J7 out or replace it with a small-valued capacitor (0.01 to  
0.1µF). Warning: if rubber O-rings are used with PCB standoffs, then the ground  
connection to the chassis is not likely to be made.  
Tube Selection  
Unlike 99.9% of tube circuits, the Aikido amplifier defines a new topology without fixed  
part choices, not an old topology with specified part choices. In other words, an Aikido  
amplifier can be built in a nearly infinite number of ways. For example, a 12AX7 input  
tube will yield a gain close to 50 (mu/2), which would be suitable for a phono preamp or  
a SE amplifier’s input stage; a 6FQ7 (6CG7) input tube will yield a gain near 10, which  
would be excellent for a line stage amplifier; the 6DJ8 or 6H30 in the output stage  
would deliver a low output impedance that could drive capacitance-laden cables or even  
high-impedance headphones. In other words, the list of possible tubes is a long one:  
6AQ8, 6BC8, 6BK7, 6BQ7, 6BS8, 6DJ8, 6FQ7, 6GC7, 6H30, 6KN8, 6N1P, 12AT7,  
12AU7, 12AV7, 12AX7, 12BH7, 12DJ8, 12FQ7, 5751, 5963, 5965, 6072, 6922,  
E188CC, ECC88, ECC99… The only stipulations are that the two triodes within the  
envelope be similar and that the tube conforms to the 9A or 9AJ base pin-out. Sadly, the  
12B4 and 5687 cannot be used with this PCB.  
Internal Shields  
If the triode’s pin 9 attaches to an internal shield, as it does with the 6CG7 and 6DJ8,  
then capacitors, C11 and C12 can be replaced with a jumper, which will ground the  
shield. However, using the capacitors will also ground the shield (in AC terms) and allow  
using triodes whose pin-9 attaches to the center tap of its heater, such as the 12AU7.  
Cathode Resistor Values  
The cathode resistor sets the idle current for the triode: the larger the value of the  
resistor, the less current. In general, high-mu triodes require high-value cathode resistors  
(1-2K) and low-mu triodes require low-valued cathode resistors (100-1k). I recommend  
running the output tubes hotter than the input tubes; or put differently, run the input  
tubes cooler than the output tubes. Interestingly enough, a lower idle current for the  
input stage does not seem to incur the same large increase in distortion that one would  
expect in other topologies (a testament to the Aikido’s principle of symmetrical loading).  
For example, 1k cathode resistors for the input tube (V2 and V3) and 300-ohm resistors  
for the output tubes (V1 and V4), when using 6FQ7s or 6CG7s throughout. Thus, the  
output tubes will age more quickly than the input tubes, so rotating output for input  
tubes can extend the useful life of the tubes.  
Capacitor C3 allows the bottom output triode’s cathode resistor to be bypassed, when  
resistor R8 is replaced with a jumper wire; this arrangement is useful when driving low-  
impedance loads, such as 300-ohm or 32-ohm headphones, as it provides the lowest  
possible output impedance from the Aikido amplifier. If used, C3 should be at least a  
1kµF capacitor. On the other hand, if high-capacitance cable is to be driven, use a  
higher idle current and retain the cathode resistor, R8, and leave capacitor C3 off.  
Current is more important than the lowest possible output impedance.  
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Configuring the PCB as a Line Amplifier  
The Aikido topology makes a perfect line amplifier, as it offers low distortion, low  
output impedance, and excellent power-supply noise rejection— all without a global  
feedback loop. The key points are not to use capacitor C3. For guidance on part  
values, look at the page 12, which lists several line-amplifier design examples.  
Calculating R15’s value is easy; it equals R16 against [(mu -2)/(mu + 2)]. For example,  
a triode with a mu of 20 results in R15 = 100k x (20 – 2)/(20 + 2) = 81.8k (82k)  
B+  
R6  
C5  
C6  
R7  
R9  
C1  
C2  
out  
R4  
R8  
J8 (J9)  
out  
R15  
R16  
in  
R3  
R10  
C12  
C11  
R1  
R2  
R5  
R12 R13  
R14  
C3  
R11  
(input) V2, V3  
(output) V1, V4  
() Parentheses denote recommended values  
Typical Part Values  
6CG7 & 6DJ8  
6CG7 & 6CG7  
12AU7 & 12AU7  
12AU7 & 12BH7  
B+ Voltage =  
Heater Voltage =  
170V - 250V (200V)  
6.3V  
200V - 300V (300V)  
6.3V  
200V - 300V (250V)  
12.6V  
200V - 300V (300V)  
12.6V  
R1,5,6,7,12,13,14 =  
R2,4 =  
1M  
1M  
1M  
1M  
270 - 1k (470)*  
100 - 1k (300)*  
200 - 330 (200 10mA)*  
87.5k  
470 - 2k (870)*  
Same  
270 - 680 (270)*  
83.2k  
470 - 2k (680)*  
Same  
180 - 470 (200)*  
80k  
470 - 2k (1k)*  
Same  
200 - 470 (523)*  
79.3k  
R3,9,10 =  
R8,11 =  
R15 =  
R16 =  
100k  
Same  
Same  
Same  
*High-quality resistors essential in this position  
All resistors 1/2W or higher  
C1 =  
C2 =  
0.1 - 4µF* Film  
0.1 - 4µF* Oil  
Same  
"
Same  
"
Same  
"
C3 =  
none  
"
"
"
C5 =  
C6 =  
C7,8,9,10 =  
C11,12 =  
1 - 10µF* Film or Oil  
0.1 - 1µF* Film or Oil  
47µF - 1kµF, 16V  
0.1µF 160V(optional)  
"
"
"
"
"
"
"
"
"
Same  
None  
None  
*Voltage rating must equal or exceed B+ voltage  
(input) V2, V3 =  
(output) V1, V4=  
6CG7, 6FQ7  
6CG7, 6FQ7  
6CG7, 6FQ7  
12AU7, 5814, 5963,  
6189, ECC82  
12AU7, 5814, 5963,  
6189, ECC82  
6DJ8, 6922,  
7308, E88CC  
12AU7, 5814, ECC82  
12BH7, ECC99  
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Configuring the PCB as a Headphone Amplifier  
The standard Aikido is a thoroughly single-ended affair, nothing pulls while something  
else pushes. Unfortunately, wonderful as single-ended mode is sonically, it cannot  
provide the larger voltage and current swings that a push-pull output stage can. Single-  
ended stages can only deliver up to the idle current into a load, whereas class-A push-  
pull stages can deliver up to twice the idle current; and class-AB output stages can  
deliver many times the idle current. For a line stage, such big voltage and current swings  
are seldom required; headphones, on the other hand, do demand a lot more power;  
really, a 32-ohm load is brutally low impedance for any tube to drive. Unfortunately, a  
heavy idle current is needed to ensure large voltage swings into low-impedance loads.  
B+  
C5  
R6  
C6  
R7  
R9  
C1  
C2  
out  
R4  
R8  
J8 (& J9)  
R15  
R16  
in  
R3  
R10  
R1 C11  
R2  
R5 C12  
R11  
C3  
R12 R13  
R14  
High transconductance output tubes are best for driving headphones, for example, the  
6DJ8, 6H30, 12BH7, and ECC99. A coupling capacitor of at least 33µF is required  
when driving 300-ohm headphones; 330µF for 32-ohm headphones. Use a high-quality,  
small-valued bypass capacitor in C2’s position. Capacitor C3 can be bypassed by placing  
a small film capacitor across the leads of resistor R11.  
Right HP  
output  
Left Line Output  
Line  
Lt C2  
Rt C1  
Mute  
Lt C1  
Rt C2  
Headphones  
Right Line Output  
Left HP  
Switch Front  
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() Parentheses denote recommended values  
Typical Part Values  
6CG7 & 6DJ8  
6CG7 & 6CG7  
12AU7 & 6H30  
B+ Voltage =  
Heater Voltage =  
170V - 250V (250V)  
6.3V or 12.6V  
200V - 300V (300V)  
6.3V or 12.6V  
200V - 300V (150V)  
12.6V  
R1,5,6,7,12,13 =  
R2,4 =  
1M  
1M  
1M  
270 - 1k (640 5mA)*  
100 - 1k (300)*  
200 - 330 (291 10mA)*  
87.3k  
470 - 2k (640 5mA)*  
100 - 1k (300)*  
200 - 470 (240 10mA)*  
83.2k  
470 - 2k (741 3mA)*  
100 - 1k (300)*  
200 - 470 (74 30mA)*  
76.5k  
R3,9,10 =  
R8,11 =  
R15 =  
R16 =  
100k  
100k  
1 00k  
*High-quality resistors essential in this position  
All resistors 1/2W or higher  
C1 =  
47µF* Film for 300-ohm HP  
470µF* for 32-ohm HP  
0.47µF* Film or oil  
Same  
Not recommended  
Same  
Same  
470µF* for 32-ohm HP  
Same  
C2 =  
C3 =  
10 - 1kµF, 10V Electrolytic "10 - 1kµF, 16V Electrolytic  
C5 =  
1 - 10µF*  
"
"
C6 =  
C7,8,9,10 =  
C11,12 =  
0.047µF - 1µF* Film or oil  
10µF-1kµF, 16V Electrolytic  
0.1µF 160V(optional)  
"
"
"
"
Same  
None  
*voltage rating must equal or exceed B+ voltage  
(input) V2, V3 =  
(output) V1, V4 =  
6CG7, 6FQ7  
6CG7, 6FQ7  
6CG7, 6FQ7  
12AU7, 5814, 5963,  
6189, ECC82  
6DJ8, 6922,  
7308, ECC88  
6H30  
Assembly  
Before soldering, be sure to clean both sides of the PCB with 90% isopropyl alcohol,  
wiping away all fingerprints. First, solder the shortest parts (usually the resistors) in  
place, then the next tallest parts, and then the next tallest... Make sure that both the  
solder and the part leads are shiny and not dull gray. Steel wool can restore luster and  
sheen by rubbing off oxidation. If some of the parts have gold-plated leads, remove  
the gold flash before soldering the part, as only a few molecules of gold will poison a  
solder joint, making it brittle; use sandpaper, steel wool, or a solder pot. NASA forbids  
any gold-contaminated solder joints; you should as well. (Yes, there are many quality  
parts with gold-flashed leads, but the use of gold is a marketing gimmick.)  
Normally, such as when the PCB sits on the floor of its chassis, all the parts sit on the  
top side of the PCB (the top side is marked). If you wish to have the tubes protrude  
from holes on the top of the chassis (and to place the PCB within 1" of the top panel  
with the aid of standoffs), then all the other parts— except the tube sockets— can be  
placed on the PCB’s backside; it is a double-sided board after all (be sure to observe  
the electrolytic capacitors' polarity and glue or tie-wrap heavy coupling capacitors to  
the PCB).  
Let me know what you think  
If you would like to see some new audio PCB or kit or recommend a change to an  
existing product or if you need help figuring out the heater jumper settings or cathode  
resistor values, drop me a line by e-mail to the address above (begin the subject line  
with either “Aikido” or “tube”).  
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R 1 2  
R 1 3  
R 1 4  
R 1 6  
R 1 4  
R 1 3  
R 1 2  
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12  
Input  
Input  
Output Output Zo Line Zo HP  
Tube  
B+  
Ik(mA)  
10.0  
10.0  
10.0  
10.0  
3.0  
5.0  
5.0  
4.5  
7.3  
10.0  
10.0  
5.0  
10.0  
10.0  
10.0  
5.0  
mu  
rp  
Rk  
100  
200  
191  
220  
583  
397  
626  
1000  
470  
243  
352  
182  
124  
205  
291  
673  
845  
481  
R15  
R16  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
R17  
170  
107  
155  
139  
498  
425  
440  
473  
391  
344  
352  
122  
93  
Gain Gain dBs Gain  
in dBs  
-0.24  
-0.27  
-0.32  
-0.33  
-0.59  
-0.59  
-0.56  
-0.53  
-0.56  
-0.60  
-0.57  
-0.39  
-0.39  
-0.37  
-0.36  
-0.35  
-0.34  
-0.35  
Amp.  
248  
279  
311  
321  
827  
657  
820  
1063  
686  
489  
576  
273  
199  
274  
350  
667  
787  
511  
Amp  
85  
53  
78  
69  
249  
212  
220  
237  
196  
172  
176  
61  
47  
49  
52  
70  
72  
59  
6AQ8  
6BK7  
6BQ7  
6BS8  
6CG7  
6CG7  
6CG7  
6CG7  
6CG7  
6CG7  
6CG7  
6DJ8  
6DJ8  
6DJ8  
6DJ8  
6DJ8  
6DJ8  
6DJ8  
300V  
300V  
300V  
300V  
150V  
200V  
250V  
300V  
300V  
300V  
350V  
100V  
150V  
200V  
250V  
250V  
300V  
300V  
57.0  
43.0  
38.0  
36.0  
20.5  
21.1  
21.0  
20.8  
21.4  
21.9  
21.8  
30.2  
30.7  
30.0  
29.6  
28.6  
28.3  
28.9  
9700  
4600  
5900  
5000  
10200  
8960  
9250  
9840  
8370  
7530  
7680  
3670  
2870  
2960  
3060  
3980  
4080  
3400  
93.2k  
91.1k  
90.0k  
89.5k  
82.2k  
82.7k  
82.6k  
82.5k  
82.9k  
83.3k  
83.2k  
87.6k  
87.8k  
87.5k  
87.3k  
86.9k  
86.8k  
87.1k  
28.1  
21.2  
18.7  
17.8  
10.0  
10.4  
10.3  
10.1  
10.5  
10.8  
10.7  
15.0  
15.2  
14.9  
14.6  
14.0  
13.8  
14.2  
29.0  
26.5  
25.5  
25.0  
20.0  
20.3  
20.2  
20.1  
20.4  
20.7  
20.6  
23.5  
23.7  
23.4  
23.3  
22.9  
22.8  
23.0  
0.97  
0.97  
0.96  
0.96  
0.93  
0.93  
0.94  
0.94  
0.94  
0.93  
0.94  
0.96  
0.96  
0.96  
0.96  
0.96  
0.96  
0.96  
99  
103  
139  
144  
118  
5.0  
8.0  
6FQ7  
6GM8  
6H30  
6H30  
6H30  
See 6CG7 and 6SN7  
24V  
2.0  
20.0  
30.0  
20.0  
20.0  
15.0  
3.0  
5.0  
5.0  
2.0  
14.0  
15.4  
15.9  
15.4  
15.4  
15.0  
39.8  
36.0  
35.0  
14.0  
3400  
1140  
1040  
1310  
1380  
1670  
12200  
9480  
956  
187  
69  
74  
221  
294  
530  
328  
221  
642  
187  
75.0k  
77.0k  
77.7k  
77.0k  
77.0k  
76.5k  
90.4k  
89.5k  
89.2k  
75.0k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
243  
74  
65  
85  
90  
111  
307  
263  
27  
7.0  
7.7  
7.9  
7.7  
7.7  
16.8  
17.7  
18.0  
17.7  
17.7  
17.4  
25.8  
25.0  
24.7  
16.8  
0.90  
0.91  
0.92  
0.92  
0.93  
0.93  
0.96  
0.96  
0.97  
0.90  
-0.90  
-0.80  
-0.75  
-0.68  
-0.66  
-0.65  
-0.32  
-0.36  
-0.25  
-0.90  
357  
127  
124  
267  
330  
528  
539  
422  
569  
357  
121  
37  
33  
43  
45  
100V  
150V  
200V  
250V  
300V  
200V  
250V  
300V  
24V  
6H30  
6H30  
7.4  
56  
6N1P  
6N1P  
6N1P  
6N27P  
9AQ8  
12AT7  
12AU7  
12AU7  
12AU7  
12AU7  
12AU7  
12AV7  
12AV7  
19.4  
17.7  
17.1  
7.0  
153  
132  
14  
3400  
243  
121  
See 6AQ8  
200V  
100V  
150V  
200V  
3.7  
2.5  
3.0  
4.0  
8.0  
60.0  
17.0  
16.6  
16.7  
17.9  
18.1  
37.0  
41.0  
15000  
9560  
9570  
9130  
7440  
7120  
6100  
4800  
270  
427  
741  
768  
336  
328  
120  
56  
93.5k  
78.9k  
78.5k  
78.6k  
79.9k  
80.1k  
89.7k  
90.7k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
250  
562  
577  
547  
416  
393  
165  
117  
29.1  
8.4  
8.1  
8.2  
8.8  
8.9  
18.3  
20.4  
29.3  
18.4  
18.2  
18.2  
18.9  
19.0  
25.3  
26.2  
0.98  
0.92  
0.92  
0.92  
0.92  
0.92  
0.96  
0.96  
-0.21  
-0.75  
-0.71  
-0.69  
-0.71  
-0.70  
-0.36  
-0.35  
457  
757  
959  
959  
601  
581  
258  
160  
125  
281  
288  
273  
208  
197  
82  
250V  
300V  
200V  
300V  
10.0  
9.0  
18.0  
59  
12AZ7 See 12AT7  
12AX7  
12AX7  
12BH7  
12BH7  
12BH7  
12BH7  
12BH7  
12BZ7  
200V  
300V  
100V  
150V  
200V  
250V  
300V  
300V  
0.5  
1.0  
4.0  
4.0  
5.0  
100.0  
100.0  
16.1  
15.7  
15.9  
17.4  
18.4  
100.0  
80000  
62500  
5480  
6090  
6140  
4870  
4300  
31800  
2000  
1100  
340  
706  
787  
383  
267  
96.1k  
96.1k  
77.9k  
77.4k  
77.7k  
79.4k  
80.4k  
96.1k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
800  
625  
340  
388  
386  
280  
234  
318  
39.0  
42.6  
8.0  
7.7  
7.8  
8.6  
9.1  
48.5  
31.8  
32.6  
18.0  
17.7  
17.8  
18.7  
19.2  
33.7  
0.99  
0.99  
0.92  
0.92  
0.92  
0.93  
0.93  
0.98  
-0.11  
-0.12  
-0.76  
-0.71  
-0.68  
-0.67  
-0.65  
-0.17  
1719  
1238  
549  
826  
877  
541  
422  
292  
400  
313  
170  
194  
193  
140  
117  
159  
10.0  
15.0  
12DJ8 See 6DJ8  
12FQ7 See 6SN7  
5687  
5687  
5687  
5687  
5751  
5963  
5965  
6072  
7119  
150V  
200V  
250V  
300V  
200V  
250V  
300V  
300V  
300V  
24.0  
20.0  
20.0  
15.0  
0.8  
10.0  
8.2  
2.0  
18.1  
17.5  
17.4  
16.9  
70.0  
21.0  
47.0  
44.0  
21.7  
1760  
1970  
2060  
2440  
58000  
6600  
7250  
25000  
2390  
37  
132  
198  
397  
1250  
200  
220  
1250  
324  
80.1k  
79.5k  
79.4k  
78.8k  
94.4k  
82.6k  
91.8k  
91.3k  
83.1k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
100k  
97  
9.0  
8.7  
8.7  
19.1  
18.8  
18.7  
18.5  
29.7  
20.3  
27.3  
26.2  
20.6  
0.91  
0.92  
0.93  
0.93  
0.98  
0.93  
0.97  
0.97  
0.95  
-0.78  
-0.68  
-0.65  
-0.62  
-0.17  
-0.63  
-0.26  
-0.25  
-0.48  
119  
216  
276  
455  
1407  
433  
337  
1272  
377  
49  
56  
59  
113  
118  
144  
829  
314  
154  
568  
110  
8.4  
72  
30.5  
10.4  
23.1  
20.3  
10.7  
414  
157  
77  
284  
55  
15.0  
ECC81 See 12AT7  
ECC82 See 12AU7  
ECC83 See 12AX7  
ECC85 See 6AQ8  
ECC86 See 6GM8  
The table above lists many triodes suitable for the 9-pin-based Aikido amplifier PCB. The table lists the same  
tube under different B+ voltages and with different cathode resistor values. Two gains are listed: the first is  
the gain the tube realizes in the input position in the Aikido; the second is the gain of the same tube in the  
output stage. To calculate the final gain multiply the two voltage gains together (or add the gain in dBs  
together). For example, given an Aikido line amplifier with a B+ voltage of 300V, and a 6CG7 input tube  
with cathode resistors of 1k, and a 6DJ8 output tube with cathode resistors of 481 ohms, the final voltage  
gain equals 10.1 from the 6CG7 against the 0.96 gain of the 6DJ8, with a product of 9.7. or, working with dB  
instead, 20.1dB plus -.35dB, for a total of 19.75dB. (Aren’t decibels great?)  
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