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Why not Wye?
By Dennis A. Bohn |
Wye-connectors (or "Y"-connectors, if you prefer) should
never have been created.
Anything that can be hooked-up wrong, will be. You-know-who said
that, and she was right. A wye-connector used to split a
signal into two lines is being used properly; a wye-connector used
to mix two signals into one is being abused and may even
damage the equipment involved.
Here is the rule: Outputs are low impedance and must only be connected
to high impedance inputs -- never, never tie two outputs
directly together -- never. If you do, then each output tries to
drive the very low impedance of the other, forcing both outputs
into current-limit and possible damage. As a minimum, severe signal
loss results.
Monoing Your Low End
One of the most common examples of tying two outputs together is
in "monoing" the low end of multiway active crossover
systems. This combined signal is then used to drive a sub-woofer
system.
Since low frequencies below about 100Hz have such long wavelengths
(several feet), it is very difficult to tell where they are coming
from (like some of your friends). They are just there -- everywhere.
Due to this phenomenon, a single sub-woofer system is a popular
cost-effective way to add low frequency energy to small systems.
So the question arises as how best to do the monoing, or summing,
of the two signals? It is done very easily by tying the two low
frequency outputs of your crossovers together using the resistive
networks described below. You do not do it with a wye-cord.
Unbalanced Summing Box
Figure 1 (below) shows the required network for sources with
unbalanced outputs. Two resistors tie each input together to the
junction of a third resistor, which connects to signal common. This
is routed to the single output jack. The resistor values can vary
about those shown over a wide range and not change things much.
Figure 1
As designed, the input impedance is about 1k ohms and the line driving
output impedance is around 250 ohms. The output impedance is small
enough that long lines may still be driven, even though this is
a passive box. The input impedance is really quite low and requires
600 ohm line-driving capability from the crossover, but this should
not create problems for modern active crossover units.
The rings are tied to each other, as are the sleeves; however, the
rings and sleeves are not tied together. Floating the output in
this manner makes the box compatible with either balanced or unbalanced
systems. It also makes the box ambidextrous:
It is now compatible with either unbalanced (mono, 1-wire) or balanced
(stereo, 2-wire) 1/4-inch cables. Using mono cables shorts the ring
to the sleeve and the box acts as a normal unbalanced system; while
using stereo cables takes full advantage of the floating benefits.
Balanced Summing Boxes
Figures 2 and 3 show wiring and parts for creating a balanced
summing box. The design is a natural extension of that appearing
in Figure 1. Here both the tip (pin 2, positive) and the ring (pin
3, negative) tie together through the resistive networks shown.
Use at least 1% matched resistors. Any mismatch between like-valued
resistors degrades the common-mode rejection capability of the system.
Figure 2
Figure 3
Termites in the Woodpile
Life is wonderful and then you stub your toe. The corner of the
dresser lurking in the night of this Note has to do with applications
where you want to sum two outputs together and you want to
continue to use each of these outputs separately. If all you want
to do is sum two outputs together and use only the summed results
(the usual application), skip this section.
The problem arising from using all three outputs (the two original
and the new summed output) is one of channel separation, or crosstalk.
If the driving unit truly has zero output impedance, than channel
separation is not degraded by using this summing box.
However, when dealing with real-world units you deal with finite
output impedances (ranging from a low of 47 ohms to a high of 600
ohms). Even a low output impedance of 47 ohms produces a startling
channel separation spec of only 27 dB, i.e., the unwanted channel
is only 27 dB below the desired signal.
(Technical details: the unwanted channel, driving through the summing
network, looks like 1011.3 ohms driving the 47 ohms output impedance
of the desired channel, producing 27 dB of crosstalk.)
Now 27 dB isn't as bad as first imagined. To put this into perspective,
remember that even the best of the old phono cartridges had channel
separation specs of about this same magnitude. Therefore stereo
separation is maintained at about the same level as a high-qualifty
hi-fi home system of the '70s.
For professional systems this may not be enough. If a trade-off
is acceptable, things can be improved. If you scale all the resistors
up by a factor of 10, then channel separation improves from 27 dB
to 46 dB. As always though, this improvement is not free. The price
is paid in reduced line driving capability. The box now has high
output impedance, which prevents driving long lines.
Driving a maximum of 3000 pF capacitance is the realistic limit.
This amounts to only 60 feet of 50 pF/foot cable, a reasonable figure.
So, if your system can stand a limitation of driving less than 60
feet, scaling the resistors is an option for increased channel separation.
For more great information, go to http://www.rane.com/library.html#rnotes
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