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LA3ZA Radio & Electronics
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Magical speaker cables - part 2
Posted: 09 Jan 2022 01:00 AM PST
https://la3za.blogspot.com/2022/01/magical-speaker-cables-part-2.html
Cable with large distance between the
conductors (Schnerzinger)Part 1 of this article concluded that it is
important to have thick enough cables in order to bring down the
resistance. It also showed two examples of slightly more exotic cables,
shown in the first two images here.
The first example had a large distance between the conductors and was
placed on its own stand to get distance from the floor. It was designed to minimize capacitance between conductors. Another design criterion was to minimize the impact of vibrations created by the speakers themselves.
Twisted multi-conductor cableThe next example was a cable made by twisting together many thinner conductors, in this case a do-it-yourself cable. It
was designed to have the least possible inductance and also to minimize the skin effect.
There is no shortage of science-based claims for how cables affect sound.
There are so many of them that this blog post, where my ambition is to say something about all of them, gets to be a little longer than I would have
liked it to be. If you are impatient, you may go to the end and just see
the conclusion. For the curious, I will consider the claims one by one.
After resistance, it is inductance and capacitance that matter. But is a
small inductance or a small capacitance preferable? Ideally, both should be zero. A cable can be made with a small value for one by getting a large
value for the other. But it is not possible to produce a cable with both
low inductance and low capacitance. And whether you have much of one or the other, they will both influence the treble. A hand-waving way of saying it,
is that inductance blocks high frequencies while the capacitance
short-circuits them. And even in a regular short speaker cable, this means
that the bass will arrive a little later than the treble (dispersion).
But in a normal short speaker cable, the difference in time delay does not correspond to much more than if the tweeter element in the speaker was
moved a maximum of one mm back, so the consequence is minimal. In addition,
the attenuation of the treble is so small that it can be neglected in most cases. If you still want to minimize the loss for high frequencies, it pays
to design for a low inductance rather than low capacitance. In other words,
it is an advantage that the conductors are close together as they are in
most cables, and not far apart as in the cable in the top picture. I’ll
come back to why at the end of the article.
Some cable designers emphasize minimizing the reflection of the signal from
the ends of the cable. That means adapting the load to the cable's characteristic impedance. This is well known from cable TV where the
impedance of the transmission line is 50 or 75 ohms. There are several objections to impedance matching for speaker cables. First, it is not
possible to make cables with impedance as low as 4 or 8 ohms as is typical
for speakers. But even more important is that a TV cable is long in
relation to the wavelength of the signal. That is what makes the
transmission line model applicable. This is not the case for audio cables
where the highest treble has a wavelength of at least 10 km and the bass
even longer. Therefore, speaker cables cannot be understood as transmission lines and all talk of impedance matching is meaningless.
Pupin coil on insulator on top of a telephone pole
(American Electrician 1903)It is different with old-fashioned telephone
cables that can be as long as 100 km. They must be considered as
transmission lines, often with a characteristic impedance of 600 ohms. It
was discovered as early as 1900 that adding coils (inductance) at regular intervals, so-called pupinization, was an advantage. There exist speaker
cables with such coils as well. But again, here a model for a long cable is incorrectly applied, not the model which is valid for a 4-5 m long speaker cable. For such cables, it is an advantage with the opposite, namely low inductance, as just mentioned.
Others emphasize that their cables avoid resonance. This may sound
convincing, as a system that has inductance and capacitance always has a resonant frequency. Even here there is a mixture of two models. The low frequency model of a cable, the one that applies to audio, consists of a discrete inductance and a discrete capacitance. Using typical values, one
will find a resonance frequency of a MHz or two, which is far higher than
what is audible. This fact alone should indicate that the effect is insignificant. Even more important is that at these frequencies, there is another cable model that applies, namely the transmission line model
mentioned above. It has distributed inductances and capacitances and that
gives no resonance. Therefore, the whole resonance problem is yet another imagined problem due to incorrect application of models.
Closely related to resistance is the skin effect. This means that the
higher the frequency, the more current is displaced to the outer part of
the conductor. Even at 50 Hz, as in the electricity supply, the current
does not penetrate much more than one cm into a copper cable. At 20 kHz,
the skin depth is about 0.5 mm. This means that for thick cables (2.5 mm2
and more or AWG 10 and less) the effective resistance increases slightly
with frequency. The proximity effect, which is how currents in the two conductors influence each other, also contributes in the same direction.
Flat cable which is 12.5 cm wide
(Magnan Audio Cables)Some expensive cables are therefore designed with
multiple conductors, each of which is thinner than the penetration depth,
as shown in the picture of the twisted cable above, to avoid this. Alternatively, the cable can be made flat and with a thickness which is
less than the skin depth, as shown here. By the way, this is quite nice if
the cable is to be put under the rug!
A third way to deal with the skin effect is to make a hollow coaxial cable,
as used for cable TV. The expensive Pear Anjou cable that annoyed James
Randi, was built this way (see part 1). However, compared to the increase
in impedance due to the inductance of the cable, the contribution from the
skin and proximity effects is not very large. Still, it does not hurt if a cable minimizes these effects, but it may be questionable whether it is
worth the money. The skin and proximity effects are real effects that can
be measured. They illustrate the fact that even if something can be
measured and analyzed, it does not necessarily mean that it is important. Designs like that of the twisted multi-conductor cable shown above are
despite this reservation to be recommended.
How can it be that some exotic cables are made with a large distance
between the conductors to get low capacitance, when I have just said that
it pays to have small inductance? Often it is because they have focused on
a memory effect found in capacitors and which is due to dielectric
absorption. Even when a capacitor is what appears to be fully discharged,
it may still remember some of the charge. I have illustrated this in a
YouTube video. This is a real effect, especially in capacitors with high capacitance, much larger than in a cable. It has to do with the quality of
the material between the conductors. Materials such as Teflon minimize it,
but even better is air such as in the cable that floats on stands above the floor in the picture above. A cable supplier can make it a point that their Teflon insulation cures such effects and explain how cables can
be 'non-linear' and smear the sound and give a bad stereo image. Is it
real? Not really, as the memory effect is linear since it can be modeled
with a network of capacitors and resistors, none of which can distort a
signal non-linearly. This has been illustrated by analog guru Bob Pease.
Then there are those who emphasize the importance of proper materials in
the conductors. As mentioned earlier, good conductivity is important. With
its good conductivity, acceptable price, and good mechanical properties, it
is no wonder that copper is so popular. It is barely beaten by silver which
has 5% lower resistance than copper. Gold does not come out so well as it
has almost 50% more resistance, but it is well suitable for electrical
contacts as it does not oxidize. You can get expensive speaker cables made
from silver. But the question is whether it is not better to increase the copper cross sectional area by 5% rather than use the much more expensive
and mechanically more fragile silver.
There are also many who emphasize the purity of the material. Here it is appropriate to say something about how a signal is conducted along a cable.
A common analogy is a water pipe. In a cable, it is the electrons that are
said to flow like water in the copper. But this analogy starts to falter
when you look at the transport velocity of electrons in a material like
copper. It increases with frequency but never becomes more than a few tens
of m/s. Let's say that a power plant located 500 km away starts up and the current is transported by electrons traveling at 10 m/s. Then it will take almost 14 hours before I notice that the power has been turned on! Here,
the analogy with the water pipe has obviously broken down.
Nobody likes corroded cablesFor it is not electrons that carry the energy,
but an electric and magnetic field that propagates almost as fast as light
and which passes between the conductors. The field induces current and
movement of electrons in the cable. But all the movement of electrons means lost energy. Therefore, high conductivity in the cable means less loss. On
the other hand, impurities will not matter, unless it affects the
conductivity, as the energy that enters the material is lost anyway as
heat. Another aspect is that copper quality affects both how flexible the
cable is and how good it is at resisting corrosion. Oxygen-free copper
(OFC) is often preferred for that reason.
The same applies to those who argue that there will be distortion if the
cable consists of several strands. For this reason, there exist rigid and unwieldy speaker cables made from solid copper. The idea is that there will
be a rectification effect in the transition between the various strands,
i.e. between copper and oxidized copper, much like in a crystal in an old-fashioned crystal radio. But this is also energy which is lost as heat. Moreover, such a distortion should be possible to measure, but I have never seen such measurements. The argument that the cable needs a break-in
period of several hours or more, as well as the idea that it is important
which direction a cable is connected also fall on its own unreasonableness. Remember, however, that it is still important that both speakers are
polarized in the same way, so it does matter which of the two cable ends is connected to which of the speaker terminals. But this is a pure acoustic
effect to ensure that both speaker diaphragms move in and out in phase and
it has nothing to do with the properties of a cable.
When it comes to tube amplifiers, some may have noticed that knocking on a
tube sometimes can be heard in the speaker. This is a mechanical or triboelectric effect that also can happen in poor quality microphone
cables. The danger is that the sound pressure from the speakers themselves
can cause the cables to vibrate and create distortion. Some people get hung
up on this in the design of speaker cables and argue for choosing geometry
and insulation materials based on it. Since it is possible to design
microphone cables which are robust against such effects with their very low signal levels, it goes without saying that this cannot be an important
effect in a speaker cable where signals are so much stronger.
There is also an effect which in a way is the opposite of that in the
previous paragraph. Due to the large currents in a speaker cable, there may
be forces between the conductors that can make them attract and repel each other. If this leads to movement, it can give rise to a new signal which
can disturb and distort the actual signal. This is used as an argument for putting the conductors far apart. But the cure must rather be to make a mechanically stable construction. Besides, this is also an effect which
should be measurable. I have even tried to measure it myself without
success. Therefore I doubt if there is anything here to worry about.
My last point is an effect which is easy to forget. There is a possibility
that a speaker cable will act as an antenna and pick up unwanted signals.
This applies especially to signals that are outside the audible range. They
are sent 'backwards' into the amplifier. What happens next depends on how
well the amplifier is designed. Such signals can be from nearby radio transmitters. Medium and long wave frequencies are often worst. But it can
also be from a noise source that not many people think about and which can
be in their own living room, namely a plasma TV. The open cable solutions
with a large distance between the conductors are clearly the worst. This
has been confirmed by both measurements and listening tests. The best
cables to minimize such interference are shielded (coaxial) cables and
twisted multi-conductor cable, but cables with the conductors close
together are also good.
In fact, there are several amplifiers of minimalistic design in hi-fi that
are more easily influenced by external factors than other more robust constructions. These can be amplifiers that professionals steer clear of,
but which are still large in the high-end hi-fi market. This may be due to sensitivity to external radiation, or that the amplifier is only marginally stable and thus extra sensitive to capacitive loads. Then a standard low-inductance cable, implicitly one with a high capacitance, could create problems. Finally, it should be mentioned that tube amplifiers, which often have a large output impedance, are more easily affected by the complex interaction between a cable, the crossover filter in the loudspeaker and
the loudspeaker elements than other amplifiers.
What should we conclude, is there magic in speaker cables? We have looked
at the effect of a large and a small distance between the conductors, on reflection and resonance, on skin and memory effects, on the purity of the conductor, whether break-in and polarizing the cable is important, on
vibration effects and finally on potential interference from external
signals. One factor that has deliberately not been discussed is the
aesthetic value. It should not be underestimated that hi-fi sells both on acoustic performance and on pleasing design.
But from a purely performance point of view, I end up with the finding that low-resistance, low-inductance cables are well supported. The most common
and cheapest type is with conductors next to each other, but they may be twisted together as well. This means that the cables can be quite
affordable as long as they have a cross section of at least 2.5 mm2 (AWG
10). In professional audio, 2 x 4 or 2 x 6 mm2 are often used (AWG 6-3),
unless they use active speakers where there is hardly any cable at all.
Twisted multi-conductor cables are often not very expensive and may
possibly have an edge at high frequencies. In any case, the longer the
cable, the thicker it should be. Due to the possibility of radio frequency interference, exotic cables with a large distance between the conductors
are something I want to warn against. The same goes for high-inductance
cables with discrete inductors embedded in them, all other exotically
designed cables have no negative effects, other than possibly on your
wallet. And since no cable is ideal, the recommendation is to make it as
short as possible, but still the same length for each speaker.
Sources:
Greiner, Richard A. "Amplifier-Loudspeaker Interfacing." Journal of the
Audio Engineering Society 28.5 (1980): 310-315.Robert A. Pease, "Understand capacitor soakage to optimize analog systems." EDN, Oct. 13, 1982.Davis,
Fred E. "Effects of cable, loudspeaker, and amplifier interactions."
Journal of the Audio Engineering Society 39.6 (1991): 461-468.Edwards,
John, and Tapan K. Saha. "Diffusion of current into conductors."
Australasian Universities Power Engineering Conference. Vol 1. CRESTA, 2001.Black, Richard. "Audio Cable Distortion is Not a Myth !." Audio Engineering Society Convention 120. Audio Engineering Society, 2006.Newell, Philip, and Keith Holland. Loudspeakers: for music recording and
reproduction. CRC Press, 2006.
(First published in Norwegian in: Magiske høyttalerkabler - del 2)
The post "Magical speaker cables - part 2" first appeared on the LA3ZA
Radio & Electronics Blog.
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