The Science of Cables


It seems to me that there is too little scientific, objective evidence for why cables sound the way they do. When I see discussions on cables, physical attributes are discussed; things like shielding, gauge, material, geometry, etc. and rarely are things like resistance, impedance, inductance, capacitance, etc. Why is this? Why aren’t cables discussed in terms of physical measurements very often?

Seems to me like that would increase the customer base. I know several “objectivist” that won’t accept any of your claims unless you have measurements and blind tests. If there were measurements that correlated to what you hear, I think more people would be interested in cables. 

I know cables are often system dependent but there are still many generalizations that can be made.
128x128mkgus
measurements? how about only buying from companies that give you a trial period and get your ears measured and rely on them.
Ears remain the best test instrument and practically no ears are like any other ears. What I mean is that if your ears protrude further from the side of your head than normal you will hear totally differently than someone who has ears that remain close to their head. You can demonstrate this by physically moving your ears out while listening to music. The difference is dramatic.
Because if everything was spelled out to the uniformed these cables couldn't be sold with over the top prices . Have to keep the uniformed in the dark to be able to charge the ripoff prices .
@millercarbon claims:

Electrical measurements are totally irrelevant.
 
 Tell us you can’t hear the difference between a lousy Walmart 24 AWG “speaker” cable and a decent audiophile 12 AWG speaker cable, or a lousy 50 cent dollar store interconnect with 1000 pF per foot capacitance between your preamp and amp, compared to an audiophile cable with 12pF per foot capacitance? Or is it “all good” as long as you shake the magic chicken’s foot at it?
A couple of things when considering the cable building thingee.

The LCR wire model is applicable only with air as a dielectric. Makes perfect sense in that application. Once that wire is encapsulated in varnish, enamel, lacquer or dielectrics of varying consists then all bets are off. “Wire” then becomes an electrical system that is very different from the raw metal.

And this from here....   https://positive-feedback.com/audio-discourse/rcl-part-2-roger-skoff-cables/

Let's see how. Let's start by simply accepting the engineers' favorite factors for cables: R (resistance), C (capacitance), and L (inductance). They say that those things make a difference, and it's true. Among other things, they can affect both the power level passed by a cable and its frequency response.

In thinking about this, remember a couple of things. First, that "resistance" is a term best applied to DC (direct current), and that with AC (alternating current) signals like music, wherever there is capacitive or inductive reactance (as there always is in cables), the more correct term to use is probably "impedance" (Z).

Second, remember that inductance, one of those favored factors, "…is the property of an electrical conductor by which a change in electric current through it induces an electromotive force (voltage) in the conductor." (read more HERE) What that means is that any current flowing through a conductor causes an electromagnetic field to form around that conductor (and out to infinity, in accordance with the "inverse-square law"), and that, when the direction of that current changes (as it does every time the AC current changes polarity) the field collapses and the collapsing field creates a voltage ("back EMF") that opposes the flow of incoming new signal. The higher the frequency, the more of an effect this has on the sound.

Remember, also, that capacitance, another of the "favored factors", is the ability to store energy (read more HERE), and that a capacitor is formed any time two conductors ("plates") are brought together, separated by a non-conductor "dielectric" (read more HERE). What that means is that every cable is, by definition, a capacitor, with its two conductors (positive and negative or "going" and "coming") being the plates, and the insulation between them being the dielectric.

Now, have you ever noticed that, when electronics designers or engineers call for a capacitor to be included in a circuit, they not only specify its capacitance, but also its type? (Ceramic, Film and paper, Polymer, air gap, mica, tantalum, and many, many others (read more HERE and HERE). If factors other than just the measured capacitance of a capacitor are important (and can make a performance difference) in other types of capacitors, how can those exact same things not make a difference in cables?

The amount of capacitance—and of inductance—in any cable or other capacitor is largely determined by how far apart the "plates" are spaced, with those two factors in a sort of "seesaw" balance:  The more capacitance there is, the less inductance, and vice versa.

Another very major factor is the material that the dielectric is made of:  For cables, virtually all of the various non-conductive elements are part of the dielectric. This is important in two ways: The first is that different dielectric materials have different dielectric constants (the ratio of the capacitance of a capacitor in which a particular insulating material is the dielectric, to its capacitance in which a vacuum is the dielectric, read more HERE). Or, to put it most simply,  the dielectric constant of a material is a number that shows how much energy any given volume of it  can store as compared to that same volume of vacuum. By way of illustration, the dielectric constant of a hard vacuum is 1.0, while balsa wood (a little stiff for most cables) is 1.4. Teflon® (there are several varieties) is around 2.0.  Polyethylene is around 2.2, and PVC and TPR (thermoplastic rubber), the two most popular cable insulators, by far, can have dielectric constants of as high as 6.8 (read more HERE).

Whatever the amount of stored energy, when the signal carried by the cable changes polarity, all of that energy is dumped into the signal path, canceling some of the incoming signal, or actually creating out-of-phase artifacts. This results in either the loss of low-level information or the actual creation of new information, either of which would be surprising if it didn't affect the sound!

The other important thing about dielectrics (which, remember, include the non-conducting elements of a cable) is their "dump rate"—how quickly they can release stored energy after the signal changes polarity so that they can start storing the new signal energy coming in. Dump rates vary wildly, with some materials, PVC, for example, being quite (relatively) slow and others (Teflon®, for example) being very, very fast. This can make a definitely audible difference (with faster dump rates that affect the incoming signal for less time being much preferred), and, surprisingly, the dump rate of a material and its dielectric constant are not directly proportional. Polyethylene is only around ten percent higher in dielectric constant than the best form of Teflon®, but has—while still vastly faster than PVC —an audibly slower dump rate, to lose low-level detail and "muddy" its sound.

There are still other factors that affect the sound of a cable—its "geometry"; the type, purity and crystal structure of the metal in its conductors:  the existence of mysterious (and perhaps mythical) micro-diodes at the crystal junctures of copper; the self- and mutual-inductance of both the cable and its connectors; how much and what kind of metal those connectors are made of, and many more, but I'm out of space for now.