Thanks guys. I had a chance to look at it briefly before leaving for a wedding today ( another poor sap bit the dust ).
I found this quite interesting to say the least. I tried discussing this with John Curl, Jon Risch, John Dunlavy, etc... and some of those well versed in electronics back about a year or two ago over on the Cable Asylum.
Here is a link to a thread that i started pertaining to this very matter:
http://www.audioasylum.com/audio/cables/messages/13340.html
While much of the terminology that Herve used in the article is slightly different than our form of "electronics gibberish" over here, i think that what he had to say is probably QUITE valid. Keep in mind that i'm coming from a point of view that is familiar with RF and how important impedance matching, velocity factors ( or as he called it "propagation speed" ), etc... can be to getting a system TOTALLY dialed in.
I have NO doubt that there are gains to be made in this area. Unfortunately, i do not have the equipment necessary to do such testing and that's why i was asking Mr Risch and Mr Curl for help. Evidently, Mr Deletraz (the author of the Stereophile article ) didn't have it either as he had to ask a local engineering school and teacher of physics and acoustics for help.
If you do an advanced search going back about two years or so, using "velocity factor" as the text and "Sean" as the author, you'll also be able to find a few dozen references that i've made to "tuning" or resonating cables to the proper impedance. Other than the public queries to professionals that are more knowledgable in the field than i am, i have never seen anyone mention this in terms of applying "RF based technology" to audio systems. As such, i would have to say that this might be a "whole new ball of wax" to deal with. Don't confuse "impedance matching networks" with the "networks" that MIT and Transparent use as they are quite different. They are dealing with trying to correct Td ( Time Delay ) distortions across the audio bandpass and not impedance mismatches from component to component. Sean
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