mtrycrafts said:
I am just trying to understand
Mee toooo...
mtrycrafts said:
I am still trying to understand how you will get 5us or more delay between the right channel and left channel that will cause the soundstage to shift noticably?
And, just because there is group delay in the cable itself between the lows and highs, how that alone will cause soundstage drift unless the cables on each side are so different to cause that 5us or more difference for that same frequency between the two sides.
Then, will the 5us delay with music be noticable as easy as with test tones?
Certainly JND studies show that music will mask level differences until a much higher difference exists than with test tones. Perhaps the same applies to soundstage issues?
How will one know if the location of the instrument is where it is supposed to be?
Hi Mtry..Happy New Year
All excellent questions..I'll give some answers, and show some research holes..via modelling..bear with me for a while..I put it here rather than private e-mail, as Pat deserves an explanation, I was a little abrupt...
Assume an impulse source in space,10 feet from the listener producing a spherical pulse wavefront (pulse for model simplicity, we can't localize a pulse in reality.). It reaches each ear based on distance.. We define the direction based on that time difference.....lateralization.
The sensitivity of discrimination will be highest directly in front, lowest at 90 degrees..a cosine based function.
By tests, it will be shown (the first segment of my work) that we can discern direction in a gaussian like manner...the better one is, the sharper the distribution (lower the sigma), the more accurately one can localize. If, 50 uSec is the best one can do, then sigma (the uncertainty of direction) will be in the 15 to 30 inch wide range. By practice, I make the assertion (entirely unproven at this point), that one will be able to reduce sigma. Localization to a span of 5 inches will require about 5 uSec capability. Humans can discern timing changes down to about 1.5 uSec, but Nordmark's work does not demonstrate that the inverse, or directivity capability, can be extended down to half an inch or so at ten feet. I make the broad assumption that 2 to 3 inches is the best one could hope to do.
Now....stereo reproduction...
Two point sources, 10 feet apart. simultaneous impuses. each ear receives it's signal at the correct time....but then, each ear hears the other's signal. This is NOT how we were meant to localize a source...The brain "sees" the virtual image produced by each ear receiving it's info, and then it "sees" the right and left image that is actually occurring as a result of two sources. The fact that we can image just the intended, center image, is a wondrous thing, while not being annoyed by the side ones (I'll refer to those as sideband images).
Since our localization sensitivity is gaussian, the sweet spot will be a gaussian "blurred" point in space. It will be roughly diamond shaped, with a gaussian profile along the two source vectors. It will also NOT be very sensitive to head rotation (the cos theta function), as we are worried about the relative image location, not absolute. However, it will be sensitive to translation from the geometric center of the spot. As one leaves the spot, the sensitivity to directionality defined by the binaural signals will diminish. (the image will become less apparent). Once the head is far enough away from the sweet spot, all image information is gone. Once the image is gone, all that is left is the fidelity of the sources. What has to be pointed out, is that if one can "learn", by practice, to sharpen one's lateralization capability, their sweet spot will become smaller (don't forget, the spot is defined by the gaussian lateralization sensitivity..) I surmise that Bose widened that sweet spot through the direct/reflecting technology...making the image larger when in the spot as an unintended side effect.
The standard arguments against cables being a concern, is centered about the fidelity of the signal. Outside of the sweet spot, this is the only concern, and the lumped parameters of the wires, especially L and C, are unimportant. So, for the vast majority of people who are not interested in sitting in a small area, the wires don't make a darn difference..For speakers that are not rigorously time coherent, it doesn't make as much of a difference..for a pair of old 901's, it also makes no difference. I consider it silly to drop lots of money into crazy cables of really low inductance and resistance, if you are not concerned with lateralization...So for the bulk of the people, what is professed on this site, is entirely accurate. It's the fidelity that matters.
Variation in timing of lateralization cues (yes, I finally got to your questions)?
First, what is the cue? zero crossing, as Nordmark hypo's? Slew rate based, as I hypo?...All that is known is that it is a 1 to 10 uSec based thing..incredibly fast, considering we hear about 20K max..
If you look at the low impedance system as a whole in light of this speed level, many things become apparent..
1. Amps are not designed for those speeds..we are implying bandwidths of a Megahertz.
2. Current slew rates in the ampere per microsecond regime create huge mag field rate of change, this will couple to loops in the locale, as well as resist efforts of the amp to control the output current.
3..Coupling of the feedback loop within the amp chassis, to the output current mag flux is unavoidable..in fact, it is not considered a part of good design yet. Why should it be? It has not been considered..
4. Measurement of these slew rates is not easy. Loop coupled voltage intercept confounds measurement. Nobody I am aware of takes care to avoid that error term, either in measurement, or in the physical layout of the amp.
5. Shielding is incapable of fixing the loop coupling..star grounding is useless also. External ground loop, as in line cords, is also an issue.
6. Given Nordmarks data, that lateralization is sharper with jitter, the amplitude of the system (spl, cone displacement) will also change the imaging.
With all these factors capable of affecting the overall output slew rate (note, not the absolute slew rate per se, but the
error in absolute slew rate), hence image clarity, the question is now one of, what magnitude is important and discernable..
I point out that the speed regime is almost three orders of magnitude faster than currently accepted engineering practices for audio reproduction. This is because the imaging requirements are there...
I point out that all the tests I have seen are incapable of accurate results at the 1 uSec level. I always require my test equipment be at least an order of magnitude better than what I am trying to measure, this is why I am making my load resistor really non reactive..I finally got a reading on it, but it is incorrect. At 100Khz, 256 point integration, the meter says 2 nanohenries...that is incorrect, as the coaxial feed structure to it is 5 inches long, Inner conductor OD of .650, Outer conductor ID of .835, DC of 1 (air)...and should be 7 nanohenries inductance plus the resistor array inductance. Clearly, there is a problem..I think the meter is seeing the output wire pair.
Without the ability to see the delays using real electrical tests, one is stabbing in the dark...amp designers are forced to "listen to ther ears", as they don't even understand the timing issues, and use random guesswork in their design..Wires, same thing...line cords, same...tweak, tweak, tweak...what a lousy way to work...
I refuse to tweak...
To answer your question....both amp channels are in the same chassis, both are trying to control a low impedance load that is miles away (the wire inductance is there)..both channels are, internally, broadcasting lots of high slew rate magnetic fields that the feedback loop is intercepting...and to top it off, we expect the thing to play well with a random signal.
It will be a long road, as I can't find any lateralization studies that I need to proceed, so I am relegated to designing my own...sigh..The e/m field theory stuff is the easy stuff, I'm sorry to say...I have lots of test experience in the 4 giga-amp per second regime and 1 ohm impedance, so these speeds won't be a problem for measurement. And, I've "dabbled" with higher current stuff.
All of what I speak of here, is testable...I will not handwave...results will be demonstrable, repeatable, and peer reviewed...nothing other than that will be acceptable..
Cheers, John.
To all the others: I apologize profusely for putting you to sleep..to the real geeks, I apologize for the oversimplifications I present..
Gene: I love this site, the editing capabities and jpeg support are absolutely the best features here..thanks.
