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196.11.134.77
In Reply to: RE: Jpp for DAC as Master (using 24/88.2) yields an additonal 4ps of Jitter posted by Sunya on March 31, 2008 at 23:28:16
That's how DSOs work. Unfortunately, my Elab-80 won't do (only 8 bit resolution). Yes those high tech versions will yield more accurate results (which would show a lower jitter measure). There's no need to compare to input file - you need to analyze the analogue output (which goes through an ADC).
If the ADC introduced substantial jitter when recording the analogue outputs, this jitter would be clearly visible in the spectrum analysis. In fact what is shown is inclusive of the ADC's jitter distortion (which gets added to analogue waveform from DAC's output). This means the result shown is a high water mark - a DSO without jitter would show even less jitter in the recorded output!
Even with an ADC step that's not jitter free, Jpp of 72ps and 76ps (with DAC as master) remain valid measures. Making assumptions over the jitter introduced by the ADC and thus reducing the Jpp figure is not my preference. Its like attributing all the good things to the DAC & Transport and parking the 'not so good' with the Recorder.
Your analysis that the ADC and DAC jitter are additive depends upon the assumption that the ADC and DAC sample clocks are independent. If they are not then the situation is complicated and the possibility of cancellation can not be easily excluded. Murphy's Law of Clocks: A multi-clock system requiring synchronization will have unsynchronized clocks, while a multi-clock system requiring unsynchronized clocks will have synchronized clocks.
Unintended synchronization of clocks was first observed by Huygens in 1673. More recently, it has been a factor in computer networks, where I have personal experience with the phenomenon and how it can impact performance as well as measurement accuracy.
Tony Lauck
"Perception, inference and authority are the valid sources of knowledge" - P.R. Sarkar
ADC clock is independent from DAC clock. DAC recovers clock from SPDIF input whilst ADC utilizes it own XO. Measurement is not in digital domain, i.e. input signal gets converted to analogue which in turn gets recorded.
Yes the situation gets complicated if clocks have dependency - this arises when working entirely in the digital domain such as computer networks.
Given that the two clocks are controlled as you described, there is no engineered reason for them to be synchronized. However, if there is any means of coupling energy associated with one clock into the other clock and if the free running rates of the two clocks are sufficiently close, then it is possible for the two oscillators to become synchronized. This happens in many systems of coupled non-linear oscillators. (A Google search turned up one such example.) In one case that I observed with computer networks, the separate clocks were "independent" crystal oscillators that were intended to be oscillating separately. Their synchronization was an artifact of the circuitry, not something intended by the digital design.
Since you are measuring to limits of precision that are close to the limits of your equipment, then I think it advisable to conduct some tests to ascertain that your "independent" clocks are actually independent. I would consider this to be part of the calibration procedure for your test setup.
Tony Lauck
"Perception, inference and authority are the valid sources of knowledge" - P.R. Sarkar
What would the result be of such XO synchronization?
I'm looking into reapplying optimizations that I reversed for the cMP recorder (to accommodate Cubase LE). The 2kHz jitter component I suspect relates to the ADC and nothing else.
Based on optimizations I've reapplied, there's an even better spectrum (using 14kHz tone). This seems to rule out synchronization of XOs?
What would the result be of such XO synchronization?
Without knowing the details of the circuitry involved I don't believe that it would be possible for anyone to answer your question. I think it would depend very much on the details of the circuitry and the causes of jitter in the two XOs, which would be things on the margin of the original circuit designs. In any event, if it were an obscure circuit design problem, it would be beyond my expertise, as I am a systems person and not a circuit designer.
However, I can take a guess. If the two clocks are synchronized then it becomes possible to consider that some amount of their jitter is correlated. The effect of this correlated jitter could then cancel to the first order. But if the clocks are not synchronized, then the correlated jitter would sometimes be additive and sometimes subtractive and how this appeared in the final results would depend on the method of averaging and the beat frequency between the two sample clocks. If there is no correlated jitter then I don't think it would make any difference whether or not the clocks were synchronized.
You can test for clock synchronization by measuring the relative timing accuracy of the two systems using a recording with two impulses separated by several minutes of silence. If the clocks are not synchronized, you will be able to determine the beat frequency of the sample clocks, which may be something to take into consideration in doing your averaging.
I will think about this some more and if I come up with something I will send you a private email.
Tony Lauck
"Perception, inference and authority are the valid sources of knowledge" - P.R. Sarkar
I'm curios if you would get the same results by repeating the measurements a few more times. My guess would be that they would vary because the numbers you obtained can't be an absolute unchangeable value.
My point was not to reduce the Jpp value because of the jitter introduced in the A/D process. What I think is that without you knowing exactly what amount of jitter imparted the ESI card in each measurement instance you can't treat the results you've got as absolute values, especially when the difference is just 4ps.
You didn't say how it sounded with the DAC as Master. Did you listen to it in this way or just made the measurements?
I'm curios if you would get the same results by repeating the measurements a few more times. My guess would be that they would vary because the numbers you obtained can't be an absolute unchangeable value.
Measurements were repeated and over separate days. Even at 24/88.2, I got to same 72ps. Likewise, on DAC master setup, measurements were same at 76ps.
A 4ps difference is 5.6% worse - that's material in a game where everything counts.
You didn't say how it sounded with the DAC as Master. Did you listen to it in this way or just made the measurements?
Same as before.
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