r1 - 2014-02-07 - 01:40:58 - HarlanStennYou are here: NTP >  Dev Web > DevelopmentIssues > NtpStartupAnalysis
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NTP Startup Analysis

Related Topics: GSoC2013StartupAnalysisRahul, GSoC2013StartupAnalysisRahulDesign


With a good drift file, stable conditions, and iburst, ntpd can sync up in about 11 seconds' time.

Other conditions can cause this process to take closer to 5 minutes' time.

We want to try and "do better".

The thought is that we can do a least-squares fit and determine the offset and the drift. The key questions include for various network transport, what sort of intervals produce what sort of results?



We must respect the "rate" considerations. This means we can send packets no faster than one every two seconds' time, and we can send no more than 8 packets in any 60-second interval.

It looks like we want to calculate y=(m-1)x+b, where m is the frequency correction and b is the offset correction. The reason for (m-1) is because we can expect m to be a floating-point value and the slope should be within parts-per-million of 1, and we'll lose a lot of precision waiting to get to the "interesting bits". So we get the "1" out of the way and are left with only the interesting bits.

The intercept will be a value that handles the offset correction.

The closer the intercept is to "now" the less correction will need to be applied to the calculated offset.



We need to know what the current offset and drift values are.

Once we know these, we want to stop all corrections and let the machine free-run while we run our tests.

At the end of that test, we should expect that by multiplying the drift value by the number of seconds between stopping corrections and the intercept time that we'll have the same offset and drift values that the startup analysis process determines.

For wired networks, we think want to see what sort of results we get when we go from, say, 20 to 120 seconds, increasing by 10 seconds on each test. Once we get an idea of where the "interesting" parts of the curve are we can look more closely.

Harlan has heard that for wireless networks, this will probably take several minutes.


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