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Subject: Re: good NTP servers
Date: Fri, 2 Feb 1996 00:46:16 -0600 (CST)
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As promised, I am passing this along to the list...

I think that this will clear up many misconceptions on exactly what UTC is
and how it is obtained (Including some of mine, and some of yours)...

> Date: Thu, 1 Feb 1996 13:47:21 -0700
> From: jlevine@time-A.timefreq.bldrdoc.gov (Judah Levine)
> To: jbryant@argus.flash.net
> Subject: The Definition of UTC
> 
> Hi,
> 
> >	okay...  I'm going to try to get the official word here...  
> >	It seems illogical that NIST would be synched to USNO, it follows 
> >	everything that I've heard that it is the other way around where 
> >	USNO would synch to NIST.
> 
> >	I'm Cc:'ing this to someone who should be able to answer this 
> >	question:
> 
> >	    "Between NIST and USNO, who obtains synch from whom, and how"?
> 
>     This is actually a complicated business, and a one-sentence answer
> won't explain all of the complexity. So, here goes ...
> 
>     There is an international agreement about time-keeping (and other
> similar physical standards) which is called the Treaty of the Meter.
> The US and almost all other countries are signatories.  The international
> standard of time is called UTC (with no subscripts).  It is maintained
> by the International Bureau of Weights and Measures (BIPM, in French),
> which is located in Sevres, just outside of Paris.  The BIPM computes
> UTC using data from about 250+ cesium clocks and hydrogen masers located
> in the laboratories of many of the signatory nations.  (In the US, both
> NIST and USNO contribute clock data for this computation.)  The BIPM
> computation is done once each month, and the results are available
> about three weeks later. For example, the computation for October, 1995
> was published by the BIPM on 16 November. 
> 
>    Since the computation of UTC is always after the fact, timing
> laboratories (such as NIST or USNO) provide an extrapolated real-time 
> version of UTC for users, which is identified by the name of the laboratory.  
> Thus UTC(NIST) is a time-scale generated by NIST from its own clock data (an
> ensemble of cesium clocks and hydrogen masers).  The BIPM publishes
> the offset between its official UTC and the UTC implementation of each
> contributing laboratory. The publication is called "Circular T" and is
> publicly available.  UTC(NIST) is steered towards UTC each month using
> these data so that the difference is as small as possible and the steering 
> is as smooth as possible.  The maximum change in rate of UTC(NIST) from
> month to month is +/- 2 ns/day.  These steering corrections are intended to 
> be small enough so that all but the highest accuracy users will not be 
> affected by them.
> 
>    The steering corrections (and related information) are published by NIST 
> in advance in the NIST Time and Frequency Bulletin.  The difference
> between UTC and UTC(NIST) varies somewhat from month to month, but is
> generally not larger than 20 ns.
> 
>     The procedures at the USNO differ in detail, but the concept is
> the same -- UTC(USNO) is generated from their local ensemble of clocks and
> is steered towards UTC as published by the BIPM using periodic adjustments.
> 
>     Thus in the short term, UTC(USNO) and UTC(NIST) are free-running 
> cesium/hydrogen ensembles which are steered towards the UTC published by 
> the BIPM once each month.  The difference between the two is of the order
> of nano-seconds, which is only significant for the highest-accuracy users.
> 
>     Although this is complicated enough, it is still not the whole story --
> There are two other inputs to the UTC computation.  
>  
>     The International Earth Rotation Service (IERS), located at the Paris
> Observatory, is responsible for deciding when a leap second is needed to
> keep UTC as computed by the BIPM and as realized by the various timing
> laboratories within +/- 0.9 s of UT1 -- a time-scale based on the rotation 
> of the earth.  This decision is based on various world-wide astronomical 
> observations.  The BIPM and all standards laboratories implement these leap 
> seconds as required -- about once a year and usually at the end of June or 
> December.  The last one was at the end of December, 1995.
> 
>     The second input to UTC is from primary frequency standards (as
> distinguished from the commerical cesium standards that provide the
> day-to-day data for UTC and UTC(lab).  There are only a few of these
> in the world; the best ones are at NIST and at PTB, the German
> equivalent of NIST located in Braunschweig, Germany.  These standards
> are designed to realize the highest-possible accuracy.  Our current
> standard is called NIST-7.  It took almost 10 years to build and has
> an absolute accuracy of about 1e-14.  It, and its counterparts in
> the PTB enter the UTC computation as periodic adjustments to the
> length of the UTC second -- the rate in other words.  The BIPM
> incorporates these data by periodically adjusting the rate of UTC.
> A typical adjustment is on the order of 1e-15 in frequency.  Again,
> these adjustments are intended to be small enough so that only
> the highest-accuracy users need to be concerned with them.
> 
>     All timing laboratories use GPS signals to transfer time and
> frequency information, but the method we use is called common view,
> which means that we all look at a specific satellite at a specific
> time and average the observations for 13 minutes (for technical 
> reasons).  The tracking schedule (the list of which satellite to
> observe when) is published by the BIPM periodically, and all 
> timing laboratories everywhere adhere to it as a minimum.  This
> method tends to cancel many of the errors due to the satelite
> clock and some of the uncertainty due to the propagation of the
> signals through the atmosphere.  The average jitter on a common-
> view measurement with 1 day of averaging is about +/- 2 ns.  Note that 
> this is much better than can be obtained by observing GPS signals directly,
> since the common-view method cancels out many of the fluctuations
> in GPS time (both thost that are due to fluctuations in the clock and
> the atmosphere and those that are intentionally applied by the
> controllers).
> 
>    There were a number of other side-issues raised in the note that
> you sent, but I think I have answered the primary question.  If you
> have more questions, please ask.
> 
> Judah Levine
> Time and Frequency Division
> NIST Boulder
> 1 February 1996

Jim
-- 
All opinions expressed are mine, if you   | "I will not be pushed, stamped,
think otherwise, then go jump into turbid | briefed, debriefed, indexed, or
radioactive waters and yell WAHOO !!!     | numbered!" - #1, "The Prisoner"
   jbryant@argus.flash.net - FlashNet Communications - Ft. Worth, Texas