with the assumption that he seems to be fine right after a sync,
(seemingly supported in the OP) reconfiguring the windows time service
to update frequently seems to me to be the easiest answer.
under xp you can do so thus:
http://support.microsoft.com/kb/314054

_eric


On Thu, Jul 29, 2010 at 11:13 AM, Bob Camp <lists-***@public.gmane.org> wrote:
> Hi
>
> My observation is that the displayed clock on LH can be off by > 10 seconds.
> That's with the current beta code and Windows 7 on a quad processor machine
> or under XP on a dual core machine.
>
> Bob
>
> -----Original Message-----
> From: time-nuts-bounces-***@public.gmane.org [mailto:time-nuts-bounces-***@public.gmane.org] On
> Behalf Of Brooke Clarke
> Sent: Thursday, July 29, 2010 2:04 PM
> To: Discussion of precise time and frequency measurement
> Subject: [time-nuts] Can Lady Heather Keep Computer Clock On Time?
>
> Hi:
>
> I have a friend who's setting up an observatory and the PC that controls
> the telescope needs to have an accurate clock.
> The telescope can point to within arc seconds of a star and that implies
> that the computer clock needs to be within 50 ms.
> If he does a Windows NTP sync first thing in the evening after a few
> hours there's too big an error.  Running the observatory is like flying
> a 747, i.e. there's a lot to do and the time needs to be handled
> automatically, not by manual NTP updates.
>
> I know that TAC32 and a Motorola GPS will do this and you have a lot of
> options of how it does it.  For example at a specified time interval or
> when the computer clock differs from GPS by a specified amount of time
> (50 ms in this case).
>
> What are the options in LH?  I ask because it's a lower cost option then
> the Motorola GPS plus TAC32 option or building a NTP time server.
>
> --
> Have Fun,
>
> Brooke Clarke
> http://www.PRC68.com
>
>
>
> _______________________________________________
> time-nuts mailing list -- time-nuts-***@public.gmane.org
> To unsubscribe, go to
> https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
> and follow the instructions there.
>
>
>
>
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> To unsubscribe, go to https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
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>



--
--Eric
_________________________________________
Eric Garner

On 07/29/2010 03:57 PM, Mark Sims wrote:
> Yes, there is a time sync command that causes the program to set the system clock at periodic intervals or whenever it differs from GPS by a given amount.
> I'm still out on the "Project From Hell Mark II" and I don't remember all the gory details... I think /TSA on the command line says sync the time whenever the clocks differ by a millisecond. There is also /TSO /TSD /TSH /TSM /TSS to set it once, hourly, daily, every minute or second. There is also a /TSX command to specify the time offset from the Tbolt serial command to GPS (which is usually around 45 milliseconds). TS from the keyboard just syncs the clock once.
> _______________________________________________
> time-nuts mailing list -- time-nuts-***@public.gmane.org
> To unsubscribe, go to https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
> and follow the instructions there.

I realize this request is for Windows, but I thought I'd mention this
for the benefit of others.

I'm using tboltd by Ralph Smith on Linux. It provides the time to ntpd
and LH 3.00 beta can talk to tboltd via the TCP connection, so
monitoring can happen at the same time as the ntpd. It works great on
Linux, as well as BSD (for which it was designed):
http://www.mail-archive.com/time-nuts-***@public.gmane.org/msg26129.html

It runs well under wine like this:
wine heather.exe /IP=localhost:45000 /TW=250

The /etc/ntp.conf config file stanza looks like this. (I admit I've
guessed at the 0.0275 delay.)

# for attached GPS
tos mindist 0.030
server 127.127.28.0 minpoll 4 maxpoll 4 prefer
fudge 127.127.28.0 time1 0.0275 stratum 1 refid GPS

Serious use would probably call for a Soekris box, but not so serious
use lets me use the tbolt time signal for free, as I have it on for the
10MHz reference.

Leigh/WA5ZNU

Hi

There is a standard NTP driver that "talks Thunderbolt". The full blown NTP package is pretty easy to set up. It will hold ms accuracy slaved to a GPS.

Bob



On Jul 29, 2010, at 7:29 PM, Hal Murray <hmurray-8cQiHa/C+6Go9G/***@public.gmane.org> wrote:

>
>> The telescope can point to within arc seconds of a star and that implies
>> that the computer clock needs to be within 50 ms.
>
>> If he does a Windows NTP sync first thing in the evening after a few hours
>> there's too big an error.
>
> That looks like the classic time vs frequency problem.
>
> What is the primary goal? Pointing or tracking? Pointing requires time.
> Tracking requires frequency.
>
> If you are otherwise happy with "Windows NTP sync", you may be able to solve
> your problem by doing a sync before pointing at another object if it's been
> more than N hours since the last sync.
>
>
> Long song and dance.... [Remember, I don't run Windows so I may screwup
> anything that's Windows specific.]
>
>
> The typical PC has 2 crystals. One runs at 32 KHz. The other is usually
> 14.xxx (from early PC days) that gets PLLed up to make clocks for the CPU and
> PCI and USB and ...
>
> The 32KHz crystal runs the battery backed RTC/TOY/CMOS clock. It's a watch
> crystal so it should be pretty good. But it's not very convenient for
> keeping time at the microsecond level.
>
> The 14 MHz crystal is stable, but typically not very accurate. (Remember low
> cost.) That's accurate at the PPM level, it will be fine if you just put a
> scope on it. It may be off by 50 PPM. Even if the hardware is good, the
> software can screw things up. (Linux is good at this. Current kernels don't
> get a consistent answer on the same hardware. Jumps by 200 PPM from boot to
> boot are not uncommon.)
>
> [Network and audio and ??? cards typically have a separate crystal. They are
> usually not convenient for timekeeping but if you do serious audio work you
> can measure it's actual frequency.]
>
> Let's see if I can do the math right...
>
> 3 hours is 10,000 seconds. 50 PPM times 10,000 seconds is 500,000
> microseconds. So if the clock is off by 50 PPM, it will drift 1/2 second in
> 3 hours. Even 5 PPM will drift 50 ms in 3 hours.
>
>
> The main reason for running real ntpd rather than just setting the time
> occasionally is that ntpd will figure out how far off the frequency is and
> correct for it. ntpd calls that fudge factor "drift" and prints it out in
> PPM with 3 digits to the right of the decimal point.
>
> If all you need is 50 ms, you should be able to get that most of the time by
> just running ntpd over the net. It's sure worth a try. It may not be good
> enough if you have a crappy net connection or change from no-load to
> uploading tons of data from observations earlier in the evening. (Contact me
> off list if you want help in monitoring a ntp server and/or setting up and
> interpreting its log files.)
>
>
>
> Odds and ends to keep in mind...
>
> Modern PCs use spread spectrum clocking. That fudges things by 1 or 1/2 % or
> so which is huge in terms of PPM. The point is that you have to measure it.
> Just doing the math from the nominal CPU frequency isn't good enough.
>
> The actual frequency is temperature dependent, so things will change if you
> open the roof and let the cold air in or the CPU changes from idle (or off)
> to working hard. The ballpark is 1 PPM per 10 F.
>
> One of the classic ways to screwup timekeeping is to miss interrupts,
> typically because some other interrupt routine is running too long. This was
> easy to tickle on (very) old Linux systems that used PIO rather than DMA for
> disk transfers. I only mention it because you might have some strange
> hardware with buggy interrupt routines.
>
> Normal Windows clocks tick every 10 ms. Windows has a multimedia mode that
> does much better. There is a switch in the Registry or something. It may
> help to use that mode. I think you want to leave it on. (The Meinberg
> ntpd-installer package turns it on.)
>
> ntpd is both a client and server. A system will act as a client to get time
> from lower stratum servers and act as a server to provide time to higher
> stratum servers.
>
>
>
> --
> These are my opinions, not necessarily my employer's. I hate spam.
>
>
>
>
> _______________________________________________
> time-nuts mailing list -- time-nuts-***@public.gmane.org
> To unsubscribe, go to https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
> and follow the instructions there.
>

Hi Hal:

The key thing is pointing, not tracking (where a guide star is commonly
used).
A TPoint model is made by pointing to known stars and the quality of the
model depends on good computer time.

Have Fun,

Brooke Clarke
http://www.PRC68.com


Hal Murray wrote:
>
>> The telescope can point to within arc seconds of a star and that implies
>> that the computer clock needs to be within 50 ms.
>>
>
>> If he does a Windows NTP sync first thing in the evening after a few hours
>> there's too big an error.
>>
> That looks like the classic time vs frequency problem.
>
> What is the primary goal? Pointing or tracking? Pointing requires time.
> Tracking requires frequency.
>
> If you are otherwise happy with "Windows NTP sync", you may be able to solve
> your problem by doing a sync before pointing at another object if it's been
> more than N hours since the last sync.
>
>
> Long song and dance.... [Remember, I don't run Windows so I may screwup
> anything that's Windows specific.]
>
>
> The typical PC has 2 crystals. One runs at 32 KHz. The other is usually
> 14.xxx (from early PC days) that gets PLLed up to make clocks for the CPU and
> PCI and USB and ...
>
> The 32KHz crystal runs the battery backed RTC/TOY/CMOS clock. It's a watch
> crystal so it should be pretty good. But it's not very convenient for
> keeping time at the microsecond level.
>
> The 14 MHz crystal is stable, but typically not very accurate. (Remember low
> cost.) That's accurate at the PPM level, it will be fine if you just put a
> scope on it. It may be off by 50 PPM. Even if the hardware is good, the
> software can screw things up. (Linux is good at this. Current kernels don't
> get a consistent answer on the same hardware. Jumps by 200 PPM from boot to
> boot are not uncommon.)
>
> [Network and audio and ??? cards typically have a separate crystal. They are
> usually not convenient for timekeeping but if you do serious audio work you
> can measure it's actual frequency.]
>
> Let's see if I can do the math right...
>
> 3 hours is 10,000 seconds. 50 PPM times 10,000 seconds is 500,000
> microseconds. So if the clock is off by 50 PPM, it will drift 1/2 second in
> 3 hours. Even 5 PPM will drift 50 ms in 3 hours.
>
>
> The main reason for running real ntpd rather than just setting the time
> occasionally is that ntpd will figure out how far off the frequency is and
> correct for it. ntpd calls that fudge factor "drift" and prints it out in
> PPM with 3 digits to the right of the decimal point.
>
> If all you need is 50 ms, you should be able to get that most of the time by
> just running ntpd over the net. It's sure worth a try. It may not be good
> enough if you have a crappy net connection or change from no-load to
> uploading tons of data from observations earlier in the evening. (Contact me
> off list if you want help in monitoring a ntp server and/or setting up and
> interpreting its log files.)
>
>
>
> Odds and ends to keep in mind...
>
> Modern PCs use spread spectrum clocking. That fudges things by 1 or 1/2 % or
> so which is huge in terms of PPM. The point is that you have to measure it.
> Just doing the math from the nominal CPU frequency isn't good enough.
>
> The actual frequency is temperature dependent, so things will change if you
> open the roof and let the cold air in or the CPU changes from idle (or off)
> to working hard. The ballpark is 1 PPM per 10 F.
>
> One of the classic ways to screwup timekeeping is to miss interrupts,
> typically because some other interrupt routine is running too long. This was
> easy to tickle on (very) old Linux systems that used PIO rather than DMA for
> disk transfers. I only mention it because you might have some strange
> hardware with buggy interrupt routines.
>
> Normal Windows clocks tick every 10 ms. Windows has a multimedia mode that
> does much better. There is a switch in the Registry or something. It may
> help to use that mode. I think you want to leave it on. (The Meinberg
> ntpd-installer package turns it on.)
>
> ntpd is both a client and server. A system will act as a client to get time
> from lower stratum servers and act as a server to provide time to higher
> stratum servers.
>
>
>
>

Hal Murray wrote:
> brooke-***@public.gmane.org said:
>
>> The telescope has around arc second pointing capability so I think he needs
>> a hundredth of a second or slightly better.
>>
> That doesn't sound right. What's the field of view of the telescope?
>
>
Worst case (declination = 0), 1 arc second of pointing is equivalent to
about 1/15 (~67ms) second of time.
The telescope field of view isn't really relevant (as long as its
greater than 1 arcsec) if one needs to maintain 1 arc second pointing.
In this case a timing accuracy of 10ms isn't overly conservative.
If one merely needs to ensure that the telescope can acquire the
object of interest so that it is well within the field of view of an
eyepiece, then 1 arc second pointing isnt necessary.
However if one needs to place the object of interest directly on a
spectrometer slit or fibre then a somewhat lower pointing error is
desirable.

To achieve 1 arc second pointing accuracy usually requires correcting
for such effects as
Tube flexure
The orthogonality error between axes
drive train eccentricities
The value of dUT1.
etc

One also requires high resolution encoders (or equivalent on each axis).
Alternative a stellar compass system like those used to gage the
orientation of spacecraft can be employed.
Despite what Meade would have one believe the application of such
devices to telescope pointing did not originate with them.


>
>> I've found some NMEA software that will set a PC clock, but it expects the
>> data on a COM port. Don't know how it might work with USB data.
>>
> I don't use Windows, but most likely it will magically show up as COMx when
> you plug it in.
>
>

>
>>> It is not clear whether the message is fixed of if it will reply
>>> to queries.
>>>
> Normally, NMEA devices send a clump of "sentences" each second. Usually, you
> can turn off the ones you don't want.
>
>
>

Bruce

Hi Hal:

FOV is 0.2 min x 0.3 min @0.47arcsec/pixel when using 1x1 binning. The
seeing doesn't often justify 1x1 binning.

Mount is the Paramount ME.
http://www.bisque.com/help/paramountme/performance_specifications.htm
There's a software package called TPoint where you manually point to
known stars and that data is used to fit a model of the common mount
errors and so correct them. For example if the RA and DEC axis are not
at exactly 90 degrees. After doing many dozens of stars this correction
(and the PEC correction) allow making images without a guide star for
say 10 minutes, something that's impossible on a Meade or Celestron type
setup.

The scope is a Planewave 17":
http://www.planewave.com/index.php?page=1&id0=0&id=1

Camera is SBIG STL-11000M
http://www.sbig.com/sbwhtmls/online.htm

Have Fun,

Brooke Clarke
http://www.PRC68.com


Hal Murray wrote:
> brooke-***@public.gmane.org said:
>
>> The telescope has around arc second pointing capability so I think he needs
>> a hundredth of a second or slightly better.
>>
> That doesn't sound right. What's the field of view of the telescope?
>
>
>
>> I've found some NMEA software that will set a PC clock, but it expects the
>> data on a COM port. Don't know how it might work with USB data.
>>
> I don't use Windows, but most likely it will magically show up as COMx when
> you plug it in.
>
>
>
>>> It is not clear whether the message is fixed of if it will reply
>>> to queries.
>>>
> Normally, NMEA devices send a clump of "sentences" each second. Usually, you
> can turn off the ones you don't want.
>
>
>
>

In message <4D336A19.40709-***@public.gmane.org>, "Dr. Frank Stellmach" writes:

>High cap value Ceramics are available since years, [...]

Can you clarify one thing for me: When I studied datasheets for these
it looked like they drop 50% of their capacitance at a DC voltage
of 10-20V.

Doesn't that make them a so-so bargain for power supply bulk capacitance ?

--
Poul-Henning Kamp | UNIX since Zilog Zeus 3.20
phk-***@public.gmane.org | TCP/IP since RFC 956
FreeBSD committer | BSD since 4.3-tahoe
Never attribute to malice what can adequately be explained by incompetence.

On Fri, Mar 18, 2011 at 12:29 PM, Hal Murray <hmurray-8cQiHa/C+6Go9G/***@public.gmane.org> wrote:
>
>> From what I can learn about "seeing" the atmosphere instability is too
>> great to allow making measurements optically in the 1 ms area.
>
> There has been some interesting amateur work done on taking lots of
> short-exposure pictures and sifting through them to find the good ones.  (I
> can't find a good URL right now.)

Video is used for imaging planets. They are bright because like earth
they are lit by the sun. But measurement is different from imaging.
For this job we don't need pictures. The method using by FASST is
called "drift scan". The images of the sky is allowed to move over a
large CCD sensor. The telescope does not track the sky so the stars
images drift. CCD sensors are read out one row at a time then the
entire images is shifted down and the next ros is read. It a drift
scan camers the charge shifting in the CCD is synchronized to the
motion of the image. The result is a very. long image. Think of
it as like a flat bad scanner ony the image moves not the sensor.
This allows for some longer exposures and also covers a lot of the
sky. One BIG advantage of drift scan is that the telescope is bolted
down solid and never moves, so uncertainty in pointing is greatly
reduced.

The FASST camera continously a large part of the sky as it drifts
overheadand they match that data to a catalog of stars and then know
the rate the sky is drifting and thenthe rate the Earth turns

I worked on a drift scan camera project a few years back. We were
able to generate the wave forms to control the CCD in software. The
Earth does not really turn all that fast I had a prtottype camera
mounted on my Garage roof for a long time, It used a chaep telephoto
lens (135mm f/2.8) as the telescopes and we were getting surprizing
accuracy for a "junk box" optical system. An example of one of the
prototypes is the white tripple lens unit here
http://www.tass-survey.org/. Software ran under a rel-time version
of Linux with timming by NTP but later re-calibratd by the stars
themselves. Our system not not nearly as good as FASST, not even
close but used many of the same techniques



--
=====
Chris Albertson
Redondo Beach, California

> That's an interesting idea, but I think all the orbit data for GPS satellites
> is Earth relative rather than star relative. I wonder if the group that
> drives the GPS satellites even knows their location relative to the stars.
> I'll bet not.
>

I'll bet they do. Lots of earth orbiting satellites use star trackers
for position determination.

Indeed those posts are from 2003 the car plant could be closed these days.
But I do indeed receive wwvb I think pretty well with a loop and preamp. Its
always been a challenge on the east coast and even Michigan when I first
started tinkering way to many years ago.
Pretty much before all these switching power supplies and cpfls etc.
Regards

On Sun, Mar 27, 2011 at 9:03 PM, Hal Murray <hmurray-8cQiHa/C+6Go9G/***@public.gmane.org> wrote:

>
> brooke-***@public.gmane.org said:
> > John Mills (THE NTP guru) has written a number of papers on and built
> > examples of a matched filter type receiver for the HF station WWV, but
> the
> > ideas would also be applicable to a WWVB receiver. The performance he
> gets
> > from WWV would knock your socks off so I expect a WWVB version would be
> > even better. In addition there are some things that could be done to
> > improve it.
>
> I assume you mean Dave Mills rather than John.
> http://www.ece.udel.edu/~mills/index.html
>
> He's basically given up on WWVB. In his area, there is too much crap
> around
> 60 KHz, mostly from switching power supplies.
> http://lists.ntp.org/pipermail/questions/2003-August/000106.html
> http://lists.ntp.org/pipermail/questions/2006-April/009958.html
>
>
>
> --
> These are my opinions, not necessarily my employer's. I hate spam.
>
>
>
>
> _______________________________________________
> time-nuts mailing list -- time-nuts-***@public.gmane.org
> To unsubscribe, go to
> https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
> and follow the instructions there.
>

Think trying to measure the distance between two distant moving spacecraft
with no idea what the gravitational gradient is between them or the ability
to measure the doppler.

Unless, of course, Bill is doing much different things than he was when I
last ran into him. :)



On Mon, Feb 20, 2012 at 3:32 PM, Hal Murray <hmurray-8cQiHa/C+6Go9G/***@public.gmane.org> wrote:

>
> > You may be able to do a similar thing in your receivers. For example if
> the
> > master node were to send a timing message at known times (say once at
> the
> > top of every hour) the receivers could use that to determine their local
> > clock offset and rate for those cases where the path was the same (or
> maybe
> > even for a list of paths).
>
> Nope. The problem is queuing delays in routers. Satellites don't have
> queues.
>
> I think those delays is what he is trying to measure.
>
>
> --
> These are my opinions, not necessarily my employer's. I hate spam.
>
>
>
>
> _______________________________________________
> time-nuts mailing list -- time-nuts-***@public.gmane.org
> To unsubscribe, go to
> https://www.febo.com/cgi-bin/mailman/listinfo/time-nuts
> and follow the instructions there.
>

On Mon, Jul 21, 2014 at 11:01:19PM -0700, Hal Murray wrote:
> > I expect that there's date and time information being sent in the header of
> > every phone call, maybe even before the first ring along with the Caller ID
> > info.

> Wiki says CallerID is sent between the first and second ring, and includes
> the date and time.
> http://en.wikipedia.org/wiki/Caller_ID#Operation

Some old modems will happily decode it for you. I compared it to
NTP at some point last year. The time stamp was only given to the
nearest minute, and for my exchange it was pretty terrible - it was
slow by about 90s for a few months. I was considering adding it to
my leap second measurements, but there didn't seem to be much point.

David.

Hi Hal:

I think there were a number of slave clock systems and some of them could do DST/ST changes and/or catch up from a power
failure.
That very well might have been what you heard.

To me the winding sounds like a muffled air compressor.
The setting sounds like Thunk.
Mail_Attachment --
Have Fun,

Brooke Clarke
http://www.PRC68.com
http://www.end2partygovernment.com/2012Issues.html
http://www.prc68.com/I/DietNutrition.html
Hal Murray wrote:
> ***@pacific.net said:
>> The click-click-click... is the self winding. A solenoid vibrates back and
>> forth and a pawl and ratchet winds the main spring.
> I don't think that's what I was referring to. It was a long time ago so my
> memory may be buggy.
>
> The click-click-click... that I remember was loud enough to distract the
> class. It only happened occasionally, ballpark of once per month or less.
> The minute hand was making a step with each click.
>
> I assumed there was some mechanism to remotely set the clock. I think it
> ended up roughly correct. (I didn't even have a watch back then.)
>
> Was there any alternative to SWCC technology in the 1950s time frame?
>
>
>> There's a heart shaped cam that forces the hour, minute and if the clock has
>> one the second hand to 12:00 and holds them there until the sync pulse goes
>> away. Note the second hand only was used on clocks in radio stations so they
>> could join the network. For that 1 second was close enough.
> Is that one cam that gets all the hands or a separate cam for each hand?
>
>
>

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Hi Hal:

Yes for level shifting. Most micro controllers have the UART built-in so that's all that's needed.
I haven't got my boxes so don't know what chips are in them.
Mail_Attachment --
Have Fun,

Brooke Clarke
http://www.PRC68.com
http://www.end2partygovernment.com/2012Issues.html
http://www.prc68.com/I/DietNutrition.html
Hal Murray wrote:
> ***@pacific.net said:
>> UARTs are not mandatory, a simple transistor level shifting circuit is all
>> that's needed for TTL/RS-232 levels.
> I think you are confusing UARTs with level shifters.
>
> In the old days, transistors were expensive enough that a 68000 class CPU was
> all that could fit on a chip. All memory and peripherals were off chip.
>
> While not quite mandatory, most of the time it made sense to use a UART chip.
> If you had a FPGA, you could put a simple UART in there. (But back then,
> FPGAs weren't very big either.) If the CPU was idle, you could bit-bang
> things.
>
>

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Hi Hal:

I think the cal process is essentially a time domain reflection measure of cable length. The GPS receiver and the cable
cal hardware would be in the antenna unit.
The 1 PPS signal would be aligned at the output of the cable.

--
Have Fun,

Brooke Clarke
http://www.PRC68.com
http://www.end2partygovernment.com/2012Issues.html
The lesser of evils is still evil.

-------- Original Message --------
> ***@pacific.net said:
>> At one point they were looking into making a GPS time receiver where the
>> cable length calibration would be built-in.
> How would you do that?
>
> The obvious way is to compare the time you get with a known-good time, but if
> you had that, why would you want this new GPS with an unknown cable length.
>
> You might be able to do it by measuring the DC drop. Getting enough accuracy
> seems tough.
>
>

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and follow the instructions there.

We have a smart antenna where the receiver is in the antenna housing and the link to the timing receiver is digital over coax. On that, we can run a variant of DTI (DocSis Timing Interface) which calibrates the cable delay automagically. Not sure what the original question was but yes, it's possible.

-----Original Message-----
From: time-nuts [mailto:time-nuts-bounces+greg.dowd=***@febo.com] On Behalf Of Hal Murray
Sent: Wednesday, June 29, 2016 12:29 PM
To: Discussion of precise time and frequency measurement
Cc: ***@megapathdsl.net
Subject: [time-nuts] Cable length calibration

EXTERNAL EMAIL


***@pacific.net said:
> At one point they were looking into making a GPS time receiver where
> the cable length calibration would be built-in.

How would you do that?

The obvious way is to compare the time you get with a known-good time, but if you had that, why would you want this new GPS with an unknown cable length.

You might be able to do it by measuring the DC drop. Getting enough accuracy seems tough.


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--------
In message <***@ip-64-139-1-69.sjc.megapath.net>, Hal Mu
rray writes:

>> At one point they were looking into making a GPS time receiver where the
>> cable length calibration would be built-in.
>
>How would you do that?

TDR ?

If it wasn't behind a choke, the inrush current to the antenna
preamp power filtering capacitor could be measured, but the choke
ruins that.

The trouble is how to do it without frying the antenna preamp...


Seriously...

GPS antennas and receivers are cheap, I would just use two GPS antennas
with a known difference in cable-length.


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We are all time nuts, so there's an obvious answer: What you do, is raise
the GPS up to a height the same as the cable length. You then drop it,
measure the time until it hits the ground, and use d = 0.5 a * t * t to
calculate d. Then you correct for the velocity factor.

Tim N3QE

On Wed, Jun 29, 2016 at 3:28 PM, Hal Murray <***@megapathdsl.net> wrote:

>
> ***@pacific.net said:
> > At one point they were looking into making a GPS time receiver where the
> > cable length calibration would be built-in.
>
> How would you do that?
>
> The obvious way is to compare the time you get with a known-good time, but
> if
> you had that, why would you want this new GPS with an unknown cable length.
>
> You might be able to do it by measuring the DC drop. Getting enough
> accuracy
> seems tough.
>
>
> --
> These are my opinions. I hate spam.
>
>
>
> _______________________________________________
> time-nuts mailing list -- time-***@febo.com
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Use of a smaller opening would be the first strategy for getting higher Q.
Making sure that the walls of the vessel were solid reflectors would be
an important factor, too.

I noted that several of his sustained oscillators were basically either
relaxation or blocking oscillators, neither of which is noted for good
phase noise performance. Even the pendulum clock mechanism
was interfering severely with the pendulum's motion- if you look
closely you can see that the pendulum bob's position versus time
function was a severely clipped waveform.

The flex hose demonstration was interesting in that different regimes
of swinging speed resulted in oscillation in different modes. I wonder
why. But in hearing people learning to play different musical instruments,
mostly wind instruments but also including the violin, I was once
moved to say that playing these devices the art was in making an
oscillator run in a resonator mode other than the "natural" one.

For an interesting look at oscillating modes and a really oddball
sustained oscillator, view https://www.youtube.com/watch?v=m6631u7d4E0.
and/or google "mercury beating heart". The electrochemical effect
makes the blob oscillate between a hunched-up shape and a flattened
shape.

If given time, this hunching oscillation "pumps" a degenerate parametric
oscillation between the two triangular shapes at nominally half the rate
of the original oscillation. I first saw this demonstrated in high school,
but the demonstrator also could not get a sustained oscillation. I
thought about that for a while and decided to try a little external stimulus
in the form of low voltage DC from an external supply. After a little
optimization it worked beautifully and could run for hours on end with
little of no attention, giving me the luxury of trying a range of different
blob sizes. With different sizes I could get sustained parametric
oscillation in four different modes: 2-sided, 3-sided (as seen in the
You-Tube clip), 4-sided, and with difficulty even 5-sided.

Of course I didn't really understand what was going on at the time,
and didn't arrive at the parametric oscillation theory until years later.
BTW, I used a baking soda solution instead of a chromium-based
chemistry, and an electrode coming down from the top center, with
a large ring surrounding the mercury blob as the other electrical
connection.

Solution concentration, voltage, electrode tip height, and electrical
polarity were the parameters that had to be adjusted for best
performance. A mercury blob about one cm across in its resting
state seemed to be a good starting point. For polarity, use the
one that results in the blob's hunching up when the electrode tip is
gradually lowered into contact with the blob. If the other stuff
is not too far off, it will quickly take off oscillating at that point.

I've been wondering whether this could be made to work with
Galinstan obtained from modern-day clinical thermometers,
instead of that dreaded mercury. A worthwhile experiment
to try.

I never did get around to measuring the Alan Variance of one
of these oscillators; indeed, I didn't even hear of the concept
until years later. It's probably not up to Time-Nuts' standards.

Dana

On Fri, Dec 8, 2017 at 4:59 AM, Hal Murray <***@megapathdsl.net> wrote:

> What's the Q of a Helmholtz Resonator? What do I do to make a high(er) Q
> version?
>
> With a narrow band filter, it might make a neat demo/toy to pull an audio
> signal out of the noise. With 2 at different frequencies you could
> demonstrate FSK.
>
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>
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The Q of Helmholtz resonators is derived here:
https://en.wikibooks.org/wiki/Acoustics/Flow-induced_Oscillations_of_a_Helmholtz_Resonator

Some Q measurements of bottles are described here:
https://math.dartmouth.edu/archive/m5f10/public_html/proj/ArainGolvach.pdf

--
Bill Byrom N5BB

On Sat, Dec 9, 2017, at 01:39 AM, Hal Murray wrote:
>
> ***@gmail.com said:
> > The flex hose demonstration was interesting in that different regimes of
> > swinging speed resulted in oscillation in different modes. I wonder why.
>
> It depends on the speed of the air going through the tube.
>
> https://www.youtube.com/watch?v=4aJ36-TlPD4
>
> http://www.exo.net/~pauld/activities/AAAS/aaas2001.html
> http://www.exo.net/~pauld/summer_institute/summer_day13music/Whirly.html
>
>
> --
> These are my opinions. I hate spam.
>
>
>
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I don't know of any particular reason why a DVD-player laser should be
faster,
since neither CD nor DVD players need to deliberately modulate the lasers
anyway. At least, that's the first blush answer.

However, these diode lasers are generally noisy, apparently due to the
inevitable presence of optical reflections back into the diodes. I once
read that deliberately FM'ing the laser by applying a high frequency RF
tone along with the DC bias current could be helpful in mitigating the
problem. But this was in connection with the *analog* Laser Disk video
recording format. I don't know if the laser noise was ever much of a
problem
with reading the digital formats of CDs and DVDs. If not, then surely the
makers of diodes for these mass market applications would not be investing
effort in making the lasers fast.

On additional factor is that CD players and DVD players use different light
wavelengths: ~780 nm for CDs, ~650 nm for DVDs. It might be that the
difference in semiconductor composition between the two types makes
a significant difference in the response speed. However, I doubt that this
would would be relevant for present purposes, unless Rb also has some
*useful* transitions in the 650 nm regime.

Dana


On Thu, Jun 14, 2018 at 11:25 PM, Hal Murray <***@megapathdsl.net>
wrote:

>
> ***@gmail.com said:
> > I've been told that CD player type diodes can be successfully modulated
> up to
> > about 600 MHz, but that going much further is either difficult or perhaps
> > impossible.
>
> Are DVD lasers faster?
>
>
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>
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"Exactly" on the time nuts list... 😊


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On Fri, Jun 22, 2018 at 1:27 PM, Hal Murray <***@megapathdsl.net> wrote:

>
> ***@pacific.net said:
> > I'm experimenting with a WSPR beacon transmitter and part of how it works
> > depends on pushing the start button at exactly 2 seconds past the
> minute.
>
> What do you mean by "exactly"?
>

I think WSPR has a +/-2s window for the start of a transmission. It really
isn't all that "exact" and certainly nothing in the way of time-nuts
definition of accuracy.

The most popular WSPR implementation runs on a PC and uses a sound-card to
generate the baseband signal and then uses an SSB transceiver to upconvert
to the desired output frequency. Even worst-case the standard NTP
implementation on Windows is more than sufficient for synchronization.

--



Brian Lloyd
706 Flightline
Spring Branch, TX 78070
***@lloyd.aero
+1.210.802-8FLY (1.210.802-8359)
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