HP 3586 entirely referenced to 10MHz: A solution II
List,
Wrote: Your simple idea is a non-workable concept.
Now how do you actually know that? It’s an opinion that would have to be proved or disproved by actually doing it. I based my opinion on the graph that showed the HP crystal frequency change verses temperature which was IIRC, quite small.
Wrote: Instead of whining about the complexity<snip>
Well, I’m sorry if a different viewpoint, in the way I expressed mine, causes you to give me a personal derogatory label instead of the usual gracious responses others on the list have provided me.
Wrote: why not contact Bert or Paul Swed and see if one of them would do you a favor and build the item for you.
Well that never occurred to me. If that thought had occurred to me, I wouldn’t have pursued it for two reasons.
-
It almost works. It it is a great improvement over the stock HP crystal oscillator but it still has some small errors do to the DDS scheme.
-
I have five working 3586B units and as I understand the article, I might need to have five different programs as each unit may have different nuances. And as I noted in my post, I have no programming ability or any source to one. And I also said in my post that if one can do it to go for it.
Wrote: I do not believe the hookup part is that hard to do and if you follow instructions well it should be quite doable.
I completely agree. I’ve worked on the innards of mine changing out a WECO connector for a BNC. The 3586 at 58 pounds it is heavy as heck because of all of its shielding but is surprisingly modular and easy to open and dis-assemble. (One should seriously consider replacing the power supply electrolytics is one is going to open the beast up.)
For the present I plan on using the measurement technique that Burt Weiner K6OQK so graciously shared on the net and to us on the list. Locking my 3586 and 3336 to my GPSDO should allow me to get good results. I also can compare my first GPSDO to a second redundant GPDSO. This I can understand and do.
Regards,
Perrier
Perry,
The bad part of your "solution", that you seem to be missing is the
BFO will not be locked or referenced to any standard but itself. If
that is acceptable to you, then there is no need to reference your 3586
to anything but itself.... rendering the entire subject void to you.
The DDS solution makes the BFO frequency, which is very important in using
audio solutions to frequency measurement with 3586 referenced to the same
standard as the rest of the unit. The small offset (not error) is easily
removed by simply subtracting, or adding it when figuring the result. It
is constant, and will never change.
Unlike simply stabilizing the BFO crystal as you propose.
-Chuck Harris
Perry Sandeen wrote:
List,
Wrote: Your simple idea is a non-workable concept.
Now how do you actually know that? It’s an opinion that would have to be proved
or disproved by actually doing it. I based my opinion on the graph that showed
the HP crystal frequency change verses temperature which was IIRC, quite small.
Wrote: Instead of whining about the complexity<snip>
Well, I’m sorry if a different viewpoint, in the way I expressed mine, causes you
to give me a personal derogatory label instead of the usual gracious responses
others on the list have provided me.
Wrote: why not contact Bert or Paul Swed and see if one of them would do you a
favor and build the item for you.
Well that never occurred to me. If that thought had occurred to me, I wouldn’t
have pursued it for two reasons.
-
It almost works. It it is a great improvement over the stock HP crystal
oscillator but it still has some small errors do to the DDS scheme. -
I have five working 3586B units and as I understand the article, I might need
to have five different programs as each unit may have different nuances. And as I
noted in my post, I have no programming ability or any source to one. And I also
said in my post that if one can do it to go for it.
Wrote: I do not believe the hookup part is that hard to do and if you follow
instructions well it should be quite doable.
I completely agree. I’ve worked on the innards of mine changing out a WECO
connector for a BNC. The 3586 at 58 pounds it is heavy as heck because of all of
its shielding but is surprisingly modular and easy to open and dis-assemble. (One
should seriously consider replacing the power supply electrolytics is one is going
to open the beast up.)
For the present I plan on using the measurement technique that Burt Weiner K6OQK
so graciously shared on the net and to us on the list. Locking my 3586 and 3336
to my GPSDO should allow me to get good results. I also can compare my first
GPSDO to a second redundant GPDSO. This I can understand and do.
Regards,
Perrier
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On Sat, Apr 02, 2011 at 04:13:55PM -0400, Chuck Harris wrote:
Unlike simply stabilizing the BFO crystal as you propose.
Has anyone given any thought to an alternative - phase locking
the original BFO Xtals with a very narrow bandwidth loop to something
derived from the 10 Mhz standard in such a way that the final frequency
of the BFO comes out exact ? Looks to me (superficially without looking
at the schematic carefully) like this might be possible too...
--
Dave Emery N1PRE/AE, die@dieconsulting.com DIE Consulting, Weston, Mass 02493
"An empty zombie mind with a forlorn barely readable weatherbeaten
'For Rent' sign still vainly flapping outside on the weed encrusted pole - in
celebration of what could have been, but wasn't and is not to be now either."
On Mon, Apr 04, 2011 at 02:00:14AM -0400, David I. Emery wrote:
On Sat, Apr 02, 2011 at 04:13:55PM -0400, Chuck Harris wrote:
Unlike simply stabilizing the BFO crystal as you propose.
Has anyone given any thought to an alternative - phase locking
the original BFO Xtals with a very narrow bandwidth loop to something
derived from the 10 Mhz standard in such a way that the final frequency
of the BFO comes out exact ? Looks to me (superficially without looking
at the schematic carefully) like this might be possible too...
To elaborate a tiny bit, if you divide 10 MHz to 25 HZ you could
use that as the reference for a classic PLL loop that stabilized the
crystals with a varactor... provided of course suitable low pass
filtering was used. There are also approaches involving doing early
late sampling of the BFOs on selected edges of the 10 MHz clock which
could be done more digitally in a FPGA.
I presume one can pull the existing crystals enough with some hacking
of the oscillator to add a varactor...
This would avoid a non integer frequency setting where the DDS
approach does not (unless you multiply by 3 to 30 MHz first I think).
--
Dave Emery N1PRE/AE, die@dieconsulting.com DIE Consulting, Weston, Mass 02493
"An empty zombie mind with a forlorn barely readable weatherbeaten
'For Rent' sign still vainly flapping outside on the weed encrusted pole - in
celebration of what could have been, but wasn't and is not to be now either."
Basically, the higher the division ratio in a PLL synthesizer,
which is what you are describing, the greater the phase noise.
You can think of it this way: Both the reference, and the oscillator
being controlled, need to be divided down to some common frequency
that you feed to the phase detector. The entire time the counter is
counting up the cycles to get you a cycle of that common frequency,
the oscillator is not being disciplined. It is only after the
count gets done that the phase detector can compare the two signals
and create a correction correct for the error in the oscillator.
The DDS is essentially a hardware solution to finding a suitable
divider ratio to convert one frequency into another.
-Chuck Harris
David I. Emery wrote:
On Mon, Apr 04, 2011 at 02:00:14AM -0400, David I. Emery wrote:
On Sat, Apr 02, 2011 at 04:13:55PM -0400, Chuck Harris wrote:
Unlike simply stabilizing the BFO crystal as you propose.
Has anyone given any thought to an alternative - phase locking
the original BFO Xtals with a very narrow bandwidth loop to something
derived from the 10 Mhz standard in such a way that the final frequency
of the BFO comes out exact ? Looks to me (superficially without looking
at the schematic carefully) like this might be possible too...
To elaborate a tiny bit, if you divide 10 MHz to 25 HZ you could
use that as the reference for a classic PLL loop that stabilized the
crystals with a varactor... provided of course suitable low pass
filtering was used. There are also approaches involving doing early
late sampling of the BFOs on selected edges of the 10 MHz clock which
could be done more digitally in a FPGA.
I presume one can pull the existing crystals enough with some hacking
of the oscillator to add a varactor...
This would avoid a non integer frequency setting where the DDS
approach does not (unless you multiply by 3 to 30 MHz first I think).
"Basically, the higher the division ratio in a PLL synthesizer,
which is what you are describing, the greater the phase noise."
In that case, that may not be a problem. Since the oscillator is a crystal, phase noise should be low enough.
One other issue is that most crystals only want to move in one direction (with the varactor pulling trick), so if it is on the wrong side of where you want it, that won't work.
Otherwise, I have been thinking about that myself.
Didier KO4BB
Sent from my BlackBerry Wireless thingy while I do other things...
-----Original Message-----
From: Chuck Harris cfharris@erols.com
Sender: time-nuts-bounces@febo.com
Date: Mon, 04 Apr 2011 07:19:38
To: Discussion of precise time and frequency measurementtime-nuts@febo.com
Reply-To: Discussion of precise time and frequency measurement
time-nuts@febo.com
Subject: Re: [time-nuts] HP 3586 entirely referenced to 10MHz: A solution II
Basically, the higher the division ratio in a PLL synthesizer,
which is what you are describing, the greater the phase noise.
You can think of it this way: Both the reference, and the oscillator
being controlled, need to be divided down to some common frequency
that you feed to the phase detector. The entire time the counter is
counting up the cycles to get you a cycle of that common frequency,
the oscillator is not being disciplined. It is only after the
count gets done that the phase detector can compare the two signals
and create a correction correct for the error in the oscillator.
The DDS is essentially a hardware solution to finding a suitable
divider ratio to convert one frequency into another.
-Chuck Harris
David I. Emery wrote:
On Mon, Apr 04, 2011 at 02:00:14AM -0400, David I. Emery wrote:
On Sat, Apr 02, 2011 at 04:13:55PM -0400, Chuck Harris wrote:
Unlike simply stabilizing the BFO crystal as you propose.
Has anyone given any thought to an alternative - phase locking
the original BFO Xtals with a very narrow bandwidth loop to something
derived from the 10 Mhz standard in such a way that the final frequency
of the BFO comes out exact ? Looks to me (superficially without looking
at the schematic carefully) like this might be possible too...
To elaborate a tiny bit, if you divide 10 MHz to 25 HZ you could
use that as the reference for a classic PLL loop that stabilized the
crystals with a varactor... provided of course suitable low pass
filtering was used. There are also approaches involving doing early
late sampling of the BFOs on selected edges of the 10 MHz clock which
could be done more digitally in a FPGA.
I presume one can pull the existing crystals enough with some hacking
of the oscillator to add a varactor...
This would avoid a non integer frequency setting where the DDS
approach does not (unless you multiply by 3 to 30 MHz first I think).
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and follow the instructions there.
Hi Didier,
If you want to convert the Xtal to a VCO, you will have to adjust the parallel
capacitance so that the crystal can get above the desired frequency, and then
design the varactor circuit so that it can pull from there to below the desired
frequency...which should be possible if the crystal was capable of being tuned
on frequency.
The crystal might be high enough Q to run in a PLL with a very high division ratio,
but I would still expect it to hiccup around about the period of the divider.... but
as you say, it might not matter.
The DDS works out to be such a simple solution, I think the minuscule offset is
hardly worth getting worked up over.
-Chuck
shalimr9@gmail.com wrote:
"Basically, the higher the division ratio in a PLL synthesizer, which is what you
are describing, the greater the phase noise."
In that case, that may not be a problem. Since the oscillator is a crystal, phase
noise should be low enough.
One other issue is that most crystals only want to move in one direction (with the
varactor pulling trick), so if it is on the wrong side of where you want it, that
won't work.
Otherwise, I have been thinking about that myself.
Didier KO4BB
Hello Didier;
I don't have a copy of the schematic however I was
wondering if there are trim caps installed for these
crystals?? If so, then a varactor can tune above and
below in place of the mechanical cap if you remove it.
Undoubtedly there is some loading cap in the circuit
that could be tweaked a tad. Crystals drift over time
though, this could have an effect on this concept. It
may be that they have already drifted too far to tweak
with the VCO concept.
Also, there are many ways that a PLL ideas interact
with phase noise. If the PLL reference source is quieter
than the intrinsic noise of the VCO then the loop band
width does govern the close in noise spectrum. However,
there are many systems wherein the reference bandwidth
is very small and the VCO noise governsl. Take for
instance the PPS control of the GPSDO OXCO. The PPS
frequency reference is unable to reduce the noise of
the OXCO above about one half Hz, so the ultimate phase
noise above that frequency is that of the oscillator itself.
This can be a creative brain buster when working on
designs for these ideas.
My vote is to do a DDS synthesizer, this is a fine evolution
low in cost and easy to implement, to displace approximate
oscillators. What frequencies are you generating?
Regards;
Greg
On 4/4/2011 7:29 AM, Chuck Harris wrote:
Hi Didier,
If you want to convert the Xtal to a VCO, you will have to adjust the
parallel
capacitance so that the crystal can get above the desired frequency,
and then
design the varactor circuit so that it can pull from there to below
the desired
frequency...which should be possible if the crystal was capable of
being tuned
on frequency.
The crystal might be high enough Q to run in a PLL with a very high
division ratio,
but I would still expect it to hiccup around about the period of the
divider.... but
as you say, it might not matter.
The DDS works out to be such a simple solution, I think the minuscule
offset is
hardly worth getting worked up over.
-Chuck
shalimr9@gmail.com wrote:
"Basically, the higher the division ratio in a PLL synthesizer, which
is what you
are describing, the greater the phase noise."
In that case, that may not be a problem. Since the oscillator is a
crystal, phase
noise should be low enough.
One other issue is that most crystals only want to move in one
direction (with the
varactor pulling trick), so if it is on the wrong side of where you
want it, that
won't work.
Otherwise, I have been thinking about that myself.
Didier KO4BB
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On Mon, Apr 04, 2011 at 07:19:38AM -0400, Chuck Harris wrote:
Basically, the higher the division ratio in a PLL synthesizer,
which is what you are describing, the greater the phase noise.
No question about that, indeed.
But I am talking about a very low bandwidth loop (presumably
well under 1 HZ should work) which means the phase noise contribution
from the dividers and reference should be only inside that 1 Hz
bandpass. Outside of that the original crystal oscillator phase noise
should control, and while this won't improve that it also won't make it
any worse.
You can think of it this way: Both the reference, and the oscillator
being controlled, need to be divided down to some common frequency
that you feed to the phase detector. The entire time the counter is
counting up the cycles to get you a cycle of that common frequency,
the oscillator is not being disciplined. It is only after the
count gets done that the phase detector can compare the two signals
and create a correction correct for the error in the oscillator.
True, but I am pretty sure the original crystal oscillator (even
modified with a varactor for tuning) was not phase-noisier than the rest
of the instruments LOs. It is, after all, a LF crystal oscillator
running at 13 or 17 KHz with presumably a high Q crystal which shouldn't
to the first order have unreasonable phase noise in the band around it.
The original problem was that this oscillator was not locked to a
reference and could drift a few tenths of a HZ (and maybe even Hz)
randomly with temp - not that it had too much phase noise.
The DDS is essentially a hardware solution to finding a suitable
divider ratio to convert one frequency into another.
I do understand DDSes.
-Chuck Harris
--
Dave Emery N1PRE/AE, die@dieconsulting.com DIE Consulting, Weston, Mass 02493
"An empty zombie mind with a forlorn barely readable weatherbeaten
'For Rent' sign still vainly flapping outside on the weed encrusted pole - in
celebration of what could have been, but wasn't and is not to be now either."
I am thinking the answer is not the interesting thread.
Its yes, that approach was considered.
I can't speak for Bert but the issue has been understood for a long time
actually. At least 10 years since my first purchase.
When I consider a problem I tend to look at the trade offs trade offs. The
ability to actually be reproduced, simple, parts availability, low cost,
stable, and a lot of other factors. Kind of would anyone else ever build
something like X.
So when FPGAs get introduced into the thread it starts to change the
complexity of the project and the likelihood of very few actually having the
ability to design or enhance and then burn the chip.
The is a heck of answer to a tough problem at a cost of $ 8 total for both
chips.
Can be improved, gets more difficult as you improve it. Like everything
else.
Regards
Paul
WB8TSL
On Mon, Apr 4, 2011 at 5:33 PM, David I. Emery die@dieconsulting.comwrote:
On Mon, Apr 04, 2011 at 07:19:38AM -0400, Chuck Harris wrote:
Basically, the higher the division ratio in a PLL synthesizer,
which is what you are describing, the greater the phase noise.
No question about that, indeed.
But I am talking about a very low bandwidth loop (presumably
well under 1 HZ should work) which means the phase noise contribution
from the dividers and reference should be only inside that 1 Hz
bandpass. Outside of that the original crystal oscillator phase noise
should control, and while this won't improve that it also won't make it
any worse.
You can think of it this way: Both the reference, and the oscillator
being controlled, need to be divided down to some common frequency
that you feed to the phase detector. The entire time the counter is
counting up the cycles to get you a cycle of that common frequency,
the oscillator is not being disciplined. It is only after the
count gets done that the phase detector can compare the two signals
and create a correction correct for the error in the oscillator.
True, but I am pretty sure the original crystal oscillator (even
modified with a varactor for tuning) was not phase-noisier than the rest
of the instruments LOs. It is, after all, a LF crystal oscillator
running at 13 or 17 KHz with presumably a high Q crystal which shouldn't
to the first order have unreasonable phase noise in the band around it.
The original problem was that this oscillator was not locked to a
reference and could drift a few tenths of a HZ (and maybe even Hz)
randomly with temp - not that it had too much phase noise.
The DDS is essentially a hardware solution to finding a suitable
divider ratio to convert one frequency into another.
I do understand DDSes.
-Chuck Harris
--
Dave Emery N1PRE/AE, die@dieconsulting.com DIE Consulting, Weston, Mass
02493
"An empty zombie mind with a forlorn barely readable weatherbeaten
'For Rent' sign still vainly flapping outside on the weed encrusted pole -
in
celebration of what could have been, but wasn't and is not to be now
either."
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To unsubscribe, go to
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