After the big East Coast blizzard, the atmosphere in my ham shack became very dry. I sit in one of those desk chairs with little plastic wheels. The shack is carpeted. So when I roll from operating bench to workbench, the chair, the carpet, the dry air and I all become a kind of Van de Graaff generator. Yesterday, my hand brushed against the 16X2 LCD display on my new R2 phasing receiver. The pretty glowing numerals in that display disappeared in a small spark, never to return.
I swapped out another display I had, so all is well. But the repair was a pain in the neck, involving the soldering of some 16 LCD pins, so I don't want to do it again. I consulted with Pete Juliano N6QW who told me that this kind of LCD carnage is quite common in dry environments. He said he had cured the problem by placing a small piece of Plexiglas in front of his displays.
This got me thinking about those static protective bags that Digikey uses when shipping many of its components. Might the material from these bags prevent the loss of another display?
I retrieved a couple of these bags from the garbage and did a little test:
First, I rolled across the shack in the chair with a small screw-driver in hand. At the other end of the shack lies my well-grounded DX-100 transmitter. I moved the screwdriver close to the metal on-off switch. SPARK! It was visible, and quite audible in the AM broadcast receiver nearby.
Next I taped a small piece of this material over the switch and repeated the ride in the chair. No spark. Nada. I repeated this several times and always got the same result.
It appears that the material in the bag helps dissipated the static discharge over a wider area, preventing the spark. I quickly taped a piece of this material over the two LCD screens in my shack. It's not pretty, but it is temporary, and cheaper than a humidifier.
I'm not going to try this on the actual screens, but I do think these small pieces of material will help prevent another accidental frying of an LCD display.
Here is the Wiki on anti-static bags: https://en.wikipedia.org/wiki/Antistatic_bag
And here is the data sheet on the bags that I am using:
http://documents.staticcontrol.com/PDF/Static_Shielding_Bag_1000_Series.pdf
Podcasting since 2005! Listen to Latest SolderSmoke
Tuesday, January 26, 2016
Monday, January 25, 2016
1936 Shortwave Listener QSL card
I found this today while rummaging around in the shack. It is starting to fall apart so I figured I better digitize it before it turns into dust.
July 24, 1936. 7 am in Central Germany. 29.0 degrees Centigrade. Clear skies? German Shortwave Receiving Station DE 2518/F monitored W5AIR's contact with Irish station EI7F on 20 meter CW. The receiver was an OV2 Schnell tube (almost certainly a regen) fed by a 38.5 meter long antenna.
Conditions must have been pretty good -- they were approaching the peak of sunspot cycle 17.
Labels:
Germany,
Old radio,
propagation,
radio history,
Regens,
Short Wave Listening
Sunday, January 24, 2016
Listen to My R2 Phasing Receiver (formerly known as "The Frankenstein" )
I really like this receiver. Thanks to all who helped.
Labels:
Campbell-Rick,
direct conversion,
Phasing Rigs,
video
Saturday, January 23, 2016
Blizzard Prep Priorities: Protecting the 160 meter L network!
I'd been meaning to build a proper cover for my improvised 160 meter L network. The approach of Winter Storm Jonas pushed me into action yesterday afternoon.
First I mounted the variable cap (from an old Johnson rig) and the roller inductor on a suitably sized piece of wood:
Here it is at the feed point. Pretty cool, don't you think?
First I mounted the variable cap (from an old Johnson rig) and the roller inductor on a suitably sized piece of wood:
Then I put the tuner inside an old cooler. I drilled holes in the bottom for the coax and the antenna wire and the ground.
Here it is at the feed point. Pretty cool, don't you think?
And here it is 24 hours later:
The blizzard has been quite impressive. Early this morning it featured lightning and thunder!
Labels:
160 meters,
antennas,
weather
Some Inspiring Phasing Philosophy from KK7B
KK7B holding his original Mini-R2
Rick Campbell KK7B concludes Chapter 9 of "Experimental Methods in RF Design" with these inspiring words:
"An amateur who has built up a phasing receiver, looked at the I and Q channels on a dual trace oscilloscope, and tweaked the phase and amplitude adjustments while listening to an opposite sideband signal drop into the noise acquires a depth of understanding far beyond that of most wireless graduate students and many of their professors. The best part is that understanding of phasing systems comes from experimenting with simple circuits and thinking -- the tinkering comes first -- then the understanding. In this area the amateur with his simple workbench; primitive test equipment; and time to contemplate, has a profound advantage over the engineering student with a computerized bench and exam next week, and the professional engineer with a million-dollar lab and a technician to run it."
N2CQR Frankenstein R2 showing I and Q audio outputs
(No exam next week for me!)
Labels:
Campbell-Rick,
Phasing Rigs
Friday, January 22, 2016
Lee Snook W1DN's Amazing New Rig
Wow, I feel myself being pulled into the digital vortex. What a cool combination of digital and analog construction! I love that small spectrum 'scope.
Lee's rigs and his workshop have been discussed on this blog before:
http://soldersmoke.blogspot.com/2014/11/the-amazing-rigs-of-lee-snook-w1dn.html
http://soldersmoke.blogspot.com/2014/11/the-amazing-rigs-of-lee-snook-w1dn.html
Thursday, January 21, 2016
High-Pass Filter Knocks Down AM Broadcast Interference
WFAX 1220 AM was starting to bother me. Each morning, I'd be drinking my coffee, listening to nice roundtables on 160 meters, when, right at 6 AM, WFAX would fire up its 5 kW AM transmitter, 1.5 miles from my location. And they would crush the "front end" of my R2 phasing receiver. It doesn't take much to do that, since the only thing between the SBL-1 mixers in the R2 and the antenna is a signal splitter. Obviously I needed some filtering.
I turned to the free program called Elsie (L-C, get it?) and quickly whipped up a design for a seven element, capacitive input high-pass filter that promised to take about 45 db out of WFAX's sails, without attenuating even the lowest end of Top Band.
Last night I scrounged through the junk boxes and found suitable capacitors. A visit to an on-line toroid calculator showed that around 35 turns on a T-50-2 (red) iron powder core would yield the needed 6 uH coils. I built the filter this morning -- picture below.
It works very well. You can see the results in the picture above. The yellow trace on the 'scope shows the signal at the antenna terminal. Yikes, it shows around 4 volts rms at 1.220 MHz (the scale is 5 volts/div). The blue trace below is on the same scale -- this is the signal coming out of the filter. Not enough to really measure on the 5 volts/division scale.
This was a very satisfying "quick and easy" build. I really like the sound of the R2, so much so that I'm not firing up the DX-100 as much as I had been. Instead I find myself just listening to the R2.
Labels:
160 meters,
Filters,
Interference,
Phasing Rigs
Wednesday, January 20, 2016
Another AM Broadcast Interference Story
Bill,Pete
Another great solder smoke podcast today. I especially liked the detail
of you using the S-meter to check on the local broadcast station, and
the better reception you had on 160 with a resonant antenna. Before I
retired I had spent over 25 years as a field service tech working on
neurological instrumentation. One of the test our instruments performed
was called an Electro-Myography. Part of this test involved a needle
electrode being inserted into a muscle. This was fed to an
instrumentation amplifier connected to a computer that processed the
output of the amplifier. The signal from the amplifier was also fed to
a speaker so you could also hear the response of the muscle fibers
activating as you flexed the muscle. One of my customers called and
said that quite often when he inserted the needle electrode, he heard
music instead.
I made a trip to his office and using a field strength meter, I could
see the modulation peaks on the FSM. But only in one location against
the wall in the exam room. I at first thought it might be from a
speaker cable for their intercom / background music system in the wall.
But there was no wires near that location , and it was an outside
wall. I went outside with the FSM and found that the signal was coming
from the down-spout for the rain gutter. Apparently the gutter was
resonant at the frequency of the local AM station and the received
signal was being radiated through the wall and picked up by the amplifier.
I quickly got the set of jumper cables out of my van and connected the
down-spout to a near by water faucet, the signal went away. After a
quick trip to the local Home-Despot and picking up some heavy copper
wire and a ground clamp for the water pipe I was able to fix this
problem. It is amazing how broadcast interference can show up in so
many places.
DuWayne
Another great solder smoke podcast today. I especially liked the detail
of you using the S-meter to check on the local broadcast station, and
the better reception you had on 160 with a resonant antenna. Before I
retired I had spent over 25 years as a field service tech working on
neurological instrumentation. One of the test our instruments performed
was called an Electro-Myography. Part of this test involved a needle
electrode being inserted into a muscle. This was fed to an
instrumentation amplifier connected to a computer that processed the
output of the amplifier. The signal from the amplifier was also fed to
a speaker so you could also hear the response of the muscle fibers
activating as you flexed the muscle. One of my customers called and
said that quite often when he inserted the needle electrode, he heard
music instead.
I made a trip to his office and using a field strength meter, I could
see the modulation peaks on the FSM. But only in one location against
the wall in the exam room. I at first thought it might be from a
speaker cable for their intercom / background music system in the wall.
But there was no wires near that location , and it was an outside
wall. I went outside with the FSM and found that the signal was coming
from the down-spout for the rain gutter. Apparently the gutter was
resonant at the frequency of the local AM station and the received
signal was being radiated through the wall and picked up by the amplifier.
I quickly got the set of jumper cables out of my van and connected the
down-spout to a near by water faucet, the signal went away. After a
quick trip to the local Home-Despot and picking up some heavy copper
wire and a ground clamp for the water pipe I was able to fix this
problem. It is amazing how broadcast interference can show up in so
many places.
DuWayne
Labels:
Interference
Tuesday, January 19, 2016
Arduino Problems -- Back from the Ledge
As I was struggling through this, someone -- who will remain nameless -- told me that because of all the technical problems resulting from the many Arduino IDE "upgrades," suicide prevention hotlines now answer all calls with an automated question: "If you are calling about an Arduino problem, press 1 for assistance."
It got pretty ugly but with the help of Tom up in NYC I managed to get through it. First he convinced me that it is indeed POSSIBLE to upload the latest version of the IDE -- the dreaded 1.6.7. I just had to REALLY get rid of earlier versions. This got me past the horrible Bundled Java Runtime Environment problem (who thinks up these names?).
We then worked with the libraries needed to upload the AD9850 code of Richard AD7C. You see, I work on Arduino stuff. Then I stop. 18 months pass. I forget all I learned. Then I start over. The pain begins again. In an effort to break this cycle, I am now taking notes (in the inside cover of Mario Banzi's book).
I am using the AD9850 with a Kanga Arduino shield designed by Paul M0XPD. It takes the AD9850 output, divides by 4 and puts it out as 2 square waves in quadrature. I use this with my R2 phasing receiver. The problem was that the display on the Arduino showed a freq 4 times the actual tuning freq. Believe me, this gets old fast. I considered just getting a San Jian freq counter and supergluing it on the top of the DDS box. I was going to connect this to the square wave output. That would have given me one readout with the actual receive freq, and another (on the Arduino) showing the (4X) freq coming out of the AD9850. But that would have been too much of a Kludge. Tom talked me out of it and modified the code so that the Arduino display shows the actual receive freq. Thanks Tom.
Armed with the new IDE and with my knowledge of Arduino basics refreshed, I was able to reload the LA3PNA Si5351 code into my 40 meter DIGI-TIA. But not before having to swap out the Arduino that drives the Si5351. One Arduino happily accepted the code, another did not. Why? Who knows? It is a digital mystery. Those little 1s and 0s are fickle you know.
The Radio Gods rewarded me for all this. At about 5:45 AM today I was listening to a very friendly SSB roundtable on 160. The guys were getting ready to sign off. The last one ended the conversation by asking the others to "Be kind. Smile at your neighbors." Nice.
Then WFAX AM started the broadcast day at 6 am, wiping out my 160 meter reception. Next project: High-Pass filter at 1.7 MHz.
It got pretty ugly but with the help of Tom up in NYC I managed to get through it. First he convinced me that it is indeed POSSIBLE to upload the latest version of the IDE -- the dreaded 1.6.7. I just had to REALLY get rid of earlier versions. This got me past the horrible Bundled Java Runtime Environment problem (who thinks up these names?).
We then worked with the libraries needed to upload the AD9850 code of Richard AD7C. You see, I work on Arduino stuff. Then I stop. 18 months pass. I forget all I learned. Then I start over. The pain begins again. In an effort to break this cycle, I am now taking notes (in the inside cover of Mario Banzi's book).
I am using the AD9850 with a Kanga Arduino shield designed by Paul M0XPD. It takes the AD9850 output, divides by 4 and puts it out as 2 square waves in quadrature. I use this with my R2 phasing receiver. The problem was that the display on the Arduino showed a freq 4 times the actual tuning freq. Believe me, this gets old fast. I considered just getting a San Jian freq counter and supergluing it on the top of the DDS box. I was going to connect this to the square wave output. That would have given me one readout with the actual receive freq, and another (on the Arduino) showing the (4X) freq coming out of the AD9850. But that would have been too much of a Kludge. Tom talked me out of it and modified the code so that the Arduino display shows the actual receive freq. Thanks Tom.
Armed with the new IDE and with my knowledge of Arduino basics refreshed, I was able to reload the LA3PNA Si5351 code into my 40 meter DIGI-TIA. But not before having to swap out the Arduino that drives the Si5351. One Arduino happily accepted the code, another did not. Why? Who knows? It is a digital mystery. Those little 1s and 0s are fickle you know.
The Radio Gods rewarded me for all this. At about 5:45 AM today I was listening to a very friendly SSB roundtable on 160. The guys were getting ready to sign off. The last one ended the conversation by asking the others to "Be kind. Smile at your neighbors." Nice.
Then WFAX AM started the broadcast day at 6 am, wiping out my 160 meter reception. Next project: High-Pass filter at 1.7 MHz.
Labels:
160 meters,
Arduino,
DDS,
Phasing Rigs
Sunday, January 17, 2016
ArduinWoes
Sometimes I really hate those little boards. Well, not so much the board as the IDE. But now that I've built at least two rigs with the little beasts in them (Of course, I blame Pete), I have the need to occasionally update or re-load software.
I tried to do just that today. Downloaded the 1.6.7 version of the IDE. All kinds of weird difficulties. The real show stopper is a message that pops up an announced that the IDE comes bundled with Java Runtime, but the bundle is missing or corrupted. No suggestion re what to do...
A visit to the Arduino blog brings no relief. There ARE lots of messages from others suffering from this problem. And acknowledgements from Arduino people that the problem exists. But no solutions. Any suggestions? Or should I just retro-fit LC VFOs or VXOs?
I seem to go through some version of this every time I try to use an Arduino.
73 Bill
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