Just go to http://soldersmoke.com. On that archive page, just click on the blue hyperlinks and your audio player should play that episode.
http://soldersmoke.com
I was listening to Glenn Hauser's excellent shortwave listening show on WRMI this week, and he mentioned a technique that I had not been aware of: listening for the harmonics of distant stations. This is apparently being done for medium wave broadcast stations, but also for stations in the lower frequency range of the shortwave bands. If propagation makes it highly unlikely for you to hear the main frequency, perhaps propagation would be better for the the second or third harmonic. This method is discussed here:
You have long been one of the leading gurus on DSB. I remember absorbing all the info I could from your website when I was getting started in DSB back in 2001.
It's great that you found the article about DSB with inverted audio. It would be very cool to build a transmitter with the inverted audio, then confirm that it could be received with a direct conversion receiver without distortion.
The incompatibility of DSB TXs and DC RXs seems like a very cruel trick of nature. There are only a few people in the world who think about this, and most of them are in the comments section of your YouTube video! An elite group indeed.
Back in 2015 your review of a DSB rig got me thinking about this incompatibility: https://soldersmoke.blogspot.com/2015/07/peter-parker-reviews-dsb-kit-and.html
It is easy to see how a slight frequency difference between TX VFO and RX VFO would cause a lot of distortion, but similar distortion would be caused by a phase difference between the two VFOs. AM SW Broadcast receivers try to minimize the effects of fading by using an internal oscillator to replace the wavering carrier -- but they have to have it exactly on frequency and locked in phase with the distant station's carrier. I have a little Sony portable that has this "synchronous detection" circuitry. It is a complicated task and I don't think you could do it with the highly suppressed carriers of our rigs. Inverted sidebands to the rescue!
Thanks for the great video and all the tribal knowledge.
The HA-600A that I picked up last week was looking kind of sorry. There was a lot of rust on the cabinet. Below is the before picture.
I'm not really into cabinetry or radio aesthetics, but it is amazing what a 6 dollar can of spray paint can do. Formula 409 also helps. I moved the light bulbs forward a bit to get more light on that Juliano Blue dial.
I am really enjoying this radio. It has brought back many memories. I think I got one for Christmas in 1972. I was 14. I got my Novice ticket on April 27, 1973 and made my first contact on July 19, 1973. For that first contact I was using an HA-600A and a Heathkit DX-40. Later I used the Lafayette with a Heathkit DX-100. The HA-600A was replaced by the far superior Drake 2B on April 11, 1974. So I used this receiver for more than two years.
Looking around inside this receiver (and following up with Google) I learned some more about it:
-- It was made in Japan.
-- The manual says it has a "mechanical filter" but in fact it has a Toyo ceramic filter. This may have been just an honest mistake by the folks who wrote the manual -- maybe they didn't understand the difference between the two types of filters.
-- There is a big difference between the HA-600 and the HA-600A, mostly in the front end circuitry. The HA-600 has fewer amplifier circuits at the front end. This probably explains why the HA-600 I picked up did not seem to live up to my memories of my teen-year HA-600A.
The fellow who gave it to me tells me that it had belonged to the short-wave listener father of a friend of his.
I know we have a lot of tube-type receivers that are much older than this thing, but I still think it is pretty amazing that this is a receiver that I used almost half a century ago. And it is still as good as new.
So on September 27,2020, I was sitting quietly in my shack, perusing the postings on various radio-related Facebook groups, when suddenly I saw it: my very first shortwave receiver, the magic box that had put me firmly on the path to amateur radio, the Lafayette HA-600A. Joe, the owner, was offering it FREE to anyone willing to pick it up at his home in Virginia's Shenandoah Valley. Holy Cow! I was scheduled to drive through that very valley later that week. A message was sent and the deal was done. CLEARLY THE RADIO GODS HAD SPOKEN (TRGHS).
Sure, the cabinet looked a bit rough, but I had high hopes for this receiver. A while back I had -- in a similar fit of nostalgia -- bought what had been advertised as a Lafayette HA-600A on e-bay. But it turned out to be a Lafayette HA-600 (no A). I immediately noticed a big difference in performance. That was NOT the radio that I remembered, not the receiver that had carried HCJB and Radio Moscow to me. Joe was clearly offering the A model.
A few days later I was in Joe's front yard for the hand-off, and a few days after that the HA-600A was on my bench.
I quickly realized how little I knew about this receiver. Mine was a Christmas gift, probably in 1973. (A few days ago I talked to my mom and thanked her for driving all the way to New Jersey to get this receiver for me.) I was so taken with this thing that I feared doing something -- anything -- that might mess it up. I lived in fear, for example, that some sort of freak mid-winter lightning bolt might destroy it. I covered it with a towel each night lest dust encumber its "jeweled movements." Obviously I was just not inclined to crack open the case and have a look around. So I didn't, and the receiver remained pretty much an appliance for all the time I owned it. (I eventually sold it on consignment at Electronics 59 in Spring Valley, New York. The proceeds probably went toward the purchase of a much better Drake 2-B receiver.)
I downloaded the manual and familiarized myself with the receiver: It is a single conversion superhet with a 455 kc IF. It is all solid state with no ICs -- all discrete transistors and diodes. The manual claims it has a mechanical filter. I kind of hoped for something like a Kokusai mechanical filter, but it turns out that the filter was really ceramic, not mechanical. Bummer.
The thing fired up right away and was inhaling on the correct frequencies. I noticed immediately that (as Joe had indicated) some of the controls were scratchy. I also noticed that the ganged band selection switch was intermittent and required some jiggling to get it to work properly. A few squirts of Deoxit D5 took care of all that. There seemed to be a bit of dirt in the main tuning capacitor, but I think I managed to blow that out using a can of Dust-off. I was quickly listening to the SW broadcast stations, and to radio amateurs on 75 and 40 meters.
Out of curiosity, I compared schematics of the HA-600 and the HA-600A. There was indeed a big difference -- the front end of the 600 lacks a lot of the RFA amplification circuitry of the A model. That's probably why is seemed so deaf and so different from what I remembered of the A model.
There is really not a lot to do on this receiver. I'll get some paint to fix up the top cover. I may check the alignment. But this single conversion receiver is so simple that alignment would be quite easy. In many ways this receiver seems like a solid state analog to the Hammarlund HQ-100, but without the clock, and without the regeneration circuitry. The dial lacks the exotic station locations (Java!) that make many of the older receivers so much fun. I guess this is an indication that this receiver was aimed more at amateur radio operators than at shortwave listeners ( I was both). I wonder how the ham band-only HA-800 compares to the HA-600A?
I could pair this receiver up with a DX-40 transmitter that I have on the shelf and I'd be most of the way toward re-creating my novice station. Anyone have a Globe VFO Deluxe? That would complete the setup.
Thanks very much to shortwave listener Joe Pechie for providing what is, for me, a very meaningful piece of gear.
I'm more of a single conversion guy myself, but in working with the DX-390 I came to appreciate the benefits (especially regarding image rejection) of the double conversion technique. While working on the DX-390, I discovered that the BFO control on the front panel DOES NOT change the BFO frequency. It was fun to try to figure out why the designers did it this way. It does make sense once you consider the limitation imposed by that PLL main tuning oscillator that only moves in 1 kHz steps. I hope the video explains things. Here is the drawing I used in the video:
And here is a drawing that shows how a single conversion superhet with a fixed or switchable (usually crystal-controlled) BFO works:
Earlier this month I did a blog post on my repair of a broken DX-390:
I've had this Radio Shack DX-390 portable receiver since the early 1990s. I bought it when I was in the Dominican Republic. It accompanied me on some interesting trips to the Haitian border, and on one very memorable 1994 trip to the Haitian capital. I have made some CW contacts with it serving at the inhaler.
Click on the diagram for a better view. It is a dual conversion superhet. First IF is at 55.845 MHz. There is a big 90's era IC-based PLL oscillator that runs from 55.995 to 118.7 MHz -- The main tuning dial moves this oscillator. Second IF is at 450 kHz. There is an oscillator at 55.395 that takes the signal down to 450 kHz. Selectivity (not a lot) is provided by ceramic filters. Finally there is a product detector and a 450 kHz oscillator that produces the audio. While there are many mystery chips in this receiver, there is also a lot of discrete-component analog circuitry in there -- it is kind of a pleasing mix.
DX-390 Main Board. Note kludged toroidal replacment for L10 (just above ferrite antenna)
The old DX-390 suffered a lot of wear and tear. The case is very beat up. The most serious problem was that at some point, probably on a cold, dry, winter day in Virginia, static electricity took out the FET in the receiver's front end. I made a half-hearted effort to fix it, but it never really worked properly. I occasionally found myself thinking of this receiver. I spotted one on e-bay not long ago, and bought it. This newer one was in very nice shape. But that old one was kind of staring at me from the corner of the shack. "C'mon radio man," it seemed to say, "can't you fix a shortwave receiver?" So this week I took up the challenge. First the FET. I had kludged an MPF102 in there, but that didn't seem to work well. Internet fora seemed to think that a J310 would do better, so I installed one of them -- it did seem to work better. (Note: Pete Juliano likes J310s -- TRGHS.)
Kludged in J310. And two sets of back to back diodes
During my earlier repair effort I had apparently destroyed the front end output transformer (L10) but I discovered that I had replaced this with a toroidal transformer. It still worked, so I left well-enough alone. I was pleased that the old receiver was receiving OK, but there was a problem: The "BFO" control wasn't working. The BFO would come on, but turning the BFO control did not vary its frequency. At this point I discovered that while there are many copies of the DX-390 service manual and schematic on the internet, all of them have seriously degraded copy quality right around the parts of the circuitry that I needed to study. Sometimes Murphy overpowers the Radio Gods. It took me a while to get a useful schematic of the BFO control mechanism. BFO is a bit of a misnomer here: the control actually shifts the frequency of the 55.395 MHz oscillator that drives the second mixer. See Block diagram above). There is a varactor diode in the base circuit of a BLT oscillator circuit. Turning the BFO control varies the voltage going to the varactor thus causing the oscillator frequency to slide up and down. But mine wasn't moving. And that was a problem. So I dove right in, trying to figure out why it was oscillating, but not shifting in frequency. At this point I discovered that I too am afflicted with the disease that Pete Juliano suffers from: Fat Finger Syndrome. That BFO control circuit has a nice big 100k pot, but all the fixed resistors and caps were surface mount and SMALL. As I poked around trying to troubleshoot, I managed to make things worse. It turned out that the lead carrying 6 volts to the BFO control circuitry had broken. But before I discovered this, I managed to do all kinds of damage to the board. I lifted two PC board pads (I should have turned down the temperature on my soldering iron). Then, when I tried to fix this, I managed to put a solder bridge across two parts of the circuit that definitely should not have been connected. This resulted in a bizarre BFO situation. From the center position, turning the BFO to the left OR TO THE RIGHT would move the BFO in the same direction. So I could tune in an SSB station by turning to the right, or by turning to the left. That was just not right.
Lifted solder pads. And small wires that now bridge the gaps
Uffff. It took me a while to find that fault. While trying to figure this out, I built the circuit in LTSpice just to see what it was SUPPOSED to be doing. This helped. Eventually, through careful inspection with magnifying goggles, I found a solder blob, and removed it. Now all was right with the universe. Even though I had caused most of the trouble, it was still quite satisfying to fix it. Some additional observations on the DX-390. -- It really is a Sangean ATS-818 in disguise. Just look at the marking on the PLL board. If you can't find a decent DX-390 schematic, just use an ATS-818 schematic.
ATS 818 marking along the bottom (green) part of the PLL board
-- The service manuals on these receivers are quite good: the include bloc diagrams, detailed alignment instructions, and even voltage charts for all the chips and transistors. Impressive and useful. -- The static discharge vulnerability is hard to understand. There is so much cool circuitry in these receivers, why not add four simple diodes? Not wanting to repeat this saga, I went in and put two sets of back-to-back small signal diodes in each receiver: one set on the telescoping antenna, and other at the input for the external antenna. Curiously, on the newer receiver, it looks like a previous owner had gone in and tried to address this vulnerability -- but he did a very incomplete job. He just put ONE diode between the external antenna input and ground. I had always thought that two diodes back to back would give you good protection from static discharge. And I don't think that single diode protects the front end in any way from discharge coming in from the telescoping antenna.
This was a good project. I got more familiar with general coverage dual-conversion receivers. And I got reacquainted with an old receiver that I liked a lot. Both receivers could probably use some alignment. I'll take that up next.
A while back I posted a picture (see below) of the shortwave dial of an old receiver used by my wife's grandfather. I noted the odd presence of 'Schenectady" among the exotic foreign locations on the dial. Pete immediately connected the dots by noting that Schenectady was the home of General Electric. This week Chris Waldrup KD4PBJ sent us a great web site describing the shortwave stations in Schenectady. Check out the tube that runs 100 kw AM (Big Bertha). https://www.radioworld.com/news-and-business/schenectady-shortwave-transmitters-1941 Chris also sent information about BIG AM broadcast band stations: In addition to Schenectady being home to GE it is the city of license to clear channel AM 50 kW WGY 810. WGY was started by GE so if the radio was GE it was probably a way to promote their station at the time. I heard mention of Rochester too and that would be for 1180 WHAM another 50 kW clear. Both WGY and WHAM are still there going strong banging out their 50 kW. And Pete reminded us of KDKA, describing its long-lasting impact on one of his ears:
Let us not forget KDKA in Pittsburgh at 1020 which I think is no longer clear channel. I used to listen to KDKA on my crystal set when I went to bed at night. My bed had an exposed bed-spring which was my antenna. To this day there is a slight kink in one of my ears where my Brush headphones rested –I am a side sleeper.
Thanks for upping the frequency of your podcasts. Each one is a welcome note to break-up the COVID monotony.
Following on to Bill’s 31m rx, I am pleased to have a new regen on the air and performing well. This started as the 12AU7 Hartley circuit found on the web; however, the original circuit needed some further work IMO. I made a number of modifications – outboard 30 MHz LPF (to remove our local Spanish FM station), inductive antenna link, variable cap for antenna coupling adjustment, up to 24V on the plate, extra by-passing, NE5532 audio section vs LM386 and a switched cap for a lower “band”. It’s still a starved triode oscillator/audio amp and it has that regen presence. Best DX is Singapore (BBC) and Madagascar although it’s ideal for easy listening on 19-60m to Romania, Greece, Cuban music, Spain, etc. As Bill said, there is still plenty worth listening to on a homebrew AM rx. 40, 30 and 20m copy OK, but bandspread is tricky! Adjusting regen is good for +/- 1 kHz, kind of a poor man’s BFO adjustment. I heard a TI station calling CQ on 20m and called him back on my Icom for a QSO.
By the way, this rx has some serious vintage mojo – Hammarlund varicap, National coil form, Millen dial and an RCA tube. The all-star team plays great together! It’s a kick seeing the filament glow while putting RF through recycled parts made decades ago.
One of the great things about having a "miscellaneous" box in an otherwise well-ordered junk collection is that rummaging through that box will often send you off on fun and interesting radio adventures. I was rummaging yesterday and I came across the guts of the little AM radio that used to be mounted on my bicycle handle bars. I last mentioned this in 2011 :
I was just about to cannibalize this board. The IF transformers were almost certainly at 455 kc and I could use a few of those. But then I started thinking and Googling and trying to figure out the circuit. That all led me this the site that provided the diagram below:
Six transistors, four transformer cans, two audio transformers. Yea, that's pretty close to what I was seeing on my board. So of course I had to see if I could get it going. I hooked up a 9V battery. I connected the pot wiper connection directly to the connection at the top of where the pot had been (it had disintegrated). It works! It is inhaling nearby WFAX, Falls Church, Virginia.
You will notice that the transistors in the circuit above are PNP. I had assumed negative ground and had hooked the battery up accordingly. No smoke was released and the thing worked, so I guessed that I had assumed NPN correctly. Sure enough, perhaps aware of the PNP ancestry, the manufacturer had marked my board "BC123 NPN"!
The author of the book I linked to above dubbed this circuit the "All Japanese 6" -- an obvious allusion to the All American 5.
I see real potential in these AJ6s. A few mods to the front end and you could be shortwave listening, perhaps on 31 meters!
BTW: The space on my handlebars formerly occupied by that little AM radio is now taken up by a Bluetooth speaker that plays tunes streamed to my I-phone from Pandora as I make my way down the same old Washington and Old Dominion bike path. Progress.
The picture above shows my problem. As predicted by the Murata data sheet and as warned by R.A. Penfold, that nice 455 kc ceramic filter has a significant response at around 640 kc. This caused me to hear Brother Stair twice as often as I should have. Clearly a spur exorcism was called for.
Click on the picture for a better image. As noted last time, my first idea was to build a series 640 kc trap LC circuit and put it ahead of the ceramic filter. But I had trouble getting the desired high Q. So I then thought about putting a wider 455 kc filter ahead of my 12 kc filter. I would, of course, need one that did NOT have the 640 kc spur. I found a 455B filter in my junk box. I used the NanoVNA to look at its response. No spur at 640 kc! Yea!
Next I put the two filters together, 455B first, then the 12 kc filter. Success! You can see on the NanoVNA that there is no spur at 640 kc.
With close to the desired termination impedances, the passband at 455 kc looked pretty good. I just put 1500 ohm resistors in series at the input and output of the dual filter combo.
It worked. Spur exorcised! I no longer hear each SW broadcast stations at two spots on my dial.
Paul Taylor VK3HN's magnificent AM receiver was the inspiration for my Quarantine-31 Shortwave Broadcast receiver. Like Paul I decided to make use of ceramic filters at 455 kHz for selectivity. I started with the +/- 3 kHz filters that Paul used, but I found them kind of narrow for SW listening. So I went with some wider ceramic filters that Bruce KK0S had sent me. But I misread the specs that Bruce sent. I thought they were 10 kHz wide filters. I realized later that they were +/- 10 kHz -- really twice as wide as I needed. So I went back to Mini-Kits in Australia and got some +/- 6 kHz filters. 12 kc wide should be just about right, I thought.
The bandwidth was right, but I started noticing a problem: I could hear strong SW broadcast stations at two places on my dial. This brought to mind an admonition from R.A Penfold, author of "Short Wave Superhet Receiver Construction" (1991 Babani Publications). He advised keeping a few standard 455 kc IF cans in the circuit because, he warned, the ceramic filters have spurious responses, spurs that the IF cans can help knock down.
Penfold was right. Look at the filter response curve on the right (above). There is a nasty spur at around 640 kHz. This was the cause of my problem. Here is why:
Suppose I was tuning Radio Marti's big signal on 9805 kc. My VFO would be running at 9350 kc.
9805-9350=455. Great, but...
With that spur at 640 kc, I could tune down to 9620 kc on my dial. My VFO would be running at 9165 kc.
9805-9165=640. Bad. That 640 kc difference product would make it through to my detector and AF amp. I'd have Radio Marti showing up in two places. I didn't like this.
I thought about putting a series LC circuit tuned to 640 kc at the output of the ceramic filter. This looked like a possible solution, but on the bench it looked like I would have trouble getting a circuit of sufficiently high Q.
So rummaging around in my junk box I found an old Murata CFM455B filter. This filter is quite broad, but it does not have the spur at 640 kc. I could use it as a kind of roofing filter just ahead of the +/- 6 kHz filter. Putting it there would allow me to avoid having to build additional matching circuits for the 455B filter.
+/-6kc filter upper left, 455B wide filter to the lover right.
I'm happy to report that this fix works. The 6 kc filter provides the needed selectivity, and the broader 455B filter knocks down the 640 kc spur.
Warrenton Va. is not far from me (and is the birthplace of Cappucio the Wonder Dog). Once we are done with the pandemic I hope that Jerry and I can get together to talk about homebrew radio.
Like me, Jerry recently turned his attention to the shortwave broadcast bands. He too went the homebrew route, but his receiver is a regen. It is based on the Sproutie by Dave AA7EE.
Here is Jerry's article detailing the project and the results:
Jerry had been scheduled to talk about antenna tuners at FDIM this year, but the pandemic caused the event to be canceled. He shared with me a Limerick that he was going to include in the presentation. Obviously we have similar feelings about automatic antenna tuners.
No offense to the birthplace of Homer Simpson, but Springfield? And Schenectady? This dial glass is all that remains of a shortwave receiver used by my wife's grandfather in the Dominican Republic.
Many years ago the Boatanchor enthusiasts had a very informal "dial lights" competition. Which receiver cast the best glow from its dial lights. (I think my HQ-100 was the best.)
The dials of many old shortwave receivers have recently started to show up on the Shortwave Listening group on Facebook. Some have some very exotic foreign locations. Perhaps we should launch a similar competition: Which SW receiver dial has the most exotic foreign locations?
-- Copper Clad board: Pete’s boards use CEM 1. CEM 1 is low-cost, flame-retardant,
cellulose-paper-based laminate with only one layer of woven glass fabric.
-- Peter VK2EMU continues to build his amplifier. But it is NOT for 50 MHz. It does have 6 different meters on the front
panel. But it is not a 6 meter rig!
-- Rich K7SZ – “now look what you’ve done”Fixing up an S-38
-- Rich WD3CProvided
some great SWL links:
https://www.short-wave.info/ if you move the green dot to your location
it will predict what the signal strength would be at your location and will
also allow you to search by station, language, frequency, etc.
"SolderSmoke -- Global Adventures in Wireless Electronics" is now available as an e-book for Amazon's Kindle.
Here's the site:
http://www.amazon.com/dp/B004V9FIVW
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