Elecraft's auto-spot and CWT features -- available on the K3/K3S/KX2/KX3 -- are very useful tools for CW operators, especially those not experienced in pitch-matching. Here's a bit of history on where these features came from and how they work.
CW Spotting History
When a station finishes a CQ in CW mode, the operator faces the challenge of copying someone who's calling back. Callers may be weak or obscured by QRM; the op can usually deal with both problems by narrowing the filter passband. However, callers may also be off frequency. A calling station may be using a wide filter passband themselves, not attempting to carefully match their VFO frequency to that of the CQing station. The result may be no QSO, even when propagation is excellent.
In the Days of Yore, a frequency offset between stations didn't always matter. Sometimes both stations used crystal-controlled transmitters, so operators had to patient tune around after calling CQ.
As a 14-year-old novice I embraced this operating style for a year or so, armed with a dozen or so crusty FT-243 crystals for my Heath HW-16. I nearly wore out the socket swapping them in and out. After calling CQ, it was not unusual to find a caller 30 or more kHz away! (Away from "where" was a poorly answered question, as my Hallicrafters receiver dial wasn't exactly digital.)
Fortunately I soon acquired an outboard VFO, a life-changing addition to my station. Jealous friends doubled up on their paper routes to pay for their own. Girls suddenly paid more attention to me.
These days virtually everyone has a VFO, along with the expectation that they won't have to tune theirs very far, if at all, to tune you in. Not only that, they're stable and well calibrated, not like the beasts we had to skillfully tame. Progress!
Manual Spotting (SPOT switch)
Once I had a VFO I quickly learned to do *manual* pitch matching. Older rigs did't provide a way to do that explicitly, so you'd improvise. Basically, you had to coerce a very weak signal out of your own transmitter, say by turning on only the driver, then tune the transmit VFO until you could hear your signal on your own receiver -- superimposed on the calling station, at the same pitch. This is what we call spotting.
Of course spotting is a lot more convenient these days, as many rigs include a SPOT switch. This function is easy for a modern transceiver designer to add, because the radio's firmware is quite capable of turning on only the CW sidetone without transmitting.
That is the purpose of the SPOT switch on all Elecraft transceivers. Tap SPOT, and you'll hear your sidetone pitch. Most people can do a good job of adjusting the VFO such that the CQing station's pitch matches that of the SPOT tone. This ensures that when you call them, you'll be close to their own frequency.
Tuning Aids: Filtering (APF), PLL (NE567), and Spectral (CWT)
Since not everyone has an inherent musical ear, various hardware-enhanced means of tuning in CW signals have been developed.
The simplest method is to just narrow your receiver passband so much that, if you can hear a station calling CQ at all, you're guaranteed to be "right on top of him." This assumes that your transceiver enforces alignment between its transmit and receive pitch...true of all Elecraft gear.
Narrow filtering has gone through decades of evolution. Some filters were based on op-amps (active filters), while others were based on LC filtering, conscripting humongous toroidal cores scavenged from telco equipment. I acquired my stash of these from a haphazard mound of old switching racks, decaying in an abandoned aircraft hanger on the Bermuda U.S. Navy base. (That irresistible junk pile was also a mother load of TO5 transistors, multi-pound electrolytic capacitors, and tetanus, but that's another story.) Typically the toroids were 88 millihenries -- a huge value for a high-Q inductor, permitting resonance in the low audio range.
Later, such filters migrated to digital signal processing, in the form of switched-capacitor ICs or DSPs. You can still buy these switched-capacitor chips, like the MF10, from various sources. It's instructive to roll your own tunable filter, just for fun.
Whether passive or active, the goal of filtering is typically to achieve a narrow passband, say 250 Hz or less. With DSP, nearly perfect filters with "brick wall" passbands can be created. But these have the disadvantage of ringing like a bell when pinged by a CW signal or noise, making copy difficult.
One solution incorporated into the K-line and KX-line is the Audio Peaking Filter (APF), which provides a 30-Hz bandwidth at -3 dB, but broad skirts, preventing ringing from occurring. As our customers will attest, APF works like magic on weak signals obscured by noise.
Another forerunner to DSP techniques was the audio phase-locked-loop, using inexpensive ICs like the legendary LM567. When locked on a signal that matched its center frequency, the circuit would turn on an LED, alerting the operator that the VFO was now properly tuned.
With the DSPs in our K-line and KX-line radios, we can provide a much more powerful tool: CWT, or "CW Tuning Aid." When enabled, CWT turns the upper portion of the rig's S-meter into something of a mini spectrum analyzer. The pitch of the strongest signal in the passband is analyzed by the DSP, then represented as a single segment of the bar graph. For CWT-enhanced manual spotting, the operator simply tunes the VFO slowly until the center CWT segment is flashing along with the keyed signal.
Manual tuning with CWT can also be used in FSK-D and PSK-D modes as described in the owner's manual.
Closing the Loop: Auto-Spotting (SPOT + CWT)
The Elecraft K3/K3S/KX2/KX3 take CW tuning another step forward by providing a way to *automatically* retune the VFO frequency to match that of a received signal. How does this work?
When CWT is turned on, firmware treats the SPOT switch as AUTO-SPOT. The DSP analyzes the incoming signal, and with a bit of processing, determines its exact audio pitch. From there all that's needed is a bit of math to offset the VFO to match this pitch to the CW sidetone.
There's another subtlety, though. Since a CW signal is generally being keyed on and off, the CWT algorithm has to ensure that it doesn't "take off," chasing a signal that's not there. To avoid this, we keep track of the energy in the passband, and slew the VFO incrementally over an average of about 0.5 second, moving only when the target signal is present.
How to Use Auto-Spot
I encourage you to give the auto-spot feature a try. It's best to start with a fairly narrow passband, say 400-600 Hz; narrower if there's a lot of QRM. Find a signal, turn on CWT, then tap SPOT to tune it in. A second tap of SPOT may get even closer, especially if there's a lot of band noise.
Auto-spot can also be used in Elecraft's PSK-D mode, i.e. for PSK31/PSK63. As with CW mode, just turn on CWT, tune in a prospective signal, and tap SPOT. Since PSK auto-decoding requires very accurate tuning, it's best to set the filter bandwidth to 50 Hz, then let auto-spot dial things in down to the last 2 or 3 Hz. If you have text decode turned on, you should start seeing text characters scroll by after auto-tuning has completed. Tapping a second time or fine-tuning the VFO a bit in 1 Hz steps may improve copy.
24 comments
Wayne as always insightful.
One of those things I missed in the documentation. Well I made at least 50 contacts before opening the manual for the first time for the KX2. A testament to the straight forward design. One of my all-time favorite rigs!
I got a kick out of your remembering those Novice days. Luckily in 1963 I had my Dad’s old 40 M xtal controlled mobile converter from the ’50s with a crystal swap and retune the output below the broadcast band to my BC-453. 40 M (7.000 to 7.300) was from 200 KC to 500 KC on the BC453, CHU on 7.335 for frequency and time checks. A double tuned pre-selector would have helped for image rejection, but at least it was rock stable and with the 85 KC IF only about 2-3 KC wide. An audio filter, yes a WWII salvaged LC one, helped when needed.
I still remember my xtal frequencies: 7156, 7160, 7173 and 7184. Wish I still had them. My AT-1 was awful (unstable then, but now fixed) but my Globe Chief Deluxe would put out nearly 90 W with a pair of JAN 807s when I got my General. Yes, we tuned 50 KC for a reply, but I placed 3rd in my very first contest running only on 40 M. Those were the days at age 13.
I found that in order for the spot function to work, you need to be in the finest frequency resolution mode, i.e.tuning in 1Hz increments.
Sounds great, esp since I’m getting back into ca after 59 years!
Prob is your equipment is very expensive.
Any recommendations?
Can u send me a catalog?
Tom Pallan
Wb2jsy
130 Parkwood Rd.
West Islip, ny
11795
Ty
Nice article. I am lucky enough to have “perfect pitch” so just have tuned around by ear until the incoming pitch of the other station matches my selected CW sidetone pitch that I’m transmitting at. On my KX3 radio, I chose 440 Hz because that’s a nice clean “A” to my ears. The other pitches sound slightly off, because they are in 10 Hz increments. I would love to be able to use a higher pitch, also. Can’t use the “A” an octave higher, because 880 Hz isn’t allowed, the setting only goes up to 500 Hz. As I get older, my hearing is best in the midrange, I’m starting to lose clarity both in the treble and in the bass, so getting above 500 Hz would be better for me. Any thoughts on allowing more flexibility of adjusting the CW sidetone pitch? Ideally, being able to adjust in 1 Hz increments, up to 1000 Hz or so, would be ideal. Or just quantize it to a musical scale, if this is too many increments to dial around. Josh K6JSH
Nice article. I am lucky enough to have “perfect pitch” so just have tuned around by ear until the incoming pitch of the other station matches my selected CW sidetone pitch that I’m transmitting at. On my KX3 radio, I chose 440 Hz because that’s a nice clean “A” to my ears. The other pitches sound slightly off, because they are in 10 Hz increments. I would love to be able to use a higher pitch, also. Can’t use the “A” an octave higher, because 880 Hz isn’t allowed, the setting only goes up to 500 Hz. As I get older, my hearing is best in the midrange, I’m starting to lose clarity both in the treble and in the bass, so getting above 500 Hz would be better for me. Any thoughts on allowing more flexibility of adjusting the CW sidetone pitch? Ideally, being able to adjust in 1 Hz increments, up to 1000 Hz or so, would be ideal. Or just quantize it to a musical scale, if this is too many increments to dial around. Josh K6JSH