Homebrew Weather Prediction?

I enjoy having a weather station at home. It is hooked up to APRS, weatherunderground.com, and I even have a weather webpage. One of the standard exchanges of information in most general QSOs is the weather: temperature, rain, …. I also like telling the folks in Florida that my humidity is 40% (I am not a fan of humidity having expierenced Fort Benning, GA in the summertime and monsoon season in Korea, not to mention my unairconditioned room at The Citadel (although I hear they have air conditioning now!)). It is easy to look at my desktop display and get all the data I need. I have heard of some folks who have a way to pull their weather data directly from their weather stations and input it into their PSK QSOs. Pretty slick, but I have never figured out how to do that (… yet).

All that being said, I do not get into weather prediction that much. If I see the barometer dropping, I may check the locak National Weather Service radar to see if anything is moving in (weather here moves from west to east). But if I wanted to get into weather prediction, this would make an interesting homebrew project: The Tempest Prognosticator.

Developed in the 1850s by Dr. George Merryweather, this device used leeches that would ring a bell if a storm was approaching. The device was even featured in Britian’s Great Exhibition of 1851. Despite the publicity, Dr. Merryweather was never able to get the government interested in putting the device into use.

I am sure there would be a way to interface the slugs with some kinda of Arduino device that would send out weather predicitions via APRS data. 🙂

a brasspounder’s cafe

Check out the wonderful blog of JJ8KGZ. Leo is in the process of assembling an Elecraft KX1 and has also started to share the joy of kit building with his son. Although I am sure there are many non-Western hamblogs out there, this is probably one of the first I’ve really explored and quite enjoy. I’ll be looking forward to Leo’s next post.

Invention Lab: RadioShack


What stuff have you done?

The tag line from a RadioShack contest and website called The Invention Lab. And they are partnered with MAKE! How cool is that?

There’s also a blog and different sections talking about various projects.

I think it’s great that RadioShack is trying to inspire the builder. RadioShack has had a pretty bad reputation over the past few years with most hams looking down there nose at the businesses drift into cell phones instead of their previous focus on radios and component parts. I believe the biggest difference between the RadioShack of yore and today’s ‘Shack is the sales people. Back in the day, the man behind the desk knew electronics inside and out. He also knew where every diode and every transistor was in the store. Today’s sales clerk does not know any of the electronic components the store carries, much less where to find them in the actual store. But this shift in the dumbing down of sales clerks is true across all lines of business. Have you been to Fry’s Electronics lately? The sales clerk at Sears in the hardware department can’t even tell you anything about the Craftsman tools they carry. So I’m a support of RadioShack – if you look hard you can usually find one that’s close that carries what you need. After you hunt and peck around the store, you’ll know where everything is and will only need the clerk to ring you up.

Items of interest

Interesting post on W2LJ’s blog about his PDA. I have an assortment of PDAs:

– Palm Pilot Pro that I got an upgrade kit for to make it a Palm III (new chip along with IR sync capability)

– Palm IIIxe which I bought on eBay. It works well except that it eats up batteries even when it is turned off. I have used this PDA with my Kenwood TH-D7 to do mobile 2m packet and PocketAPRS.

– Palm m130. This was the first PDA I had that allowed you to use an SD card. I have used this to program my TinyTrack APRS device.

– Palm Tungsten 3 (or T3). First PDA with wireless connectivity, in this case Bluetooth. Also has a slot for an SD card. I used this PDA for mobile logging, mainly taking advantage of the voice recording function… I’d have a mobile QSO, pick up the Palm T3 and record a voice memo of the time, freq, callsign, and any other significant info. At a later point I used that to update my primary log.

– Some variant of an HP PDA that has WiFi and an SD card slot.

Also have an assortment of keyboards, cameras, and other doo-dads that go with these.

I have the Palm T3 with me now… I’m guessing it needs to be charged.

K3OQ has a post about his upcoming trip to the Outer Banks. He also plans to activate The Bodie Island Lighthouse (USA-067). I had the opportunity to activate that light back in June of 2006. Beautiful area out there – very relaxing. One of the highlights of any hams visit to the Outer Banks is using the Outer Banks Repeater Association’s 2m and 70cm repeaters. I had a few great exchanges with Jack, W2EHD who lives in the area year around. The repeater system also allowed me to stay in contact with the XYL while I was off activating lighthouses.

N9IK’s Radio Blog has a new post about his completion of the Rock-Mite 40 transceiver kit. He’s got some great pics of his work. I hope to develop my building skills to that level. Very nice work. I look forward to hearing about the contacts he makes with it.

K9ZW tries to solve the age old question of the best way to organize QSL cards with his latest post. I’m curious to see how others keep their cards organized. I don’t have a ton of cards yet, but I would like a solid method of keeping my cards organized that will last for years and allow me to access them as needed.

As always – I enjoy reading your blogs. It keeps my interest in amateur radio strong even if I don’t get on the air as often as I’d like.

The Evolution of the Elecraft KX1 Transceiver

ANYWHERE, ANYTIME HF: The Evolution of the Elecraft KX1 Transceiver

By Wayne Burdick, N6KR
Special to the ARS Sojourner

If there is a place, and you can get to it, you must operate from there.
—Ade Weiss, WØRSP, Joy of QRP
Some years ago at the Dayton Hamvention I did a presentation entitled Ergonomics and Amateur Radio. It was not lost on either me or the audience that the title was an oxymoron. I spent an hour suggesting ways to improve the situation.

While discussing field operation, I alluded to something called a “trail friendly radio” (TFR), and speculated on what form it might take. Ergonomically, it’s an interesting assignment. Suppose you have no table? No chair? No room to string up a dipole? Suppose like Ade Weiss, you wanted to operate from anywhere?

Though the need for a trail-friendly radio has been evident for years, we can thank Richard Fisher, KI6SN, for giving the genre a name. He and Russ Carpenter, AA7QU, popularized it here on the ARS web site in the form of the TFR Challenge, and many interesting designs have resulted. Cam Hartford, N6GA, and I talked about it at length at the Zuni Loop field day site one year, when Cam showed me his own beautifully-designed TFR.

I’ve always wanted to explore TFRs myself, with the goal of optimizing them for small size, ease of use and maximum integration. But the idea had to simmer and morph in my mind for about a decade before all pieces of the puzzle came together – in my case, as the KX1.

Early Attempts

The story of the KX1 really begins in the 1970s. Like many hams who grew up in the era when transistors and ICs had just become affordable, I had the great fortune to acquire a copy of Solid State Design for the Radio Amateur by Wes Hayward, W7ZOI, and Doug DeMaw, W1FB (silent key, 1997). Armed with a Radio Shack etch-resist pen and ferric chloride, I home-rolled Wes’s Mountaineer, a crystal-controlled, direct-conversion, 40-meter transceiver. From then on I was hooked on both homebrew and QRP.

But it was the small, grainy photo of Wes operating the Mountaineer with gloved hands and wool cap – while while standing – that fired my imagination. Wes listed the many difficult constraints he had to satisfy in this design. The rig had to be small and lightweight to be suitable for backpacking, which dictated the use of QRP and a small battery pack. The antenna system had to be similarly light, so he opted for a simple dipole and RG-174 miniature coax cable. It had to be usable in cold temperatures, which suggested crystal control. Finally, it had to be usable in many different operating situations, including sitting on the ground, lying in a sleeping bag, or standing beside a trail. These constraints would inspire my own explorations in the TFR design space.

In 1989, I designed something I called the Safari-4 (QEX magazine, Oct. / Nov. / Dec. 1990). While not exactly a TFR, this 5 x 7 x 3″, 4-band, 1-watt transceiver did push the envelope on integration. It included an internal 0.8 amp-hour gel-cell, manual antenna tuner, SWR bridge, and keyer, and had a stack of four transverter boards covering 40, 20, 15, and 10 meters. Like the KX1, it had keyer paddle mounted on the front. Unfortunately it was actuated by skin resistance, and despite the gold-plated comb pattern on either paddle, it suffered when humidity was low. It also could not be used with gloves on.

Still, a rig like this had been my dream for many years. All you needed to set up a station was a random-length wire and a pair of headphones. I used the Safari-4 at every opportunity, and once managed to work Angola from Arizona on 15 meters with 200 milliwatts and a 16′ wire strung horizontally just 8′ off the ground. All of the credit goes to the operator in Africa, of course, and to extremely quiet band conditions.

I built my first truly back-packable, hand-held HF transceiver in 1991 while living in Massachusetts. It was 2 x 4 x 1″, operated on 15 meters only with a VXO and superhet receiver, and had a push-button CW key on the top. With two internal, paralleled 9-volt alkaline batteries, it eked out just one-half watt. This level was significant. According to Solid State Design, a half watt represented a good tradeoff between communications efficiency and battery weight. Taking this wisdom from my QRP heroes for granted, I took the little rig out on many occasions and made several interesting QSOs. The most memorable happened when I was operating mobile, driving north on I-495 outside of Boston one winter day. Using a three-foot-long whip on the roof – a Radio Shack CB antenna re-resonated at 21 MHz – I had a solid, 10-minute QSO with a station in St. Louis.

A PIC in the Pocket

Several years later, after designing a few PIC microcontroller projects at work, I decided to see what a PIC might do for the cause of further transceiver integration. The result was another hand-held, which I dubbed the Koala. This was a 2 x 4 x 1″, half-watt, 40-meter superhet that ran from a single 9-volt battery. The Koala had a keyer, dot and dash buttons on the top cover, frequency counter, battery voltage monitoring, and most significantly, audio-Morse-code frequency readout of all parameters including the VFO. This allowed operation with no display.

I should also briefly mention my club project phase, which led to the NorCal 40, Sierra, and SST transceiver kits. Again, these were not TFRs, but each furthered my goal of optimizing transceivers for portable use. All three were also enhanced by the addition of microcontrollers.

The NorCal 40 was the first NorCal club project. Doug Hendricks, KI6DS, Jim Cates, WA6GER, and others helped me specify the NC40’s features, which included small size, very low current drain, “wireless” construction, and the now-ubiquitous BNC antenna jack – I liked the small size, and I couldn’t find a PCB-mount SO239 anyway. I can’t thank Doug and Jim enough for their efforts, which made this rig and other NorCal projects a success.

The KC-1 keyer / counter option was added when another NorCal member, Bob Dyer, K6KK, started Wilderness Radio to sell the NorCal 40A commercially. The KC-1 used a PIC as a keyer and audio-Morse frequency readout – features now widely found in small transceivers. But I added one other unique firmware feature: the operator could use the keyer paddle to enter a target VFO frequency in kHz, then rotate the VFO knob until they heard an acknowledgement from the KC-1.

To minimize complexity while preserving low current drain, I used plug-in band modules in the Sierra, NorCal’s second transceiver project. Having tried a band switch in the Safari-4 and modules in the Sierra, I am now a firm believer in a third solution—latching relays—which I’ve used in every multi-band rig since, including the KX1. I later designed the KC-2 keyer / counter for the Sierra – yet another PIC-based unit. By running the KC-2’s MCU at just 100 kHz, and using a non-multiplexed LCD display, I was able to keep RFI to an absolute minimum. The Sierra construction article, sans KC-2, can be found in any ARRL Handbook from 1996 through 2003.

In the case of the SST, or Simple Superhet Transceiver, I tried to cut the size, parts count – 85 or so – and current drain to absolute minimums while preserving ease of construction and decent performance. The receiver still included AGC, the transmitter put out 2 to 3 watts, and there was room inside the box for a 9-volt battery and a KC-1. The combination of these features has made the SST popular as a Spartan Sprint rig. I suppose it could even qualify as a sorta-TFR if the KC-1 controls and dot / dash buttons were installed on top.

The NC40A, Sierra, and SST are all still available from Wilderness Radio.

Five Field Days

Before I could turn my attention to a serious TFR, a most amazing thing happened: I quit my day job. I did this even though my wife and I were only a few months away from having our first child. What inspired this irrational behavior was my teaming up with Eric Swartz, WA6HHQ, to start Elecraft.

Eric and I had met quite a bit earlier, through NorCal. He was recruited as a technical advisor to the club, and helped me with some last-minute Sierra design issues. He also proved he was serious about QRP by racking up over 100 countries on his NorCal 40.

But it was doing Field Day together for five straight years that laid the foundation for Elecraft and for our transceiver designs. At FD 1995 and 1996 we used a hodge-podge of radios, batteries, antenna tuners and antenna switching schemes, often doing more QRP experimentation than operating. Finally, in 1997, we looked at that year’s pile of gear and concluded that there just had to be a better way. By early evening we had abandoned operating and were sketching out the K2 on the backs of FD log sheets.

The K2 was our notion of the ultimate Field Day rig, with all-band coverage, wide receiver dynamic range, current drain of about 200 mA, and internal accessories – battery, ATU, antenna switch, power meter, and contest keyer. But it was not really a backpacking transceiver. So in 2000 we introduced the K2’s baby brother, the K1. Now we were getting close!

The K1 is just a bit larger than a NorCal 40, draws 55 mA or so on receive, covers up to 4 bands without modules and includes an integral battery and ATU. We wanted the K1 to function like a TFR, so we designed a special tilt stand (KTS1) that would allow the rig to be aimed up, even when it was resting on the ground. The tilt stand is fully collapsible for transport, keeps the connectors up off the ground, and provides a place to mount a keyer paddle such as the Paddlette Backpacker.

But the K1 still doesn’t meet all of the design constraints for a TFR. It’s too heavy for many backpacking expeditions, and can’t be used conveniently in difficult operating situations, such as when sitting in a camp chair, lying in a sleeping bag, or standing up. So for two years the idea continued to simmer. And then, finally, something bubbled over.

Inspiration, Perspiration

One morning in March, 2003, I woke up suddenly with the design for a plug-in, physically-reversible keyer paddle in mind. This was the all-important missing link. The trick was to mount the paddle at a 45-degree angle for ease of use. I could thread a metal-bushing eighth-inch stereo plug into the custom mounting bracket and use a captive thumb screw to hold the paddle firmly to the panel. I quickly sketched out a TFR-style radio around this paddle: controls facing up, paddle facing forward, and batteries accessible via a removable bottom cover.

A few days later Eric and I fleshed out a set of performance and feature requirements. Like usual, Eric pushed performance and features, while I aimed for low current drain and ease of construction. Then, at the expense of other projects that I had been pursuing, I spent the next month doing the design.

This is where, for me, all of the constraints and possibilities of the CW TFR finally converged. I now felt that it was possible to satisfy all of the requirements Wes Hayward had laid out for us in the Mountaineer, while providing much better performance, enhanced usability, multiple bands and more operating features.

The most important design decision was to use a DDS VFO. This would eliminate a number of parts, including the transmit mixer and its crystal oscillator. While it wouldn’t provide the high spurious-free dynamic range of an L-C VFO, it would be very stable over a wide temperature range, and also frequency-agile, allowing full coverage of 40, 30, and 20 meters as well as nearby SWL bands. Other designers had used DDS VFOs in QRP rigs with success, notably Dave Benson (NN1G) in his DSW series. But I’d been holding out for a DDS chip with much lower current drain. Luckily, one appeared: the Analog Devices AD9834, which draws just 5 to 8 mA.

Another critical question was whether to use an LCD or LED for the 3-digit display. An LCD would have required a backlight, complicating packaging given the small area available for the display. It would also have required a separate display driver, since the KX1 had to get by with only a 28-pin MCU. So we opted for a rugged, incredibly efficient red / orange LED. The unit we selected can be driven directly by the MCU (multiplexed), and requires less than 100 microamps average per segment in typical room lighting. For outdoor use, the current requirement increases to as high as 0.8 mA per segment, meaning the LED contributes up to about 10 mA average (12 segments lit) at its brightest setting. However, we included two refinements to make this a non-issue: a programmable display-off timer, and a 100 percent audio Morse-code interface, even including menu text.

The Morse-audio feature allows the KX1 to be used without looking at the display, which is great for bicycle mobile operators, too-sleepy-to-keep-your-eyes-open Field Day operation, and operation in extremely bright sunlight. But we’ve also discovered that blind hams appreciate the KX1’s Morse-audio interface, and that alone was worth its inclusion.

Revisiting the Power-to-Weight Issue

In order to allow room for the automatic antenna tuner option (KXAT1), we decided to use just six AA cells for the rig’s internal battery pack. We discovered we had to use two 3-cell sockets with a gap in the middle to accommodate the keyer paddle jack and the I.F. and BFO crystals.

Six 1.5-volt lithium cells work very well in this application, providing around 1.5 to 2 watts output. And they last forever, it seems, with a rating of nearly three amp-hours and a very long shelf life. I did six KX1 field-test outings from May through September on a single set of these batteries.

So let’s return to the issue of how much power output is required for a backpacking rig. As you recall, Wes Hayward suggested one-half watt to attain a good power / weight tradeoff. But he didn’t have access to lithium 1.5-volt AA cells, which were invented in 1992. Alkalines have a similar milliampere-hour rating, yet their voltage rapidly drops as they discharge, and the mA-hr rating is based on an end-of-charge voltage of 0.9 volts. In contrast, lithium cells have a nearly flat discharge curve, remaining at about 1.4 volts for some 90 percent of their charge life. They also weigh just over half as much as alkalines – a six-cell pack weighs just 3 ounces.

So the equation really has changed. Given lighter batteries with better performance, I think the optimal power level for backpacking rigs is around 1.5 to 2 watts. This will produce more QSOs and more reliable emergency communications.

Finishing Touches

There are a number of other subtleties in the KX1 design that contribute to its small size and moderate parts-count. For example, the transmit low-pass filter is a careful compromise, covering three bands yet using just one relay. Only three crystals are used in the varactor-tuned IF filter, rather than four (K1) or seven (K2). T-R switching of the receiver’s bandpass filter is handled using a series-tuned circuit and an NPN transistor clamp rather than PIN diodes. The BFO is fixed-frequency, optimized for a 600 Hz sidetone / TX offset. A contacting rather than optical encoder is used, the former being much smaller and still having a long predicted lifespan of more than 100,000 rotations. Four sidetone levels are provided by simply using two outputs on the MCU and two resistors (i.e., a 2-bit DAC). And finally, a simple AGC circuit is used in combination with limiting at the AF amp. The LM386 runs from just 6 volts, so it clamps leading-edge thumps pretty effectively.

Two other features provided the icing on the cake: the log lamp and SWL coverage.

The integrated white LED log lamp elicits a lot of smiles when we demonstrate the KX1. It’s really handy for nighttime operation, allowing you to shut off your larger lantern or flashlight, which might disturb someone sleeping nearby. The LED only requires about 6 mA when operated from internal batteries, and since it has its own on-off switch, it doubles as a book lamp, flashlight, or a visible signaling device. During field test someone suggested that we use a red rather than white LED, since white light attracts flying insects. You can easily swap LEDs if this is a concern.

The KX1’s SWL coverage allows you to get news, time beacons (including WWV at 5, 10, and 15 MHz), weather information, and a variety of perspectives on world events. This seemed like a useful addition to a backpacking rig, since it may be the only radio you carry, and it has proven popular with early builders. The crystal filter can be widened out to about 2 kHz to listen to AM and SSB stations. For flexibility, we also added 5 kHz tuning steps, three frequency memories per band, and USB / LSB capability.

The KX1 could be made much smaller if we had used surface-mount components and AAA batteries, left out the ATU, and had been willing to pack the controls together more tightly. While this might help someone win in the “skinny” division of the Sprint, it would also make the rig less rugged and a lot harder to build and use. Instead, we designed the rig from the ground up to be a reliable, easy to build, easy to use, fully-integrated station. Our chosen 3″H x 5″W front panel size allows quite a bit of room for controls and display, and the 1.2″ height allows for AA batteries and an automatic antenna tuner.

K-zero (Not!)

Initially we didn’t know what to call the rig. We tried and rejected K.5, KR5, K-zero, and other names that would complete the dubious mathematical series { K2, K1, … }. We also rejected “Elecraft Elf,” although we may use that for something else . . . someday. “KX1” won in the end. “K” would keep the KX1 firmly planted in our line of transceivers. “X” was a reference to “eXtreme” operating conditions or “eXtremely small.” And “1” seemed a reasonable choice, since the rig is just too small to be a “2”.

When I first envisioned the KX1, what came to mind right away was the Adventure Radio Society. Russ and I had had a meeting about his ARS proposal a few months before the launch, and it was clear that he really did have adventurous and innovative plans for the organization. Given the many serious backpacking trips taken by Russ and other ARS members, the KX1 just seemed to be a good fit. I’m hoping we’ll get a lot more feedback on the design as the rigs find their way into the field.

But I also had a more esoteric goal for the KX1: I wanted it to be the ultimate radio for couch potatoes. Imagine lying on the couch, working CW DX with a paperback-novel-sized lap-top transceiver. It’s an entirely new way to experience CW – anywhere, anytime!
* * * * * * * * * * *
Wayne Burdick, N6KR, a founder of the Adventure Radio Society with membership No. 2, is one of amateur radio’s leading designer / innovators and co-owner of Elecraft, manufacturer of the KX1 trail-friendly transceiver.

Riding the shortwaves

I’ve enjoyed a little of my down time by tuning around with my Grundig YP300E. While not a feature rich radio, I’m surprised at how well it does. Two nights ago I enjoyed listening to a news program on Iranian radio. Reception was pretty solid and the propaganda reminded me of when I used to listen to Radio Moscow as a kid. Last night I tuned in to Radio Sweden for their half hour English language broadcast. I also briefly heard the Voice of Turkey, but was unable to get strong reception. It seems like I can always find the BBC.

The radio I’m looking at to give me the ability to receive LSB/USB as well as CW is the Elecraft KX1. What intrigues me most is it’s compact size. The radio has received excellent reviews on eHam.net. The radio’s small size will also allow me to take it on the road when I travel to Europe early next year.

An interesting website I stumbled across: ham-shack.com. It’s one stop shopping for a variety of information on amateur radio. I’m now reading the section
on the history of amateur radio called The Way Back Machine by Bill Continelli, W2XOY. Well written – great stuff.

Unveiled – the new Elecraft K3

This HF 160-10m rig comes in 10 and 100 watt versions. You can also get a kit version so you can build it yourself.

Please read the official announcement from the Elecraft Mailing list.


This afternoon at the DX Convention in Visalia, CA, we unveiled a new top-of-the-line transceiver — the Elecraft K3. This is the culmination of three years of design, test, and refinement, and we believe the K3 will set a new standard for performance and value in its class. It has features and performance comparable to present radios ranging from $4000 to $12000.

(We’d like to thank the many surprised convention attendees. What they all said boils down to something like “Yes!”)

A full K3 web page will be set up by Monday, complete with order form and other details. Meanwhile, please take a look at the temporary page:


Among other things, you’ll find a very high-resolution front panel photo (as well as other photos):


And the K3 data sheet:

Click to access K3_Data%20Sheet_rev06.pdf

There’s also an order form that could be printed and mailed, but sometime on Monday the on-line order page will be up and running, which is the preferred method.

As explained on the order form, you can reserve a K3 now for initial shipments in July. A 50% deposit is requested if you’d like to secure one of the first 200 production units (serial numbers 20-220, probably).

Here’s a quick summary of the K3’s specs:

– K3/100 and K3/10 models (the K3/10 can be upgraded very easily, internally, to a K3/100)

– Basic K3 price ranges from $1399 to $1989 depending on whether you start with the
10-watt or 100-watt model, and whether you choose factory assembled or
modular, no-soldering, kit (this is the subject of the next email).

– Desktop/portable size: 4″H x 10″W x 10″D (10 x 25 x 25 cm) — optimized for both
home and travel use

– All modes (SSB, CW, DATA, AM, FM, plus AM-sync receive, and built-in PSK31/TTY decoder)

– High-dynamic range, down-conversion architecture, plus 32-bit I.F. DSP
for software-defined capabilities (and lots of room for future expansion)

– Optional subreceiver with *identical* performance to the main receiver,
including a fully independent front end, its own set of roofing filters,
its own DSP, and low-noise synthesizer; binaural or combined receiver audio

– Up to five crystal roofing filters *per receiver*, with bandwidths as narrow as 200 Hz

– Narrow ham-band filtering, plus optional general-coverage receive filters
(can be added to either or both receivers)

– Internal 100-W ATU option with two antenna jacks

– 100 W PA module includes two large fans, circuit breaker, full parameter monitoring

– All signal sources phase-locked to common 49.380 MHz reference oscillator;
1 PPM TCXO option, firmware-correctable to better than 0.5 PPM

– Built-in PSK31, RTTY, and CW decoding and display allows use of
digital modes with or *without* a computer; use CW keyer paddle or
attached computer for casual, two-way data QSOs

– Advanced noise reduction; auto- and manual notch. Noise blanker included (both
I.F. hardware pulse blanker and DSP noise blanking)

– Easy-to-use DSP shift/width and locut/hicut controls with automatic crystal filter
selection based on selected passband width (in real-time — no filter calculation delays)

– Dedicated CW/voice message buttons; optional digital voice recorder

– 100 general frequency memories with alphanumeric text labeling, plus 4 scratchpad memories per band

– Full-custom, optimized, segmented LCD with two VFO displays, alphanumeric text, and
dedicated filter passband graphic

– Rich I/O set: stereo speaker outputs, fully isolated soundcard interface, dedicated RS-232
I/O (and optional USB adapter), receive antenna in/out jacks (for patching in RX filters, etc.),
and both front- and rear-panel mic and headphone jacks

– One-click PC firmware download program checks for updates automatically and quickly
updates microcontroller and DSP firmware

If you have any questions on specifications, performance, etc., that are not answered by the data sheet, feel free to email wayne@elecraft.com.

Sales questions should go to Lisa:


We’d like to acknowledge the hard work of the following colleagues:

Lyle Johnson, KK7P (DSP, digital I/O, audio I/O, many of the PC boards, and countless critical tasks)
Bob Friess, N6CM (RF deck, ATU, high-performance 1st mixer, noise blanker, other receiver design)
John Grebenkemper, KI6WX (synthesizer, general receiver architecture)
Brian Broggie, W6FVI (manufacturing engineering — say hi to him at Visalia tomorrow)
Paul Russell (purchasing)
Lisa Jones (who somehow held down the fort during the entire process)

Eric (WA6HHQ), as usual, applied pressure in all the right places to ensure that this would be the best radio we could make: he’s Mr. Performance and Features. Wayne (N6KR — yours truly) was the principle designer, and also got to do all the fun parts (packaging, firmware, and Owner’s manual). And that’s why he gets to answer your questions 🙂

We’d also like to express our thanks to our very patient 15-member focus group. Over a period of about a year, they endured a never-ending series of concept drawings, refinements, and feature discussions. They’re a distinguished bunch! I’m sure you’ll hear from some of them as the K3 is discussed at length.

Finally: thanks to all of you who have generously contributed ideas for a hypothetical K3 during our many on-line “fishing expeditions.” You had wonderful input, and I hope we’ve created the radio you’ve always wanted.

Wayne, N6KR
Eric, WA6HHQ

Keep your IC-706/MKII/MKIIG Cool!

I completed a quick and easy addition to my IC-706MKIIG today using a great article from Phil, AD5X. The article describes how to add a 12v fan on the back of the IC-706’s heatsink to help keep the radio cool. Phil’s article describes how to use a Molex plug on the back of the 706 to power the fan. Everything went smooth and the fan is working great.

Check out more articles here.

Thanks Phil!

Post Christmas Wrap Up

Christmas was good to me. I received a NorCal 40A kit along with David B. Rutledge’s The Electronics of Radio. Together these items make up a basic analog electronics’s course and my hope is to build the kit and learn more about electronics and radio.

Notes from the budding brewmaster: The final bottles of my first batch of beer were actually quite good. It worked out to the following: 2 weeks in the keg, 2 weeks in the bottle, 3 days in the fridge. Very tasty. Also – I’m sticking to regular white sugar for the carbonation.

I’ve also been spending way to much time playing Age of Empires III on my laptop.

I need to get in the radio room, tidy up, catch up on logging in a stack of QSL cards, and prepare for Straight Key Night.