My Mountain Topper Radio project

After doing some portable operations with the KX3, I felt that having something smaller and lighter would allow my pack to get smaller and smaller. The only problem is that there is nothing smaller than the KX3 that is comparable unless you get a CW only rig. I decided to get the MTR (Mountain Topper Radio) that was developed by Steve Weber (KD1JV). It’s a 2.5-5W QRP CW rig that gives you the options for two bands.

The problem is that the MTR kits are produced and sold in small quantities with high demand.  I’ve learned that Steve developed a version 2 of the MTR (3 bands) and had a pre-sale. Even though he gave out the wrong URL, people managed to figure out the correct URL and sold out within hours. I found out a tad too late and ended up having my money refunded.

I was a little bummed out. I was very excited that I might get this kit. I’ve never worked with surface mount devices and the CW only aspect of the rig would sort of force me to actually learn CW. After making my disappointment known, a local ham mentioned that he had an unbuilt kit from the orginal run that he might be willing to sell to me. Making fun of him didn’t help but I think the fact that I might learn CW might have compelled him to sell me his kit.

What did I just do?

Once I got my hands on the kit and took it home I inspected it (what ham doesn’t when they get a new toy?). That’s when I saw the components I’ll be dealing with. Very tiny resistors, capacitors and IC’s. The toroids were tiny and were not wounded.  Everything is so… small. I have built ham radio related kits before but they were all through hole meaning that the parts like the resistors and IC’s had legs and pins the fit into the holes. They were large enough to where I can easily work with them.

I am not prepared for surface mount work. My soldering iron is this $10 Radio Shack 35W fixed iron. I knew it was not ideal for SMT as I have tried and failed using that iron. I need to learn how to solder surface mount and I need the proper gear to do it with. I’ve learned over the years that working with the correct tools makes the job much easier.

New Tools In The Shack

I’ve learned the hard way many times over that having the proper tools can make things a lot easier. I feel that I have everything needed for the job except for a soldering iron. I looking at the sub $40 Chinese type irons but I stopped myself from purchasing one. I wanted an iron that can last me for many years so I ended up purchasing a Hakko 888D soldering iron. At around $100 I felt that it was worth the purchase.

The Build. Day One!

Soon as I got the iron in, I went straight to work. Following the assembly guide I started with the IC’s and the MCU. I felt that you are starting with the hardest part of the job by soldering small SMT IC chips with small leads and small gaps. I avoided installing the MCU and DDS chips until the other ICs were installed.  Once all the IC’s were installed, I used a jewelers loop and checked my connections. The MCU was crooked a bit and thought it was still good so I kept chugging along. I installed the resistors on the bottom of the board and called it a night.

20140506_215401

My working area. You’ll see the board with solder, tweezers, assembly manual, solder, 10X  Jewelers loop, desk lamp with magnifying glass and my new soldering iron. When I purchased the soldering iron, I also purchased different sized and shaped tips.

The Build. Day Two

Next day I got back from work and installed everything else.  It wasn’t really bad as I thought. The soldering Iron was tight in some places but it appeared everything went quite well.

smttsd

Here is a close up of my soldering. It could be better but I would say not too bad considering I’ve never done SMT work before.

Power On Time.

I didn’t want to wire up the power, headphones or anything else because I was going to design a case but in order to make sure it worked. I needed to wire it up.  Soon as I hooked up the battery… Nothing!  It did’t lite up, It didn’t beep. The only thing I notice was a slight noise in the headphones. Sounded like the noise of when you turn something on.

What Went Wrong?

As panic starts to set in, I was worried that I now have a nice new expensive brick  on my hands. All that time, energy and money spent on the kit and tools needed seemed be wasted. Out came the jewelers loop and soldering iron. I double checked every connection. Then I took out the multimeter and followed the troubleshooting guide in the manual and started checking voltages coming out of the regulators. Everything was checking out. The only thing I see is that the MCU was a little bit crooked.

I tried re-soldering the MCU but it proved to be very difficult. I used solder wick and suction tools that did not help, the chip would not move for me. For me the only choice was to remove the MCU. But how? After some internet searching I decided to use enameled wire and snake it under the chip where the leads meet the chip. I then touched the soldering iron to the leads and slowly pulled the chip off.

eIpMXvS

Using that method allowed to me to remove the chip, but in the process I damaged the MCU. The above images is not representative of my soldering work. It was more of a panic move and I just wanted to get the chip off without damaging the pads or board. The pads were in great shape and I’m just lucky nothing else happened.

Dealing With Steve Weber

Well it’s obvious the chip will need to be replaced. There are two options available. Beg steve for a new chip or purchase the MCU and flash it using a MSP Launchpad. I almost went the latter because Steve just released V2 and I am sure he was busy dealing with that and life in general but I decided to e-mail him anyways.

Dealing with Steve was a pleasure. I know these radios is not his full time job but he replied within a reasonable time and he was willing to send out a pre-programmed chip for my version of the MTR. Since I was having him sending me stuff, I purchased a case because the price he was asking was more than fair.

Attempt #2

Now that I have the new MCU, I promptly installed it. This time I quadruple check to make sure the chip was aligned properly before soldering. It went much better.

9xY2xy6

When I applied power I jumped for Joy as I saw the LED come to life and the sounds of CW in my headphone. I did some initial testing and then installed the last toroid.

It’s… ALIVE!!! ALIVE!!!  

Now that it turns on, it’s time to make the adjustments needed for proper operation. Thankfully I have Acquired the test gear I needed over the years from mostly local hams looking to clean their shack. I have a decent frequency counter, oscilloscope and a station monitor.

The manual found on the Yahoo Groups page provided step by step installation and tuning. It made things a lot easier.

20140525_093919

First thing I did was adjusted the reference oscillator frequency to match exactly 10MHz. This was very easy. Just pushing a button until I see 10Mhz on the counter. There are reference points on the board to where you can easily measure things.

20140525_094159

Adjusting the LO to find the center of the passband. This was a little tricky because I didn’t fully understand the manual and process. In the tuning mode the MCU sends out a tone and I adjusted it by watching the signal peaking on my scope while counting the steps between the peaks. I then went backwards only half of the steps. Hopefully it was done correctly. For me, this was the hardest part of tuning.

20140525_095042

Here I am adjusting the receivers filters. With the station monitor I injected a signal into the MTR through the antenna port and adjust the band capacitors until the signal was at it’s loudest. I did the same thing on the other band. This was quite easy.

Last thing I did was hooked it up to a dummy load and checked for output wattage. Using a variable power supply and a DMM hooked in-line, I’ve sent out a tuning signal and adjusted the power supply until the DMM read 9Vdc with a TX load. I was seeing approx 2.5W which is within spec.

Time to get one the air

Now that it’s built and tested, It’s time to get on the air and see what I can (not) do.

20140525_100322

Heh, it’s smaller than my paddle.  What’s great about CW is that you don’t have to call CQ over and over again hoping someone would come back to give you a signal report. Just call CQ a couple times and head over to the Reverse Beacon Network where you can see almost in real time where your signal is being heard. There are receivers all over the world scanning the bands for signals.

TdHhvUi

Here are my results using just a crappy 9V battery. I am pleased to see that not only are stations hearing my signal, but they are on the frequencies that the MTR is tuned to. While I was testing the worst thing happened… Someone replied. I tried very much to work the person. I know the call was a K2 something but that’s all I could make out.

Final Thoughts

This was my first actual kit that I built, It’s also the first time that I ever worked with tiny surface mount devices and even though I messed up the MCU, it was really fun to build. Soldering SMD seems to be a nightmare but after the first couple of parts, it felt real easy and it felt that I was working much quicker compared to through hole parts. This project is also a big kick in the ass to learn CW because I want to use this rig. I’m all about packing very lite when it comes to SOTA and even though I love the KX3, I feel it would be more of an adventure using the MTR. We’ll see.

Thanks for reading!

– Jeff

 

 

 

Hello APRS My old friend.

I’ve come to talk with you again.


APRS – ™ By:  Bob Bruninga, WB4APR Http://www.aprs.org

Back in 2001 when I first got my license. I was interested in APRS because it was something I can do with my new license. I went as far as setting up a part time digipeater and after only a couple of months, the digipeater went down and lost interest in APRS because the cost of a GPS receiver at the time (even though GPS is NOT a requirement to listen or participate on the APRS network).
GPS receivers are a lot cheaper compared to 10 years ago and I have a old Garmin GPS-V lying around. So I figured this would be the perfect time to get back into APRS. For those who don’t know what APRS is, It’s Automatic Packet Reporting System which is an Amateur (Ham) based system for real-time communications of information using a digital protocal (AX.25). There are many possible things you can do with APRS. You can send (Short) text E-mail, SMS Messages,  send weather data (Which the NWS uses) and when hooked up to a GPS , will send position data.  I am not going to go into much detail because there are websites that are dedicated to APRS.
I am going to be doing a couple of things with APRS. One thing is that I am going to set up a part-time iGate (internet gateway) to make use of the frequency scanner and antenna that is not being used. Packets of Information received from the scanner (tuned to 144.39mhz) will be sent over the internet using the APRS-IS network so it can be databased and displayed on such websites as aprs.fi .

The other thing I want to do is location tracking. In order to do tracking you’ll need 2 or 3 things. You’ll need a GPS receiver that has an output for NMEA data, TNC (Terminal Node Connector) and a transceiver (VHF [144-148mhz] is Most used). As stated earlier, I have a Garmin GPS-V lying around and I also have a Kenwood TH-78A.  All that is missing is a packet TNC.  A Real TNC can cost $100+ and needs a computer. However there are units designed and built for APRS that will encode the data from the GPS to the AX.25 protocol and transmit the signal using the transceiver. I’ve purchased one of these units called ” TinyTrack3+” from a company called Byonics. It’s as basic as it gets. You can either buy it as a kit or assembled, with or without a GPS Receiver, with or without cables for your transciver or with or without cables for various GPS models.  I ended up going with a solder and assemble your self kit without any extra cables because I wanted to invest the least amount of money in it as possible.

Here is the kit as you would get it in the mail. It comes with the componets, board, case and instructions.

Here is the board soldered up. I used a 35W Pencil type soldering Iron. I filed the tip a little bit to assure that solder flows to the tip. It took about 1/2 to 3/4 of an hour to solder. If your new to assembling boards, I would go to the Byonics website and download the manual because the online .pdf manual will cover the assembly and everything else in great detail. As long as you follow the step by step instructions, it will turn out great. For newbies make sure the diodes are going in the right direction, LEDs in the right direction and make sure the notch (little cutout) is aligned with the silk screen image.

Now that board is done, time to make some cables! (Since I didn’t order any)

Here is the cable all assembled! It’s a DB-9 Connector  (Radio shack P/n: 276-1538 US$2.69) , Pos and Neg power cords with Anderson power poles attached so it could powered by many different sources (7-35vDC), Sacrificed  speaker microphone from the Wouxun for its cable, Ferrite Core choke (Optional, Radio Shack P/N: 273-105) and the DB-9 Case (Radio Shack P/n: 276-1539 US$2.09). I Got the wiring diagram from the  Byonics website and took about 1/2 hour to make which ended up costing me around $5 since I already had the cable, choke and power connector

Just an FYI, I sacrificed a speaker microphone from my Wouxun. Power-Werx which distributes Wouxun products (as well as the power poles), has the exact same cable for this application for sale on their website. They also have a similar one but with a cigarette lighter plug (Both for US$20). Byonics also sells cables for this and many different radios. Also note that that wouxun speaker mic layout is the same for kenwood HT’s!

After you assemble the tracker and the cable. Apply power to unit and hopefully it comes to life by flashing the yellow and green LEDS three times. Only thing left to do is to program the tracker using your computer. This point it can get tricky. The TinyTrak3 needs a NULL modem cable (Or adapter) to program it and possibly a gender changer. I found that I didn’t have a null modem cable, all I have are straight through cables. Since I didn’t want to wait for an adapter I made one from old computer parts lying around my house

Here is the cable that I made from parts out of an old 486 that I had in the attic. It’s not pretty or rugged enough for daily use but once you program the Tracker and are satisfied with the operation then you will most likely not have to program it again.

Here is the complete setup. Right now I have the unit running off a 9V battery. I also used a cigarette lighter plug with power poles connected to it. Depending on how you programmed the tracker, It will only send when there is data from GPS. There are limitless things you can do with this setup. For SOTA members (Summits On The Air), They can bring this along with them so others can see their progress in their hike. If you helping out in a public service or public events which ham radio operators are helping, you can show your location to HQ without even telling them. It makes things a lot easier.

Here is my first track. I learned a lot when doing this. I found that my handheld in the truck has a hard time communicating with the digipeaters in the area. I might purchase a small 1/4″ wave mag-mount  or a duplexer and switch to my dual band antenna for when I am running APRS in the truck.

Modifications

I added things to the Tinytrak3+ which I think will make it better for me to run. If I had to be really critical about the tracker is that the DB-9 connectors did not come with mounting screws. The first test out with my truck the power/radio connector became loose and eventually lost power to the tracker. To fix this I went scavenging parts off  a old computer.

Now I can secure both the power and GPS connections. The screws came off the LPT and monitor ports of an old mother board. There is a small amount of space between the back plate of the connector and the board. So I had to grind down the bolts and nuts so It would not touch the board.

Another issue that might come is when I am portable (walking). More likely the power source for the tracker for this purpose will be a 9V battery. The tracker with all the LEDS running will consume around 18.6ma which means a 9V battery (.370Ah avg) could possibly last for about 9-12 hours (60% discharged). If  you turn off the LEDs, the power consumption is 6.6ma. On a 9V battery, the tracker could last around 30 hours. The TinyTrak3+ can run without the LEDS by cutting a lead (tells you how in the directions). If you using a high-capacity 9V (.580Ah)with no LEDs it could last for more than 50 hours so it might be beneficial to cut the lead and add a jumper. The down side is that you will not know the status of the Tinytrak.

So what I did is cut the lead on the board and installed a bridge (shown in the picture above with the blue jumper). When jumped the LEDs are operational.
Also pictured are 2 bridges installed (on the left side) for jumpers J5 (outside pair) and J6 (inside pair). If J5 is jumped it will switch to what was programed in the secondary tab in the program (Program 2) . This would work great for an event which required either a different call and/or different settings. After the event, you can switch back to the primary settings. If J6 is jumped it will send a signal to power on the transceiver. This would involve another board with a relay to put power into the transceiver or modifying the transceiver. I don’t plan on messing around with it any time soon but since I am soldering on jumper bridges, why not.

Overall it was a really great build and I am having a blast with APRS. My plans are to find a way to make it all fit into a nice tiny package that I could carry when hiking or driving.

73 and thanks for reading!