Well the RAC Canada Day Contest is over for another year.
As with all the RAC Contests I set certain goals for my self and for this one was no different.
The goals were as follows:
HAVE FUN- This is a must. I am a casual operator and not a βdyed in the woolβ contester. The main thing is to have fun and keep it friendlyβ¦ This was not an issue and I had a blast working across Canada.
TRY AND WORK CANADA COAST TO COAST TO COAST-
Well almost⦠I had contacts in:VE1, VE2, VE3, VE4, VE5, VE6, VE7, VE8, VE9 and VO1. East Coast to the West Coast and the North West Territory.
Unfortunately this time VO2,VY0, VY1 and VY2 escaped me.
HAVE A SCORE IN THE TOP 50% OF MY CATAGORY. Needless to say that this time its not going to happen. I made contacts on 15m, 20m and 40m and they were good contactsβ¦. I just needed more of them.
After about 9 hours of radio stretching it out over a 24 hour period it was all over. One of the lowest scores I will not be submitting but it was still fun.
Onwards and upwards soβ¦. Happy 4th of July to my American Friendsβ¦. Iβve already gotten 7 of the 13 Colonies station in the log and I started chasing them today.
Following on from my article about my QO-100 Satellite Ground Station Complete Build, this article goes into some detail on the Node-RED section of the build and how I put together my QO-100 Satellite Ground Station Dashboard web app.
The Node-RED project has grown organically as I used the QO-100 satellite over time. Initially this started out as a simple project to synchronise the transmit and receive VFOβs so that the SDR receiver always tracked the IC-705 transmitter.
Over time I added more and more functionality until the QO-100 Ground Station Dashboard became the beast it is today.
M0AWS QO-100 Ground Station Control Dashboard built using Node-RED.
Looking at the dashboard web app it looks relatively simple in that it reflects a lot of the functionality that the two radio devices already have in their own rights however, bringing this together is actually more complicated than it first appears.
Starting at the beginning I use FLRig to connect to the IC-705. The connection can be via USB or LAN/Wifi, it makes no difference. Node-RED gains CAT control of the IC-705 via XMLRPC on port 12345 to FLRig.
To control the SDR receiver I use GQRX SDR software and connect to it using RIGCTL on GQRX port 7356 from Node-RED. These two methods of connectivity work well and enables full control of the two radios.
M0AWS Node-RED QO-100 Ground Station Dashboard Flow as of 12/06/24
The complete flow above looks rather daunting initially however, breaking it down into its constituent parts makes it much easier to understand.
There are two sections to the flow, the GQRX control which is the more complex of the two flows and the comparatively simple IC-705 section of the flow. These two flows could be broken down further into smaller flows and spread across multiple projects using inter-flow links however, I found it much easier from a debug point of view to have the entire flow in one Node-RED project.
Breaking down the flow further the GQRX startup section (shown below) establishes communication with the GQRX SDR software via TCP/IP and gets the initial mode and filter settings from the SDR software. This information is then used to populate the dashboard web app.
M0AWS Node-RED QO-100 Ground Station Dashboard β GQRX Startup Flow
The startup triggers fire just once at initial startup of Node-RED so itβs important that the SDR device is plugged into the PC at boot time.
All the startup triggers feed information into the RIGCTL section of the GQRX flow. This section of the flow (shown below) passes all the commands onto the GQRX SDR software to control the SDR receiver.
M0AWS Node-RED QO-100 Ground Station Dashboard β GQRX RIGCTL Flow
The TCP RIGCTL -> GQRX node is a standard TCP Request node that is configured to talk to the GQRX software on the defined IP Address and Port as configured in the GQRX setup. The output from this node then goes into the Filter RIGCTL Response node that processes the corresponding reply from GQRX for each message sent to it. Errors are trapped in the green Debug node and can be used for debugging.
The receive S Meter is also driven from the the output of the Filter RIGCTL Response node and passed onto the S Meter function for formatting before being passed through to the actual gauge on the dashboard.
Continuing down the left hand side of the flow we move into the section where all the GQRX controls are defined.
M0AWS Node-RED QO-100 Ground Station Dashboard β GQRX Controls Flow
In this section we have the VFO step buttons that move the VFO up/down in steps of 10Hz to 10Khz. Each button press generates a value that is passed onto the Set DeltaFreq change node and then on to the Calc new VFO Freq function. From here the new VFO frequency is stored and passed onto the communications channel to send the new VFO frequency to the GQRX software.
The Mode and Filter nodes are simple drop down menus with predefined values that are used to change the mode and receive filter width of the SDR receiver.
Below are the HAM band selector buttons, each of these will use a similar process as detailed above to change the VFO frequency to a preset value on each of the HAM HF Bands.
The QO-100 button puts the transmit and receive VFOβs into synchro-mode so that the receive VFO follows the transmit VFO. It also sets the correct frequency in the 739Mhz band for the downlink from the LNB in GQRX SDR software and sets the IC-705 to the correct frequency in the 2m VHF HAM band to drive the 2.4Ghz up-converter.
The Split button allows the receive VFO to be moved away from the transmit VFO for split operation when in QO-100 mode. This allows for the receive VFO to be moved away so that you can RIT into slightly off frequency stations or to work split when working DXpedition stations.
The bottom two Memory buttons allow you to store the current receive frequency into a memory for later recall.
At the top right of this section of the flow there is a Display Band Plan Info function, this displays the band plan information for the QO-100 satellite in a small display field on the Dashboard as you tune across the transponder. Currently it only displays information for the satellite, at some point in the future I will add the necessary code to display band plan information for the HF bands too.
The final section of the GQRX flow (shown below) sets the initial button colours and starts the Powermate USB VFO knob flow. Iβve already written a detailed article on how this works here but, for completeness it is triggered a few seconds after startup (to allow the USB device to be found) and then starts the BASH script that is used to communicate with the USB device. The output of this is processed and passed back into the VFO control part of the flow so that the receive VFO can be manually altered when in split mode or in non-QO-100 mode.
M0AWS Node-RED QO-100 Ground Station Dashboard β Powermate VFO Flow
The bottom flows in the image above set some flow variables that are used throughout the flow and then calculates and sets the RIT value on the dashboard display.
The final section of the flow is the IC-705 control flow. This is a relatively simple flow that is used to both send and receive data to/from the IC-705, process it and pass it on to the other parts of the flow as required.
M0AWS Node-RED QO-100 Ground Station Dashboard β IC-705 Control Flow
The IC-705 flow is started via the timestamp trigger at the top left. This node is nothing more than a trigger that fires every 0.5 seconds so that the dashboard display is updated in near realtime. The flow is pretty self explanatory, in that it collects the current frequency, transmit power, SWR reading, PTT on/off status and S Meter reading each time it is triggered. This information is then processed and used to keep the dashboard display up to date and to provide VFO tracking information to the GQRX receive flow.
On the left are the buttons to change band on the IC-705 along with a button to tune to the VOLEMT on the 60m band. Once again there two memory buttons to save and recall the IC-705 VFO frequency.
The Startup PTT Colour trigger node sets the PTT button to green on startup. The PTT button changes to red during transmit and is controlled via the Toggle PTT function.
At the very bottom of the flow is the set transverter IF Freq function, this sets the IC-705 to a preselected frequency in the 2m HAM band when the dashboard is switched into QO-100 mode by pressing the QO-100 button.
On the right of the flow there is a standard file write node that writes the 2.4Ghz QO-100 uplink frequency each time it changes into a file that is used by my own logging software to add the uplink frequency into my log entries automatically. (Yes I wrote my own logging software!)
The RX Audio Mute Control filter node is used to reduce the receive volume during transmit when in QO-100 full duplex mode otherwise, the operator can get tongue tied hearing their own voice 250ms after theyβve spoken coming back from the satellite. This uses the pulse audio system found on the Linux platform. The audio is reduced to a level whereby it makes it much easier to talk but, you can still hear enough of your audio to ensure that you have a good, clean signal on the satellite.
As I said at the beginning of this article, this flow has grown organically over the last 12 months and has been a fun project to put together. Iβve had many people ask me how I have created the dashboard and whether they could do the same for their ground station. The simple answer is yes, you can use this flow with any kind of radio as long as it has the ability to be controlled via CAT/USB or TCP/IP using XMLRPC or RIGCTL.
To this end I include below an export of the complete flow that can be imported into your own Node-RED flow editor. You may need to make changes to it for it to work with your radio/SDR but, it shouldnβt take too much to complete. If like me you are using an IC-705 and any kind of SDR controlled by GQRX SDR software then itβs ready to go without any changes at all.
I get quite a few emails from readers of my blog asking how my QO-100 satellite station is put together and so, I thought perhaps now is a good time to put together an article detailing the complete build.
My QO-100 satellite ground station is built around my little Icom IC-705 QRP transceiver, itβs a great little rig and is ideal for the purpose of driving a 2.4Ghz transverter/up-converter.
Of course all the software used for the project is Opensource and freely available on the internet.
M0AWS QO-100 Ground Station Build Visual (Click to Enlarge)
The station comprises of the following building blocks:
QO-100 Ground Station Dashboard developed using Node-RED
LMR400-UF/RG58 Coax Cable
M0AWS QO-100 1.1m (110cm) off-set Dish with IceCone Helix antenna and Bullseye LNB.
To get a good clear view of the QO-100 satellite I have the dish mount 3.2m above the ground. This keeps it well clear of anyone walking past in the garden and beams the signal up at an angle of 26.2 degrees keeping well clear of neighbouring gardens.
The waterproof enclosure below the dish houses all the 2.4Ghz equipment so that the distance between the feed point and the amplifier are kept to a minimum.
The DXPatrol amplifier is specβd to run at 28v/12w or 12v/5w, I found that running it at 28v produced too much output for the satellite and would cause the LEILA alarm on the satellite to trip constantly. Running the amp at 12v with a maximum of 5w output (average 2.5-3.5w) is more than enough for me to have a 5/9+10 signal on the transponder.
The large 1.1m dish gives me quite an advantage on receive enabling me to hear the very weak stations with ease compared to other stations.
2.4Ghz ground station enclosure ready for testing
The photo above shows the 2.4Ghz equipment mounted in the waterproof enclosure below the dish. This photo was taken during the initial build phase before I rewired it so, the amplifier is shown connected to the 28v feed. To rewire the amp to 12v was just a matter of removing the 28v converter and connecting the amp directly to the 12v feed instead. This reduced the output from a maximum of 12w down to a maximum of 5w giving a much better (considerate) level on the satellite.
Itβs important to keep all interconnects as short as possible as at 2.4Ghz it is very easy to build up a lot of loss between devices.
For the connection from the IC-705 to the 2.4Ghz Up-Converter I used a 7m run of LMR-400 coax cable. The IC-705 is set to put out just 300mW on 144Mhz up to the 2.4Ghz converter and so itβs important to use a good quality coax cable.
Once again the output from the 2.4Ghz amplifier uses 1.5m of LMR-400-UF coax cable to feed up to the 2.2 turn Icecone Helix Antenna mounted on the dish. This keeps loss to a minimum and is well worth the investment.
Bullseye 10Khz High Stability Unversal Single LNB for 10.489-12.750Ghz
The receive path starts with a Bullseye LNB, this is a high gain LNB that is probably one of the best you could use for QO-100 operations. Itβs fairly stable frequency wise but, does drift a little in the summer months with the high temperature changes but, overall it really is a very good LNB.
The 12v feed to the LNB is via the coax and is injected by the Bias-T device that is in the radio shack. This 12v feed powers the LNA and associated electronics in the LNB to provide a gain of 50-60dB.
Bias-T to inject 12v feed into the coax for the Bullseye LNB
From the Bias-T the coax comes down to the NooElec SmartSDR receiver. This is a really cheap SDR device (<Β£35 on Amazon) based on the RTL-SDR device but, it works incredibly well. I originally used a Funcube Dongle Pro+ for the receive side however, it really didnβt handle large signals very well and there was a lot of signal ghosting so, I swapped it out for the NooElec SDR and havenβt looked back since.
The NooElec SmartSDR is controlled via the excellent Opensource software GQRX SDR. Iβve been using GQRX SDR for some years now and itβs proven itself to be extremely stable and reliable with support for a good number of SDR devices.
To enhance the operation of the SDR device I have added a Griffin Powermate VFO knob to the build. This is an old USB device that I originally purchased to control my Flex3000 transceiver but, since I sold that many moons ago I decided to use it as a VFO knob in my QO-100 ground station. Details on how I got it working with the station are detailed in this blog article.
Having the need for full duplex operation on the satellite this complicates things when it comes to VFO tracking and general control of the two radios involved in the solution and so I set about creating a QO-100 Dashboard using the great Node-RED graphical programming environment to create a web app that simplifies the management of the entire setup.
M0AWS QO-100 ground Station Control Dashboard built using Node-RED.
The QO-100 Dashboard synchronises the transmit and receive VFOβs, enables split operation so that you can transmit and receive on different frequencies at the same time and a whole host of other things using very little code. Most of the functionality is created using standard Node-RED nodes. More info on Node-RED can be found on the Opensource.radio Wiki or from the menuβs above.
Iβll be publishing an article all about the QO-100 Dashboard in the very near future along with a downloadable flow file.
Iβm extremely pleased with how well the ground station works and have had well in excess of 500 QSOβs on the QO-100 satellite over the last last year.
Commemorating the 80th anniversary of the Allied assault on Normandy beachesFrom June 4 to 9, 2024, a number of crew members of the Plusscouts PA3EFR/J and other Radio Scouters will be traveling to Normandy (Omaha Beach) to support the international ac...
Commemorating the 80th anniversary of the Allied assault on Normandy beachesFrom June 4 to 9, 2024, a number of crew members of the Plusscouts PA3EFR/J and other Radio Scouters will be traveling to Normandy (Omaha Beach) to support the international ac...
Last December, students from the Advanced Technology Group of the Harbor Creek School District in Harborcreek, Pennsylvania, got the rare opportunity to talk with European Space Agency astronaut Andreas Mogensen, KG5GCZ, who was operating from the International Space Station (ISS). The event drew a great deal of attention, shining a spotlight on the young hams who did such a stellar job representing the bright future of amateur radio.
This May, members of the enthusiastic group were treated to another exciting opportunity to experience the best in amateur radioβan up-close look at one of the worldβs premier contesting sites. Tim Duffy, K3LR, DX Engineering CEO, hosted the students at his superstation, where the young hams could see the antennas, transceivers, and other equipment that have been used by world-class teams to produce record-breaking scores in high-profile contests.
Joining Tim, K3LR, were Scott Jones, N3RA, DX Engineering sales manager; Colleen Campbell, KB8VAQ, a science teacher at Columbiana High School in Columbiana, Ohio; her daughter Katie Campbell, KE8LQR, who was a participant in theΒ 2023 Dave Kalter Memorial Youth DX Adventure at K3LR; Drew Mortensen, AC3DS, and Allen Lombardozzi, KC3TGY, from Harbor Creek Senior High; and Elaine LaFuria, KC3SFY, from Harbor Creek Junior High.
βThank you for this great opportunity for our students. They absolutely loved this trip today. Drew, Elaine, and I really appreciate all you did for our club today. This was such a great learning experience for them and us.β
Allen, KC3TGY, from the DX Engineering Facebook page
From all of us at DX Engineering and OnAllBands, best of luck to the Advanced Technology Group as you explore new worlds of opportunity through amateur radio. 73!
The event was held on June 1st and finished on June 2nd. At the time of posting this there were 106 Museum Ships (including memorials) on the list. For more info on the event check out: https://www.nj2bb.org/museum/ .
In Kingston we were fortunate enough to have the SS Keewatin berthed at the Great Lakes Museumand so for this event it was a 45 min bus ride with all the radio gear I needed to participate.
Here is a couple of pics I took while at the museum.
The gear I used for operating from alongside the Keewatin was my POTA Station that consisted of my Yaesu FT891, Eco-Worthy 20ah LIPO 4 battery and a MFJ 33 foot telescopic mast to support the home brewed 63 Foot End Fed Half Wave (10m to 40m) antenna.
It looks rather small compared to the size of the Keewatin⦠Thanks to the Taxi Driver who moved into the pic so I could show the size of the ship easier. No I did not use the taxi⦠Kingston Transit bus #3 stops right at the front door of the Museum.
All my gear fit in my wifeβs laundry cartβ¦ She may never get it back nowβ¦
I used some bungy cords to secure the mast (right of the pic) to a fence behind the tree cover. It suspended the EFHW in a βinverted Veeβ configuration and worked well for me with no tuner needed.
I was able to operate for about 3 hours (or less) each day. The gear worked without a hitch but not so much the operator.
As the radio room in the Keewatin has not been updated yet, I was forced to operate from alongside (the above pic) so I was unable to leave the gear to use the facilities and so once nature called⦠it was time to pack up.
At the end of the event according to my logs I actually was contacted by 100 stations that were βWelcomed on Board the Keewatinββ¦ of those 100 contacts 12 of them were other Museum Ship and their details follow.
(Pictures above the name of the ship)
Col James M Schoonmaker
USS Lafferty
USS Thresher Memorial
USS Massachusetts
Tall Ship Elissa
USS Nautilus
Claud W Somers
USS North Carolina
Watson Naval Museum
USS Salem
USS Cobia
This was a βspur of the momentβ style of activation. I was going past the ship a week before and then found out the Museum Ships event was the next weekend. Although the Keewatin does have a valid Callsign without the radio room ship shape they were not in a position to activate.
I asked if I could do it and was given the green light to operate (using my own personal callsign) from where I did. (alongside but outside the fence)
As the Drydock is part of the Great Lakes Waterfront Trail (POTA CA-6003) some amateurs also got a new park in their logs.
Long story shortβ¦ The activation was a successβ¦. At least 100 amateurs now know of our ship and the Museum Ship community welcomed the Keewatin and its my hope that next year the ship itself will the on the air.
If we made the contact, thanks again. My logs for the two day event have been uploaded to EQSL, QRZ.com, the Museum Ships Group and will be uploaded to LoTW when they have fixed the security issue. I will also offer a copy of my logs to the Keewatin Radio Operators (see above link) for their records.
This solution has worked incredibly well from the outset and over time Iβve added extra functionality that Iβve found to be useful to enhance the overall setup.
The latest addition to the ground station solution is a Sennheiser Headset that I picked up for just Β£56 on Amazon (Much cheaper than the Heil equivalents at the HAM stores!) and have found it to be excellent. The audio quality from both the mic and the headphones is extremely good whilst being light and comfortable to wear for extended periods.
M0AWS β Sennheiser SC 165 Headset
To incorporate this into the ground station the headset is connected to my Kubuntu PC and the audio chain to the IC-705 is sent wirelessly using the latest version of WFView. This works extremely well. The receive audio comes directly from the GQRX SDR software to the headphones so that I have a full duplex headset combination.
Audio routing is done via pulse audio on the Kubuntu PC and is very easy to setup.
Since I no longer have a mic connected to the IC-705 directly I found that I needed a way to operate the PTT wirelessly and this is where the latest addition to my NodeRed QO-100 Dashboard comes in.
Adding a little functionality to the NodeRed flow I was able to create a button that toggles the IC-705 PTT state on and off giving me the ability to easily switch between receive and transmit using a simple XMLRPC node without the need for a physical PTT button.
M0AWS β Additional NodeRed PTT Flow
The PTT state and PTT button colour change is handled by the Toggle PTT function node shown in the above flow. The code to do this is relatively simple as shown below.
M0AWS β NodeRed Toggle PTT Function to change button colour
The entire QO-100 Dashboard flow has grown somewhat from itβs initial conception but, it provides all the functionality that I require to operate a full duplex station on the QO-100 satellite.
M0AWS β NodeRed QO-100 Dashboard complete flow
This simple but, effective PTT solution works great and leaves me hands free whilst talking on the satellite or the HF bands when using the IC-705. This also means that when using my IC-705 it only requires the coax to be connected, everything else is done via Wifi keeping things nice and tidy in the radio shack.
M0AWS β Updated NodeRed QO-100 Dashboard with PTT button
The image above shows the QO-100 ground station in receive cycle with the RX/TX VFOβs in split mode as the DX station was slightly off frequency to me. The PTT button goes red when in TX mode just like the split button shown above for visual reference.
As you can probably tell, Iβm a huge fan of NodeRed and have put together quite a few projects using it, including my HF Bands Live Monitoring web page.
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