We’ve been having a lot of fun with the Greencube (IO-117) satellite, so I decided to put together a portable ground station for activating grid squares. I wanted a station that –

• Has adequate antenna gain and power for reliable Greencube operation
• Uses solar-battery power so that it is quiet when operating in public places
• Uses computer management for Doppler correction
• Can provide accurate grid locator information via  a GPS receiver
• Is easy to set up in the field in less than 30 minutes

Station Components

We already have a solar-battery power system that we build for portable operation with a 100w transceiver as well as an IC-9700 transceiver that we use as part of our transportable satellite ground station. We also have Windows and Mac laptop computers that we can use as part of our Greencube (IO-117) portable ground station. With these components in mind, here are the hardware components that we are using as part of our Greencube portable station –

• Icom IC-9700 Transceiver (70 watts output on 70cm).
• M2 Antenna Systems 440-11X Antenna mounted on a heavy-duty video camera tripod.
• Advanced Receiver Research coax-powered LNA.
• A portable solar-battery power system capable of producing up to 180 watts of power.
• MacDoppler software running on a MacBook Air Laptop.
• Greencube digital client and logging software running on a Windows Computer.
• A GPS Dongle and Client Software is running on a Windows Computer to accurately determine the grid locator we are operating from.
• A Verizon Jetpack 4G Wireless Modem for Internet Access.

We are using the following software for our portable Greencube (IO-117) ground station:

• UZ7HO’s Greencube Soundmodem (download greentnc.zip).
• OZ9AAR’s Greencube Terminal Software.
• DK3WN’s Greencube Telemetry Decoder.
• MacDoppler to determine antenna pointing and to provide automatic Doppler correction on the IC-9700.
• N3FJP’s ACLog for logging contacts.
• NMEATime 2 Client Software to accurately determine the grid locator that we are operating from.

We also purchased a case (Pelican Air 1555) to package the transceiver and accessories.

Antenna System

We choose the M2 Antenna Systems  440-11X Antenna for our portable ground station. This antenna has more than adequate gain for use with Greencube, and its lightweight rear-mounted design makes it ideal for use with our heavy-duty video camera tripod.

The antenna is attached to the tripod using a Camera Tripod Ball Mount, a Handlebar Ball Mount Clamp, and a Double Socket Ball Arm. The Handlebar Clamp grips that antenna’s rear extension and allows the antenna to be easily rotated to align its polarity with Greencube’s antenna during a pass. A short section of water pipe with a cap, hook, and a 1,000-gram weight provides a counterweight to balance the antenna on the tripod.

A Magnetic Digital Angle Guage is used to adjust the elevation angle of the antenna.

A coax-powered LNA from Advanced Receiver Research (an available alternative is the SSB Electronic SP 70 preamp) is attached to one of the legs of the tripod and is connected to the antenna with a short LMR-240uF coax cable. a 20′ length of LMR-400uF coax connects the antenna system to the transceiver. N-connectors are used throughout the feedline system.

Radio, Computers, and Software

Our setup uses an Icom IC-9700 transceiver and two computers. The IC-9700 transceiver is connected to the Windows computer via the radio’s USB port and to the MacBook Air via a CI-V cable.

The Windows computer runs the following software programs to provide the client terminal, modem, and logging functions required to operate with Greencube –

• UZ7HO’s Greencube Soundmodem (download greentnc.zip)
• OZ9AAR’s Greencube Terminal Software
• DK3WN’s Greencube Telemetry Decoder

The configuration of these programs is covered in more detail here.

The Windows laptop also runs the NMEATime application and uses a USB GPS Dongle to accurately determine the grid locator where we are operating from. The grid locator from NMEATime is used to configure MacDoppler to ensure accurate tracking information for aiming our antenna.

The MacBook Air laptop runs MacDoopler. MacDoppler is connected to the IC-9700 transceiver via a CI-V cable and controls the IC-9700’s uplink and downlink frequencies to provide Doppler correction. MacDoppler is also used to determine the azimuth and elevation of Greencube to enable manual pointing of our antenna.

Power System

Powering a 100-watt transceiver in a portable application during extended operating sessions can present a challenge. I also wanted a setup that was quiet as we often operate portable in public locations. For these reasons, I decided to put together a solar-battery setup that consists of the following components:

• Two 90-watt foldable solar panels from PowerFilm (current model is 120W)
• Two A123 4S4P 10.0 Ah LiPo batteries from Buddipole
• An MPPT Charge Controller
• A RigRunner Power Distribution Panel

The solar panels are wired in series and provide about 34 Vdc in bright sunlight.

The MPPT Charge Controller automatically determines the best balance between cell voltage and current to provide maximum power transfer to charge the batteries. The batteries provide the extra power capacity needed when transmitting. The resulting power setup can sustain the full power operation of our portable station, even on cloud days.

The laptops run on their internal batteries and are changed via automotive lighter socket power adapters between operating sessions.

Operating Using Greencube

My initial tests of the portable station were done using the station to receive Telemetry from Greencube. This allowed me to learn to steer the antenna and adjust it for the best polarity during passes. The station had no trouble hearing and decoding Greencube’s telemetry transmission from horizon to horizon.

It was relatively easy to point the antenna based on the azimuth and elevation information from MacDoppler. I used a compass app on my iPhone to set the antenna’s azimuth heading and the Digital Angle Guage to set the antenna’s elevation. Pointing the antenna to within +/- 10 degrees of accuracy was adequate for reliable operation with Greencube.

I turned the speaker volume on the radio high enough so I could hear Greencube’s signal while adjusting the antenna polarity. Finding the polarity that caused Greencube’s signal to be weakest and then rotating the antenna 90 degrees from this point worked well.

I was able to make 15-20 contacts on each Greencube pass with our portable ground station. The RSSI graph in the Greencube terminal is a good indicator to determine when to adjust the antenna’s heading and polarity to track Greencube during a pass. It’s best to have a helper with one person making contacts and the other adjusting the antenna, but it’s possible for a single operator to do both jobs and still make many contacts during a pass.

More Fun With Greencube

I am quite pleased with the performance of our new portable ground station for Greencube (IO-117). Anita and I are planning a portable grid square activation trip for later in the fall to make use of the station.

This article is the fifth in a series that we are working on. You view the other articles via the links below. This is a work in progress, and we’ll be creating additional Greencube-related posts in the near future:

• Greencube (IO-117) – A New Satellite for DX!
• Greencube (IO-117) – Station Setup, Software, and Operation
• Greencube (IO-117) – Completing a Satellite Worked All States
• Greencube (IO-117) – M2 Antenna Systems LEO Pack – Will It Work?
• Greencube (IO-117) – The Road to a Satellite DXCC?

You can also read more about our Satellite Ground stations here.

Fred, AB1OC

The post Greencube (IO-117) – A Portable Station for Activating Grid Squares appeared first on Our HAM Station.

I’ve recently upgraded the Amplifier for our 2m EME station to one that can provide full-duty cycle operation at 1500 watts. The digital modes used for EME on 2m (JT65 and Q65) require an amplifier that can sustain full output for periods of 1 minute or more as well as sustain full power operation at a 50% duty cycle over an extended period of time.

I’ve had great experiences with Jim Klitzing, W6PQL’s amplifiers in our station so I contacted Jim to build a new 2m amplifier for our EME station.

Construction and Setup

Jim does an excellent job with the design and construction of his amplifiers. The parts are top-notch and the quality of construction and attention to detail are second to none. Jim provides components and sub-assemblies as well as some turn-key amplifiers.

He hand-builds each amplifier to his customer’s specifications and there is usually some wait time to receive a completed amplifier. The results are absolutely worth the wait!

The connection and setup of the amplifier was straightforward. It is well worth the effort to hook up an ALC feedback connection from the amplifier to your exciter. In our case, we are using an Icom IC-9700 to drive the amplifier. This radio does not have a positive sequencing control input for the power stage of the transceiver. Our setup uses an external sequencer to manage transmit and receive changeover and protect our tower-mounted preamplifiers. We have had numerous problems where sequencing errors damaged our preamps.

One of the unique features of Jim’s Amplifier Control Board is the inclusion of an ALC hold-back capability. The amplifier can be configured to send an output limiting ALC voltage to the driving transceiver to prevent any power from being applied until the sequencer completes the final Tx changeover step by keying the amplifier. This feature requires additional amplifier adjustment (the adjustment procedure is well covered in the documentation). This capability has eliminated the issue of sequencing problems causing damage to our preamplifiers!

Power Supply

The recommended power supply for this amplifier is a 48-volt, 62.5-amp switching design from Meanwell (Model RSP-3000-48). Jim set up the supply and provided the cabling to connect it to the amplifier. The supply is 240 VAC powered and is quite efficient. Jim adjusted the power supply’s output voltage and tested the amplifier with it with the amplifier before shipping.

Controls and Operation

The operation of the amplifier is straightforward. It is best to set the driving transceiver for a watt or so and perform some initial test transmissions to ensure that the antenna system is presenting a low SWR and that your station’s sequencing system is operating correctly. Note the LNA and Amplify Controls must be turned on for the ALC holdback feature to work correctly.

The amplifier provides PA Voltage and PA Current meters as well as bar-graph displays for Forward and Reflected power.

More Articles on EME

We are very pleased with our new amplifier! I’ve used it for quite a few contacts, and it performs great. It provides a full 1500 watts output with the digital modes used for EME work.

You can read more about our EME station project via the links that follow:

• EME Station 2.0 Part 1 – Goals and Station Design
• EME Station 2.0 Part 2 – Excavation, Footings, and Conduits for New Tower
• EME Station 2.0 Part 3 – Phase Tuned Receive Coax Cables
• EME Station 2.0 Part 4 – New EME Tower Is Up!
• EME Station 2.0 Part 5 – Control Cables and Rotator Controller
• EME Station 2.0 Part 6 – Tower Grounding System
• EME Station 2.0 Part 7 – Building Antennas
• EME Station 2.0 Part 8 – Elevation Rotator Assembly and Sub-System Test
• EME Station 2.0 Part 9 – H-Frame Assembly
• EME Station 2.0 Part 10 – Antennas On The Tower
• EME Station 2.0 Part 11 – Station Hardware in Shack
• EME Station 2.0 Part 12 – Station Software
• EME Station 2.0 Part 13 – H-Frame Enhancements

If you’d like to learn more about How To Get Started in EME, check out the Nashua Area Radio Society Tech Night on this topic. You can find the EME Tech Night here.

Fred, AB1OC

The post EME Station 2.0 Part 14 – New 1.5 Kw Amplifier appeared first on Our HAM Station.

Quite a few folks have the M2 Antenna System LEO pack antenna. I wanted to see how this antenna system would perform with Greencube (IO-117). Our LEO Pack is set up on a Glen Martin roof tower that we’ve modified to create a transportable ground station. Here are some of the specs for the setup we’ve tested:

• M2 LEO Pack Antennas (2MCP8A and 436CP16)
• Alpha-Spid Az/El Rotator
• M2 Polarity Switches installed in both antennas
• Advanced Receiver Research coax-powered preamps installed at both antennas+

The specifications for the 70cm antenna are as follows:

• Frequency Range: 432 To 438 MHz
• Gain: 13.3 dBic
• Front to back: 15 dB Typical
• Beamwidth: 42° Circular

The published gain number for this antenna meets the requirements for operation with Greencube, so we set up our transportable station in our backyard and proceeded to do some testing.

Transportable Ground Station

The ground station setup includes an IC-9700 Transceiver, a Green Heron RT-21 AZ/EL Rotator Controller, and two computers.

The Mac laptop runs MacDoppler, which handles steering the antennas and Doppler correction, and the Windows laptop runs the modem and client software to access Greencube’s Digipeater.

The antennas are located about 100 ft from the rest of the ground station and are connected using LMR-600uF coax cable. This results in about 40 watts of power being delivered to the feedpoint of the 70 cm antenna.

Testing The LEO Pack With Greencube’s Digipeater

I am happy to report that the LEO Pack 70cm antenna enabled us to make quite a few contacts using the Greencube Digipeater. The setup required the remote preamp to be on and the use of the polarity switching controls to optimize losses due to mismatched polarity, which occurred frequently during Greencube passes. The LEO Pack antenna/preamp combination provided consistent decodes of Greencube’s packets. The challenge was getting our packets to be Digipeated by Greencube. On some passes, this worked very well. During other passes, we were only able to get reliable Digipeats during the approaching portion of a pass at elevations above 25 degrees.

Optimizing Our Station

I spent a lot of time determining the best uplink frequency to use with Greencube’s Digipeater. The settings above are what I finally settled on for uplink and downlink frequencies.

I also spent some time experimenting with the Soundmodem settings. The lengthened Tx lead-in and tail settings above helped Greencube decode our signals more reliably.

These adjustments also improved the Digipeating performance of the larger antennas used in our main ground station, so they are not specific to the LEO Pack.

Conclusions About The LEO Pack and Greencube

I probably made about 50 contacts using Greencube and our LEO Pack antennas. If you already have a ground station built around the LEO Pack Antenna System, I would encourage you to add a preamplifier if you don’t already have one and try Greencube.

If you are building a fixed ground station for use with Greencube, it might be better to step up to a larger antenna such as the M2 Antenna Systems 436CP30.

I have also found that antennas with circular polarity are not necessarily the best for Greencube. This is likely due to a combination of the lengthened path through the ionosphere due to Greencube’s altitude, resulting in stronger polarity rotational effects and mismatches with the circularly polarized antennas we are using. I am anxious to do some more testing with the non-circularly polarized yagi that we are using with our portable station to see if I can confirm this.

More Fun With Greencube

This article is the fourth in a series that we are working on. You view the other articles via the links below. This is a work in progress, and we’ll be creating additional Greencube-related posts in the near future:

• Greencube (IO-117) – A New Satellite for DX!
• Greencube (IO-117) – Station Setup, Software, and Operation
• Greencube (IO-117) – Completing a Satellite Worked All States
• Greencube (IO-117) – A Portable Station for Activating Grid Squares
• Greencube (IO-117) – The Road to a Satellite DXCC?

You can also read more about our Satellite Ground stations here.

Fred, AB1OC

The post Greencube (IO-117) – M2 Antenna Systems LEO Pack – Will It Work? appeared first on Our HAM Station.

Greencube (IO-117) is a Medium Earth Orbit (MEO) satellite that carries a 70cm digipeater. This satellite can provide DX contacts covering a wide area around an Amateur Radio satellite ground station. Putting together a station and the necessary software to use Greencube is not difficult. If you already have a computer-controlled satellite ground station that works on 70cm, you may already have most of what is needed. We’ll cover Greencube (IO-117) setup in detail in this article.

Operating with Greencube – What’s Required

Greencube (IO-117) requires the following for successful contacts via its digipeater:

• A directional antenna with at least 12 dBi gain
• A 70cm SSB/FM capable Transceiver with a soundcard interface and at least 25 watts of output at the antenna
• Software to control the Transceiver to correct for Doppler shift and provide antenna tracking control or pointing information
• A computer running modem software and a Greencube Terminal Program
• A low-noise preamp at the antenna is recommended

Greencube Satellite Antennas

We have three different antenna combinations that are Greencube capable here:

• An M2 Antenna Systems 436CP46UG antenna(18.9 dBic gain) on a house-bracketed tower
• An M2 Antenna System LEO Pack with a 436CP16 antenna (13.3 dBic gain) on a transportable ground tower
• An M2 Antenna Systems 440-11X antenna (13.44 dBi gain) mounted on a camera tripod for portable use

All three antennas have Advanced Receiver Research Low-Noise preamps which are powered via the associated antenna’s coax feedline. Unfortunately, the ARR preamps are no longer available. A good alternative would be the SSB Electronic SP 70 preamp. I recommend choosing a preamp that can be sequenced using coax power from your transceiver if your transceiver supports coax-powered preamps. This approach ensures that your preamps are protected from transmit power in most operational scenarios.

Radio, Computers, and Power

All of our Greencube (IO-117) setups use an Icom IC-9700 Transceiver.

We use two computers to run our stations:

• A Mac (iMac or MacbookAir) running MacDoppler to control antenna tracking and to control our IC-9700 to perform Doppler correction
• A Windows PC running the modem, terminal client software, and a logger for using Greencube’s digipeater and for decoding telemetry

Using the two computers means that both must simultaneously control the IC-9700 via the radio’s CAT interface. This is easily accomplished with the IC-9700 by using both the CI-V and USB CAT interfaces. The radio’s CI-V interface is used with MacDoppler, and the USB interface is used with the Windows PC to connect the IC-9700’s Rx and Tx audio to the modem SW and to provide for PTT via a COM port.

We use AC power for our fixed and transportable setups.

Our portable setup uses solar power consisting of two 90-watt foldable panels, an MPPT charger system, and a pair of A123 LiPo batteries. We’ll share more about our portable and transportable setups in subsequent posts.

Software

We use the following software for our Greencube (IO-117) ground station:

• UZ7HO’s Greencube Soundmodem (download greentnc.zip)
• OZ9AAR’s Greencube Terminal Software
• DK3WN’s Greencube Telemetry Decoder
• MacDoppler to control antenna tracking and Doppler correction on the IC-9700
• N3FJP’s ACLog for logging contacts

MacDoppler runs on a Mac computer (iMac or Macbook Air), and the rest of the software runs on a Windows PC.

The links above include instructions for setting up each of the software applications. The following are some notes on Greencube (IO-117) setup for each software component.

MacDoppler

The Greencube (IO-117) setup in MacDoppler configures the IC-9700 Transceiver to operate in simplex SSB digital mode. This is the SSB-D choice in MacDoppler’s Modes tab for Greencube.

You’ll want to select SSB-D mode in MacDoppler to track Greencube and configure the IC-9700 to work with the Greencube digipeater. Setting the uplink and downlink offsets to -1.200 KHz will place Greencube’s packet transmissions in the middle of the IC-9700’s passband.

UZ7HO Soundmodem

There is a specific version of UZ7HO’s Soundmodem for use with Greencube (see the link above to download greentnc.zip). The soundcard and PTT COM port interfaces provided via the USB connection to the IC-9700 must be configured in Soundmodem.

Soundmodem Devices Settings

The USB connection from the IC-9700 to a Windows PC will create a pair of sound devices (in this example, USB Audio CODEC) and a COM port (in this example, COM15) for CAT and PTT control. These must be properly configured in the Settings – Devices choice on the Soundmodem main menu.

Soundmodem Modem Settings

The Settings – Modems choice on the Soundmodem main menu brings up this dialog. The settings are the default ones. Note that Soundmodem has two modes – GreenCube 1200bd and GreenCube 300bd. The GreenCube 1200bd setting is normally used for digipeater operation, including decoding telemetry when enabled. You’ll need to use the GreenCube 300bd setting to decode telemetry if Greencube’s digipeater is turned off.

IC-9700 Transceiver Settings

There are some important adjustments to the configuration of the IC-9700 that need to be made for Soundmodem to work properly with the transceiver.

Configuring the CI-V USB Port to Unlink from [REMOTE] is necessary to allow it to function independently for the other interfaces.

You’ll want to set the AF Output Level of the USB interface to about 25% of the maximum and adjust the Windows audio control in Control Panel to get a display on the Soundmodem waterfall of about the intensity shown above.

Setting up the Tx audio levels is important to avoid overdriving the Transmitter. A good place to start is to set the USB Mod Level in the IC-9700 to about 25%.

Then adjust the Windows audio control in Control Panel to get full transmitter output power with only one or two bars of ALC indication on the IC-9700’s ALC meter when transmitting via the Greencube Terminal client. This adjustment is an essential part of your Greencube (IO-117) setup.

OZ9ARR’s Greencube Terminal Setup

A client program is required to format and decode the packets from Greencube. We are using OZ9ARR’s Greencube Terminal for this purpose. This program includes a macro button capability to help you format Greencube Tx packets and includes some nice capabilities for logging contacts and identifying new DXCCs, Grids, and Stations that you have not yet worked.

We are using Greencube Terminal with N3FJP’s ACLog to log contacts made with Greencube. This makes it easy to export our contacts to an adif file after each Greencube operating session and import them into our main logger. We also periodically export an adif file containing all of our satellite contacts from our main logger and provide access to this file so Greencube Terminal can determine what we’ve worked before. OZ9ARR’s Greencube Terminal webpage thoroughly explains how to set up and use the program.

DK3WN’s Greencube Telemetry Decoder

Greencube periodically sends Telemetry information. You can decode it by using DK3WN’s Greencube Telemetry Decoder with Soundmodem. You can download the decoder and see how to install it on DK3WN’s webpage.

Making Contacts with Greencube

With your Greencube (IO-117) Setup complete, you should be ready to make some contacts! Begin by starting up all of the software and configuring MacDoppler to track Greencube in SSB-D mode. When Greencube is in range, you should see Greencube’s packet transmission being displayed in Soundmodem’s waterfall, and you should be able to hear the packet bursts on your Transceiver. Adjust the Soundmodem decode pointers by dragging them with your mouse to center them in the waterfall traces received in Soundmodem. The setting should be around 1400 – 1500 Hz. Also, make sure that GreenCube 1200db mode is selected in Soundmodem. You should see packets being decoded by Soundmodem.

You can configure the Shortcut buttons to handle the steps needed to make a contact. The images above show the setup of the buttons that we are using here.

You’ll want to set the Tx delay for 0 – 2 seconds to give your preamp time to recover from transmitting before you receive your digipeater packets back from Greencube.

You can begin to make a contact by either clicking on another station’s CQ to load the station’s callsign or by just calling CQ yourself. Next, use the INFO button to send your callsign and grid square and then the RRR and 73 buttons to complete your contact. When you are done, you can right-click on the last packet in the exchange or on the station’s callsign that you have worked in one of the right windows to log the contact. That’s all there is to it!

Note that you’ll want to confirm that Greencube has heard and digipeated each of your transmissions. Collisions, fading, and other effects will often cause your packets to not be digipeated, and you’ll need to repeat your transmission until it is digipeated by Greencube.

You can also use the digipeater in store-and-forward mode by setting a long TX Delay (the number is in seconds). This can be as long as several hours to allow you to have Greencube digipeat your packet on the other side of the world! Note that store and forward contacts do not count for operating awards such as Worked All States, VUCC, or DXCC.

The video above shows Uz7HO Soundmodem and OZ9AAR’s Greencube Terminal being used to make contacts during a Greencube pass. the video also demonstrates some of Greencube Terminal’s features for identifying unworked calls and grids. You’ll want to spend some time reading OZ9AAR’s webpage to learn about and take maximum advantage of the many features Greencube Terminal can provide.

More Fun With Greencube

This article is the second in a series that we are working on. You view the other articles via the links below. This is a work in progress, and we’ll be creating additional Greencube-related posts in the near future:

• Greencube (IO-117) – A New Satellite for DX!
• Greencube (IO-117) – Completing a Satellite Worked All States
• Greencube (IO-117) – M2 Antenna Systems LEO Pack – Will It Work?
• Greencube (IO-117) – A Portable Station for Activating Grid Squares
• Greencube (IO-117) – The Road to a Satellite DXCC?

You can also read more about our Satellite Ground stations here.

Fred, AB1OC

The post Greencube (IO-117) – Setup, Software, and Operation appeared first on Our HAM Station.

The Amateur Radio satellite community is fortunate to have a relatively new Medium Earth Orbit (MEO) satellite. The satellite is named Greencube or IO-117. Here’s some more information about Greencube from the S5Lab Research Team:

GreenCube is a 3U CubeSat aimed at demonstrating an autonomous biological laboratory for plants cultivation on-board a CubeSat platform. The satellite project is managed by the S5Lab research team at Sapienza University of Rome and it involves ENEA (the Italian National Agency for New Technologies, Energy and Sustainable Economic Development) and University of Naples “Federico II”. The project is coordinated by the Italian Space Agency (ASI) and it has benefitted of a launch opportunity offered by the European Space Agency. The spacecraft has been launched on-board the maiden Vega-C flight on 13 July 2022 and it has been deployed in Medium Earth Orbit (MEO) at approximately 5800 km of altitude. GreenCube is carrying microgreens (brassicacae) seeds for the farthest experiment ever of plants cultivation in microgravity.

Amateur Radio Payload

In addition to its scientific payload, Green carries an Amateur Radio digipeater that operates on the 70 cm band. The Digipeater operates in both real-time and store and forward modes.

The satellite’s MEO orbit provides passes lasting as long as 90 minutes and some great DX contact opportunities for Amateur Radio satellite operators. The image above shows a typical Greencube pass in the Northeastern US. The tracking program is MacDoppler, and the red arc shows the area on the ground that we can contact. This pass provides DX contacts to China, Asia, Hawaii, Alaska, the US, and Mexico. We can also reach much of Europe, the Middle East, Africa, and South and Central America via Greencube.

To date, I have made about 320 contacts using Greencube, including DX contacts to Japan, China, Hawaii, Central and South America, the Caribbean, Europe, the Middle East, Africa, and many stations in the US.

Operating with Greencube – What’s Required

Greencube requires the following for successful contacts via its digipeater:

• A directional antenna with at least 12 dBi gain
• A 70cm SSB/FM capable Transceiver with a soundcard interface and at least 25 watts of output at the antenna
• Software to control the Transceiver to correct for Doppler shift and provide antenna tracking control or pointing information
• A computer running modem software and a Greencube Client Program
• A low-noise preamp at the antenna is recommended

The ground station at our QTH more than meets these requirements.

We are also testing our Transportable LEO Pack-based station with Greencube, and we’ll have more on the results from these tests soon.

More to Come

I am planning a series of articles covering setup and operations with Greencube in hopes that other Amateur Radio satellite operators might take advantage of this bird:

• Greencube (IO-117) – Station Setup, Software, and Operation
• Greencube (IO-117) – Completing a Satellite Worked All States
• Greencube (IO-117) – M2 Antenna Systems LEO Pack – Will It Work?
• Greencube (IO-117) – A Portable Station for Activating Grid Squares
• Greencube (IO-117) – The Road to a Satellite DXCC?

You can read more about our Satellite Ground stations here.

Fred, AB1OC

The post Greencube (IO-117) – A New Satellite for DX! appeared first on Our HAM Station.