User:Muaddib: Difference between revisions
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Remote Spectrum Monitoring Example using Hardware | Remote Spectrum Monitoring Example using Hardware | ||
This portion of the tutorial uses two open source projects that implement the concepts shown above to provide wideband remote spectrum monitoring over a low data rate IP connection. | |||
This tutorial assumes you have one of the following Software Defined Radios: | |||
Ettus Research USRP | *Ettus Research USRP | ||
*This tutorial can be run from the same computer, but is intended to be used on two separate machines. | *Lime Micro LimeSDR | ||
*RTL-SDR | |||
This tutorial can be run from the same computer, but is intended to be used on two separate machines. | |||
Both machines require GNURadio 3.9+ and the proper driver for the radio. In the case of the USRP, UHD is required. For either the LimeSDR or the RTLSDR, GNURadio 3.9+ includes SoapySDR drivers for both. | Both machines require GNURadio 3.9+ and the proper driver for the radio. In the case of the USRP, UHD is required. For either the LimeSDR or the RTLSDR, GNURadio 3.9+ includes SoapySDR drivers for both. | ||
Clone the following two repositories on the remote host: | |||
*https://github.com:muaddib1984/stillsuit | |||
*https://github.com:muaddib1984/arrakis | |||
Clone only the arrakis repository on the local host: | |||
* | *https://github.com:muaddib1984/arrakis | ||
REMOTE HOST | |||
*Attach one of the SDR's listed above to your remote host. Ensure your radio is connected to the host by running either: | |||
<br><code>uhd_find_devices</code> for USRP | |||
<br><code>SoapyUTILS --find</code> for LimeSDR/RTLSDR | |||
From your local host, open an SSH tunnel with IP Forwarding to the remote host: | From your local host, open an SSH tunnel with IP Forwarding to the remote host: | ||
<br><code>ssh -L 5001:localhost:5001 -L 8001:localhost:8001 -L 8000:localhost:8000 <username>@<hostname|IP Address></code> | <br><code>ssh -L 5001:localhost:5001 -L 8001:localhost:8001 -L 8000:localhost:8000 <username>@<hostname|IP Address></code> | ||
Now you are connected via SSH to the remote terminal. | Now you are connected via SSH to the remote terminal. | ||
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If you prefer to have two terminals, you can open a second SSH session, but leave off the '-L' arguments since we already have the ports forwarded in the first shell. | If you prefer to have two terminals, you can open a second SSH session, but leave off the '-L' arguments since we already have the ports forwarded in the first shell. | ||
With two terminals, you can also omit the "&" in the previous command. | With two terminals, you can also omit the "&" in the previous command. | ||
Whether in one or two terminal windows run: | Whether in one or two terminal windows run: | ||
<br><code>cd path/to/arakkis</code> | <br><code>cd path/to/arakkis</code> | ||
<br><code>space_folder.py</code> (note: If you are using an RTLSDR, pass the -s argument to space_folder.py with a value of 2.5e6 like this | <br><code>space_folder.py</code> (note: If you are using an RTLSDR, pass the -s argument to space_folder.py with a value of 2.5e6 like this <code>space_folder.py -s 2.5e6</code>) | ||
Revision as of 08:58, 27 November 2021
Understanding XMLRPC Blocks
This tutorial presents the GNU Radio XMLRPC blocks. There are two blocks in this collection: XMLRPC Client and XMLRPC Server. Both blocks have IP address/port fields while the Client block also has callback and variable fields. The blocks use the Python XMLRPC module and use a subset of the full XMLRPC spec.
XMLRPC is an XML-based Remote Protocol Control mechanism that does just that. It uses HTTP transport and allows a client to use SET commands to change parameters on a server or use GET commands to obtain the value of parameters on the server.
To understand better how GNURadio implements XMLRPC, look at the block documentation linked in the paragraph above.
To understand the XMLRPC protocol and Python implementation in detail, the reference links below are a good starting point.
Reference Links
https://docs.python.org/3.8/library/xmlrpc.html
Prerequisites
Introduction: What does XMLRPC do in GNURadio and Why Should I Care?
WHAT: In GNURadio placing the XMLRPC Server block in a flowgraph will create an XMLRPC server that exposes all the variables in the flowgraph on the specified IP Address and Port. This allows a client to change them at runtime. The XMLRPC Client block allows the user to create a flowgraph that can control any of the parameters in a flowgraph that has the XMLRPC Server block.
WHY: In many cases, we want to adjust the variables of a GNURadio flowgraph at runtime. We usually do this by adding QT GUI Widget block (range, push button, etc). But what if you want to have the same control interface, but in a different flowgraph? XMLRPC will allow you to control all of a flowgraph's variables from a second flowgraph using HTTP. In fact, the second flowgraph doesn't even have to be on the same computer! Therefore, XMLRPC can be used to add runtime control of any flowgraph running on a remote system like a Raspberry PI, headless server or otherwise.
Contents of Tutorial
GNURadio XMLRPC Examples
- We will start with running the basic client/server example flowgraphs from the GNU Radio source tree (gr-blocks/examples/xmlrpc).
GNURadio XMLRPC Examples with added ZMQ Streaming Data Visualization
- Here we will modify the examples to include ZMQ streaming so we can visualize the remote flowgraph's datastream in our XMLRPC Client flowgraph.
GNURadio XMLRPC Remote Control Over IP Network
- Next, we will run the server/client pair over an IP network using 2 separate computers. (Requires 2 hosts on the same network with GNURadio 3.9+ installed)
GNURadio XMLRPC Advanced Usage Example
- (OPTIONAL) As a bonus step we will run a project that implements a remote, headless wideband RF receiver and stream the data to a Remote Controller for control and visualization.
GNURadio XMLRPC Examples
Open the siggen_xmlrpc_server.grc flowgraph.
Shown here:
Open the siggen_controller_xmlrpc_client.grc flowgraph
Shown here:
First, Run the Siggen Server Flowgraph
Your GUI window should look like this:
Next, run the Siggen Controller flowgraph
Your GUI window should look like this:
<controller.jpg>
Arrange both GUI windows so you can see them at the same time.
In the Siggen Controller Flowgraph Move the Frequency Slider slightly to the left and observe the Siggen Server time/frequency display. You should see the frequency changing as shown here:
That's it, you've just remote controlled a flowgraph over a network socket!
Close both GUI windows and continue to the next tutorial.
GNURadio XMLRPC Examples with ZMQ Streaming Data Visualization
Make sure you are familiar with ZMQ streaming from the ZMQ tutorials.
- Create a copy ('save as') of both XMLRPC example flowgraphs and name them:
"siggen_xmlrpc_server_streaming.grc" "siggen_controller_xmlrpc_client_streaming.grc"
(don't forget to change the names in the 'ID' of the 'Options' block to match the new .grc filenames)
- In the Streaming Server Flowgraph, copy the throttle and GUI display blocks, then paste them into the Streaming Controller flowgraph.
- Now delete the GUI blocks from the Server Flowgraph and add a ZMQ Pub Sink block. Connect the output of the 'Throttle' block to the input of the ZMQ Pub Sink where the GUI blocks used to be connected.
ZMQ PUB SINK PARAMETERS: 'Address': tcp://127.0.0.1:5000 'Pass Tags': 'Yes' All others default
- Change the 'Generate Options' in the Server flowgraph to 'No GUI'. This will allow us to run the flowgraph on our localhost or a remote host as a 'headless' flowgraph.
- In the Streaming Client flowgraph.
Change the sample rate to match the Streaming Server Flowgraph (32ksps)
Add a ZMQ Sub Source block to the flowgraph and connect it to the input port of both the 'QT GUI Time Sink' and 'QT GUI Frequency Sink' GUI blocks.
ZMQ SUB SOURCE PARAMETERS: 'Address': tcp://127.0.0.1:5000 'Pass Tags': 'Yes' All others default
- RUN IT!
From GRC: Click the run button on the 'siggen_xmlrpc_server_streaming' flowgraph. A blank terminal window will open (don't worry its doing it's job).
Click the run button on the 'siggen_xmlrpc_controller_client_streaming' flowgraph. A GUI window will open with the same time/frequency display as before, but in the same graph with the GUI Range 'frequency' slider.
In the Controller GUI: Adjust the slider as before and observe the frequency changing.
You are now both remote controlling and viewing streaming data over a network connection!
GNURadio XMLRPC Remote Control Over IP Network
- Extending this example to two hosts using one of two methods.
Assume our Streaming Server machine is Host A and our Streaming Client machine is Host B.
NOTE: These tutorials are focused on functionality not security. Understanding of the IP mechanisms used in this tutorial fall on the user. Know your network!
- METHOD 1
Changing the IP Addresses in both flowgraphs:
- Streaming Server Flowgraph (Host A)
ZMQ Pub Sink Address <IP Address of Host B -OR- '0.0.0.0'>
XMLRPC Server <IP Address of Host A -OR- '0.0.0.0'>
- Streaming Client Flowgraph (Host B)
ZMQ Sub Source Address <IP Address of host A>
XMLRPC Client Block (frequency) Address <IP Address of host A>
- METHOD 2
SSH Port Forwarding (more information can be found here Using SSH Port Forwarding, a user can keep everything the same in the flowgraphs. We are using port 8000 for XMLRPC and Port 5000 for our ZMQ Streaming Data. Simply run the following command from Host B:
ssh -L 8000:localhost:8000 -L 5000:localhost:5000 <username>@<IP Address of Host A>
This SSH command effectively shares any traffic on ports 8000 and 5000 between the two hosts.
GNURadio XMLRPC Advanced Usage Example
Remote Spectrum Monitoring Example using Hardware
This portion of the tutorial uses two open source projects that implement the concepts shown above to provide wideband remote spectrum monitoring over a low data rate IP connection.
This tutorial assumes you have one of the following Software Defined Radios:
- Ettus Research USRP
- Lime Micro LimeSDR
- RTL-SDR
This tutorial can be run from the same computer, but is intended to be used on two separate machines. Both machines require GNURadio 3.9+ and the proper driver for the radio. In the case of the USRP, UHD is required. For either the LimeSDR or the RTLSDR, GNURadio 3.9+ includes SoapySDR drivers for both.
Clone the following two repositories on the remote host:
Clone only the arrakis repository on the local host:
REMOTE HOST
- Attach one of the SDR's listed above to your remote host. Ensure your radio is connected to the host by running either:
uhd_find_devices
for USRP
SoapyUTILS --find
for LimeSDR/RTLSDR
From your local host, open an SSH tunnel with IP Forwarding to the remote host:
ssh -L 5001:localhost:5001 -L 8001:localhost:8001 -L 8000:localhost:8000 <username>@<hostname|IP Address>
Now you are connected via SSH to the remote terminal.
If you prefer to have only one terminal window open, from the SSH terminal, run:
cd path/to/stillsuit
./<uhd|lime|rtl>_stillsuit.py &
(this will allow you to run the second application from the same terminal)
If you prefer to have two terminals, you can open a second SSH session, but leave off the '-L' arguments since we already have the ports forwarded in the first shell.
With two terminals, you can also omit the "&" in the previous command.
Whether in one or two terminal windows run:
cd path/to/arakkis
space_folder.py
(note: If you are using an RTLSDR, pass the -s argument to space_folder.py with a value of 2.5e6 like this space_folder.py -s 2.5e6
)
- LOCAL HOST
Now open a terminal window on your local machine and run:
cd path/to/arrakis
./guild_navigator.py
(note: If you are using an RTLSDR, pass the -s argument to guild_navigator.py with a value of 2.5e6 like this guild_navigator.py -s 2.5e6
)
You should see a frequency plot updating at a fairly slow rate. -To make the frequency plot update faster, change the vectors per second dropdown menu to 8. -To make the spectrum more stable visually, change the 'Average/Raw' dropdown to 'AVERAGED'. -If using a USRP/Lime, you can adjust the sampling rate to 40MHz (performance will be dependent on your remote host's processing power.) -Finally, tune the frequency to 98000000.0 Hz in the frequency window (FM Radio).
Your plot should look something like this: