SDR PHY » History » Revision 24
Revision 23 (fixeria, 08/09/2018 08:00 PM) → Revision 24/32 (fixeria, 08/09/2018 08:03 PM)
h1. SDR (Software Defined Radio) hardware {{>toc}} Unlike the obsolete [[Phones|Calypso based phones]], "SDR (Software Defined Radio)":https://en.wikipedia.org/wiki/Software-defined_radio has many advantages, providing much more freedom for the implementation of mobile side [[Software|GSM protocol stack]]. This page describes all steps required for running the higher layer (L2&3) applications (e.g. [[mobile]] or [[ccch_scan]]) on SDR hardware. h2. SDR PHY vs Calypso h3. What's so special about SDR? * General purpose hardware ** i.e. not limited to any particular technology and/or protocol stack, ** could be used as PHY for GSM, LTE, IEE802.11, GPS, Bluetooth, etc. * Becomes cheap and available for everyone ** e.g. RTL-SDR, LimeSDR-Mini * Becomes even smaller than a credit card ** e.g. XTRX * Open Source friendly ** GNU Radio, GQRX, OpenBTS, OsmoTRX, srsLTE, etc. ** some drivers, firmware and PCB schematics are available h3. Advantages over Calypso * No need to rely on a 'black box' DSP * No hardware availability problem * No reverse engineering required * No freq. band limitations h3. Disadvantages * Low output power * General purpose hardware ** No screen, no keyboard, ** No built-in SIM reader, ** No built-in audio ** etc. h3. What is it for? * Another hardware platform for [[OsmocomBB]] * 100% Open Source GSM L1 implementation ** GSM TS 05.02 scheduling ** GSM TS 05.03 channel coding ** GSM TS 05.04 (de)modulation ** GSM TS 05.10 synchronization h2. Supported SDR hardware At the moment, only USRP hardware is supported via UHD driver. This limitation caused by the requirement of RX / TX time tags persistence. We are currently working on adding support of RX / TX time tags to both Osmocom SDR Source and Sink... The current implementation is known to work on the following devices: * USRP B2X0, including 'mini' * Fairwaves [[UmTRX:]] h2. Software installation !graph_trxcon.png! The signal processing part is based on [[GR-GSM:]] (https://github.com/ptrkrysik/gr-gsm) project, which is represented by a set of "GNU Radio":https://www.gnuradio.org/ blocks for GSM. So, first of all you need to install "GNU Radio":https://www.gnuradio.org/ with compiled-in "UHD driver":http://files.ettus.com/manual/ support. h3. 1. "UHD driver":http://files.ettus.com/manual/ Follow the "Installing and/or Building UHD" section of official project documentation. After the installation, make sure that your device is recognized properly: <pre> $ uhd_find_devices $ uhd_usrp_probe </pre> h3. 2. "GNU Radio":https://www.gnuradio.org/ Despite "GNU Radio":https://www.gnuradio.org/ is available as a binary package on some distributions, we recommend to build the latest release version from source. Please follow the corresponding "building guide":https://wiki.gnuradio.org/index.php/BuildGuide. During the build configuration process, make sure you have the following components: * python-support * gr-digital * gr-filter * gr-blocks * gr-uhd For binary or already installed builds, use the following command to get build info: <pre> $ gnuradio-config-info --enabled-components </pre> h3. 3. [[GR-GSM:]] with transceiver !graph_trx.png! For now, the transmitter implementation lives in separate branches. This manual compilation from source is required. "General building process":https://github.com/ptrkrysik/gr-gsm/wiki/Manual-compilation-and-installation and dependences are described in the "project's wiki":https://github.com/ptrkrysik/gr-gsm/wiki/. <pre> # Get the source code $ git clone git://git.osmocom.org/gr-gsm $ cd gr-gsm/ $ git checkout fixeria/trx # Configure and compile $ mkdir build $ cd build $ cmake .. $ make # Install $ sudo make install $ sudo ldconfig </pre> The transceiver logic is represented by the following flow graph: !grc_trx.png! h3. 4. [[OsmocomBB:]] You need to compile OsmocomBB with the [[TRX_Interface|TRX interface]] support. Please refer the corresponding [[TRX_Interface|wiki page]]. h2. Running First of all, please see [[SDR_PHY#Project-status|known limitations]]. h3. Hardware preparation You need to have two antennas connected: one for RX, another for TX. Both antennas should be chosen for a proper frequency band, otherwise the distance will be limited. Also, it's strongly recommended to use a band-pass filter for TX in order to *avoid interference*. _Note: There is a bug of USRP B2X0 hardware, which affects the burst transmission quality. It appears when both transmission and reception are performed of the same side of device. To mitigate this, please use an attenuator or antenna with some resistance between the active pin and ground._ Finally, connect your SDR hardware and make sure it's working. h3. Transceiver Check available configuration options: <pre> $ grgsm_trx --help ... TRX interface specific -i --remote-addr Set remote address (default 127.0.0.1) -p --base-port Set base port number (default 5700) Radio interface specific -a --device-args Set device arguments -s --sample-rate Set sample rate -g --rx-gain Set RX gain (default 30) -G --tx-gain Set TX gain (default 10) --rx-antenna Set RX antenna (default RX2) --tx-antenna Set TX antenna (default TX/RX) --ppm Set frequency correction (default 0) </pre> If you already have another transceiver runing, e.g. [[OsmoTRX:]], choose a different TRX base port. Keep in mind that a single transceiver process occupies six UDP ports at the same time. Choose proper RX / TX antennas and corresponding gain values depending on your device. TX gain requires more attention and should be set depending on your environment and antennas used. Feel free to use a spectrum browser, such as GQRX or osmocom_fft, for measuring the proper values. PPM value is typically measured at runtime, so no need to specify it manually. <pre> $ grgsm_trx --rx-gain 30 --tx-gain 80 linux; GNU C++ version 4.8.5; Boost_105500; UHD_003.010.002.000-0-122bfae1 License GPLv2+: GNU GPL version 2 or later <http://gnu.org/licenses/gpl.html> This is free software: you are free to change and redistribute it. There is NO WARRANTY, to the extent permitted by law. [i] Init Radio interface -- Detected Device: B200 -- Operating over USB 3. -- Initialize CODEC control... -- Initialize Radio control... -- Performing register loopback test... pass -- Performing CODEC loopback test... pass -- Setting master clock rate selection to 'automatic'. -- Asking for clock rate 16.000000 MHz... -- Actually got clock rate 16.000000 MHz. -- Performing timer loopback test... pass -- Setting master clock rate selection to 'manual'. -- Asking for clock rate 26.000000 MHz... -- Actually got clock rate 26.000000 MHz. -- Performing timer loopback test... pass -- Asking for clock rate 26.000000 MHz... OK [i] Init CTRL interface [i] Init complete </pre> At this step transceiver is ready. h3. The trxcon application As we don't use Calypso-based phones, the [[osmocon]] application is useless here. Instead, you need to run another application called trxcon. You should use the same TRX base port as specified to transceiver. <pre> $ cd osmocom-bb/src/ $ host/trxcon/trxcon License GPLv2+: GNU GPL version 2 or later <http://gnu.org/licenses/gpl.html> This is free software: you are free to change and redistribute it. There is NO WARRANTY, to the extent permitted by law. <0001> l1ctl_link.c:235 Init L1CTL link (/tmp/osmocom_l2) <0003> trx_if.c:646 Init transceiver interface <0005> sched_trx.c:112 Init scheduler <0000> trxcon.c:277 Init complete </pre> See help details. h3. L2&3 applications At this step you should be able to run the higher layer applications. For example, run [[ccch_scan]]: <pre> $ cd osmocom-bb/src/ $ cd host/layer23/src/misc/ $ ./ccch_scan -i 127.0.0.1 -a <ARFCN> </pre> It should synchronize with a BTS on specified ARFCN, and start decoding BCCH messages. h2. Docker images It's possible to run the software in Docker containers. This way is recommended for beginners. _Note:_ at the moment, there is a build script for GR-GSM TRX only. The build script for [[GR-GSM:]] (i.e. Dockerfile) is shipped as a part of a separate project called "docker-playground". It's based on "base/archlinux" image, which provides the recent versions of both UHD and GNU Radio without tons of dependencies such as Xorg, GTK, fonts, etc. h3. Building Docker image You need to clone the "docker-playground" repository first: <pre> $ git clone git://git.osmocom.org/docker-playground/ </pre> Then make sure you have stable Internet connection and enough disk space, and start building: <pre> $ cd docker-playground/ $ cd gr-gsm-master/ $ make build </pre> It will take a while... As soon as the building process is finished, you should see the new images: <pre> $ docker image ls REPOSITORY TAG IMAGE ID CREATED SIZE user/gr-gsm-master latest c5912ee7d6ae About an hour ago 2.09GB base/archlinux latest 7477438791e3 28 hours ago 689MB </pre> Please note that *this container requires privileged access* to the host USB devices (USRPs). h3. Running Docker image Read the above part about running first. As soon as you build the image, feel free to start it: <pre> $ cd docker-playground/ $ cd gr-gsm-master/ $ make run </pre> The last command will drop you into a bash shell. As there are no build scripts for the higher layer applications of [[OsmocomBB:]], the following part assumes that you are running [[OsmocomBB:]] on the host side. By default, Docker should create a network interface for interacting with containers: <pre> $ ip addr # ... 5: docker0: <NO-CARRIER,BROADCAST,MULTICAST,UP> mtu 1500 qdisc noqueue state DOWN group default link/ether 02:42:13:85:c2:c9 brd ff:ff:ff:ff:ff:ff inet 172.17.0.1/16 scope global docker0 valid_lft forever preferred_lft forever </pre> In this example, the host has 172.17.0.1 assigned. Remember this address. _Note:_ make sure your firewall doesn't block the connections with Docker's interface. The container itself should also have it's own address. You can check it: <pre> [root@f7e86148c1c2 tmp]# pacman -S net-tools [root@f7e86148c1c2 tmp]# ifconfig eth0: flags=4163<UP,BROADCAST,RUNNING,MULTICAST> mtu 1500 inet 172.17.0.2 netmask 255.255.0.0 broadcast 0.0.0.0 ether 02:42:ac:11:00:02 txqueuelen 0 (Ethernet) RX packets 40 bytes 139097 (135.8 KiB) RX errors 0 dropped 0 overruns 0 frame 0 TX packets 32 bytes 2752 (2.6 KiB) TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0 lo: flags=73<UP,LOOPBACK,RUNNING> mtu 65536 inet 127.0.0.1 netmask 255.0.0.0 loop txqueuelen 1 (Local Loopback) RX packets 0 bytes 0 (0.0 B) RX errors 0 dropped 0 overruns 0 frame 0 TX packets 0 bytes 0 (0.0 B) TX errors 0 dropped 0 overruns 0 carrier 0 collisions 0 </pre> Now, make sure your hardware is available within the container: <pre> [root@f7e86148c1c2 tmp]# uhd_find_devices # Device list will appear here </pre> And finally, start the transceiver: <pre> # You need to use IP address of the host [root@f7e86148c1c2 tmp]# grgsm_trx --remote-addr 172.17.0.1 </pre> and trxcon on the host side: <pre> $ cd osmocom-bb/src/host/trxcon/trxcon/ # You need to use IP address of the host $ ./trxcon --trx-ip 172.17.0.2 </pre> That's it! h2. Related pages * [[TRX Interface]] {{child_pages(TRX_Interface)}} h2. Project status Known limitations (not implemented): * Automatic PHY delay measurement * AGC (Automatic Gain Control) * Power measurement Work in progress: * Docker scripts (Dockerfiles) * GAPK based audio back-end * TCH/H implementation * Frequency Hopping Future plans: * Extend supported hardware list (Soapy?) * PC/SC physical SIM interface * AMR (Adaptive Multi-Rate) h2. Further reading / watching https://media.ccc.de/v/34c3-8952-running_gsm_mobile_phone_on_sdr https://www.youtube.com/watch?v=nmqzr2-yF04