[[Include(WikiToC)]]

== GNURadio OFDM tutorial ==

=== Description ===

This tutorial illustrates the use of GNURadio OFDM blocks for data transfer between a pair of USRPs. The GNURadio flowgraphs used here were obtained from the workshop material provided for [https://gitlab.flux.utah.edu/powderrenewpublic/mww2019 POWDER-RENEW Mobile and Wireless Week 2019]. They are mainly based on the GRC examples available in the [https://github.com/gnuradio/gnuradio/tree/main/gr-digital/examples/ofdm GNURadio repository]. For a good understanding of the flowgraphs and the blocks, please refer to OFDM pages on GNURadio Wiki such as [https://wiki.gnuradio.org/index.php/Basic_OFDM_Tutorial OFDM Basics] and [https://wiki.gnuradio.org/index.php/Schmidl_%26_Cox_OFDM_synch. OFDM Synchronization]


=== Prerequisites ===
In order to access the test bed, create a reservation and have it approved by the reservation service. Access to the resources is granted after the reservation is confirmed. Please follow the process shown on the COSMOS [wiki:GettingStarted getting started] page to get started. 

=== Resources required ===
A pair of USRPs in COSMOS or ORBIT testbed. 
- 2 USRP X310s (connected to node1-1,node1-2) in sb2.orbit-lab.org  or
- 2 USRP 2974s (sdr2-s1-lg1,sdr1-md1) in sb1.cosmos-lab.org

=== Tutorial Setup ===

Follow the steps below to gain access to the [wiki:/hardware/Domains/sb1 sandbox 1 console] and set up nodes with appropriate images. 
 1. If you don't have one already, sign up for a [https://www.cosmos-lab.org/portal-2/ COSMOS account]
 1. [wiki:/GettingStarted#MakeaReservation Create a resource reservation] on sandbox 1
 1. [wiki:/GettingStarted#LogintoyourReservation Login] into sandbox 1 console (console.sb1.cosmos-lab.org) with an SSH session. SSH session for COSMOS SB1 with MobaXterm can be setup as shown, with remote host = console.sb1.cosmos-lab.org, and username = your COSMOS username. X11 forwarding is enabled to access GUI.
[[Image(mobaxterm_sb1_session.JPG, width=600px)]]
 1. Make sure all the nodes and devices used in the experiment are turned off:
{{{#!shell
omf tell -a offh -t system:topo:all  
}}}
 1. Load gnuradio_ofdm.ndz on both the nodes 
{{{#!shell
omf load -i gnuradio_ofdm.ndz -t node1-1,node1-2
}}}
 1. Turn the nodes on and check the status
{{{#!shell
omf tell -a on -t node1-1,node1-2
}}}
{{{#!shell
omf stat -t all
}}}
 1. Open 2 terminal sessions and ssh into the nodes with -Y for X11 forwarding
{{{#!shell
ssh root@node1-1 -Y
ssh root@node1-2 -Y
}}}


=== Experiment Execution ===

==== Find the USRPs ====
1. As mentioned in the [https://orbit-lab.org/wiki/Hardware/bDomains/cSandboxes/bSB2 sb2.orbit] page, the X310s have their port 1 directly connected to their respective nodes, and the IP addresses hardcoded to 192.168.40.2 as given in the [https://files.ettus.com/manual/page_usrp_x3x0.html#x3x0_setup_network X310 manual]. To access the X310s run eth_config_sb2_orbit.sh on both the nodes. It sets a static IP address 192.168.40.1 on eno2 interface, and modifies the maximum send and receive socket buffer sizes.
{{{#!shell
root@node1-2:~# ./eth_config_sb2_orbit.sh
net.core.wmem_max = 25000000
net.core.rmem_max = 25000000
root@node1-2:~# ip addr show DATA2
4: DATA2: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 9000 qdisc mq state UP group default qlen 1000
    link/ether f4:52:14:83:af:80 brd ff:ff:ff:ff:ff:ff
    inet 192.168.40.1/24 scope global DATA2
       valid_lft forever preferred_lft forever
    inet6 fe80::f652:14ff:fe83:af80/64 scope link
       valid_lft forever preferred_lft forever
}}}
2. Run uhd_find_devices and uhd_usrp_probe to detect the X310s and to make sure they have a compatible firmware installed.
{{{#!shell
root@node1-2:~# uhd_find_devices
[INFO] [UHD] linux; GNU C++ version 9.4.0; Boost_107100; UHD_4.4.0.0-0ubuntu1~focal1
--------------------------------------------------
-- UHD Device 0
--------------------------------------------------
Device Address:
    serial: 30F10F9
    addr: 192.168.40.2
    fpga: XG
    name:
    product: X310
    type: x300

root@node1-2:~# uhd_usrp_probe --args="addr=192.168.40.2"
[INFO] [UHD] linux; GNU C++ version 9.4.0; Boost_107100; UHD_4.4.0.0-0ubuntu1~focal1
[INFO] [X300] X300 initialization sequence...
[INFO] [X300] Maximum frame size: 8000 bytes.
[INFO] [GPS] No GPSDO found
[INFO] [X300] Radio 1x clock: 200 MHz
  _____________________________________________________
 /
|       Device: X-Series Device
|     _____________________________________________________
|    /
|   |       Mboard: X310
|   |   revision: 8
|   |   revision_compat: 7
|   |   product: 30818
|   |   mac-addr0: 00:80:2f:27:0d:51
|   |   mac-addr1: 00:80:2f:27:0d:52
|   |   gateway: 192.168.10.1
|   |   ip-addr0: 192.168.10.2
|   |   subnet0: 255.255.255.0
|   |   ip-addr1: 192.168.20.2
|   |   subnet1: 255.255.255.0
|   |   ip-addr2: 192.168.30.2
|   |   subnet2: 255.255.255.0
|   |   ip-addr3: 192.168.40.2
|   |   subnet3: 255.255.255.0
|   |   serial: 30F10F9
.
.
.
.
|   |    /
|   |   |       RX Frontend: 0
|   |   |   Name: UBX RX
|   |   |   Antennas: TX/RX, RX2, CAL
|   |   |   Sensors: lo_locked
|   |   |   Freq range: 10.000 to 6000.000 MHz
|   |   |   Gain range PGA0: 0.0 to 31.5 step 0.5 dB
|   |   |   Bandwidth range: 160000000.0 to 160000000.0 step 0.0 Hz
|   |   |   Connection Type: IQ
|   |   |   Uses LO offset: No


}}}
3. In case of firmware mismatch, follow the directions displayed in the error message and use uhd_image_loader to update the firmware.

==== Run the GRC application ====
1. Start the OFDM receiver on node1-2
{{{#!shell
gnuradio-companion  
}}}

{{{#!shell
root@sdr2-s1-lg1:~# gnuradio-companion  /root/gr-ettus/examples/rfnoc/rfnoc_fosphor.grc
<<< Welcome to GNU Radio Companion 3.7.14.0 >>>

Block paths:
        /usr/local/share/gnuradio/grc/blocks

Loading: "/root/gr-ettus/examples/rfnoc/rfnoc_fosphor.grc"
>>> Done
}}}

With X11 forwarding enabled, GRC should show up as below. 

[[Image(TX_OFDM_grc.png, width=800px)]]

2. Run the OFDM transmitter on node1-1
{{{#!shell
}}}
[[Image(TX_OFDM_grc.png, width=800px)]]

3. Make sure the device arguments on both nodes are correctly set as shown below. Check the center frequencies and sample rates, and make sure they match. TX_OFDM.grc has a "File Source" block which reads the text file to be transmitted. RX_OFDM.grc stores the received data in a local file that is specified in the "File Sink" block.  
[[Image(TX_OFDM_grc.png, width=800px)]]

4. Run the receive flowgraph followed by the transmit flowgraph.