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= IBM 28GHz PAAM: Link Rate vs. SNR  =

=== Description ===
In this tutorial, we demonstrate the example use case of MAMBAS, a novel system that maneuvers analog MUBF using an ASA to support simultaneous communication with multiple users located in close proximity using the 28 GHz IBM PAAM board. 

* The instructions for the MAMBAS can be found [https://github.com/functions-lab/MAMBAS-MobiCom2024 here]
The following papers describe the integration of the IBM 28 GHz PAAMs with MAMBAS in the COSMOS testbed. We would appreciate it if you cite this paper when publishing results obtained using the PAAMs deployed in COSMOS.

* Z. Gao, Z. Qi, and T. Chen, "Mambas: Maneuvering Analog Multi-User Beamforming using an Array of Subarrays in mmWave Networks". in Proc. ACM MobiCom'24, 2023
* Z. Qi, Z. Gao, C. Tung, and T. Chen, "Programmable Millimeter-Wave MIMO Radios with Real-Time Baseband Processing". in Proc. ACM MobiCom'23 Workshop on Wireless Network Testbeds, Experimental evaluation & Characterization (WiNTECH '23), 2023

Authors: \\
Zhihui Gao, Duke University <zhihui.gao[at]duke[dot]edu> \\
Zhenzhou (Tom) Qi, Duke University <zhenzhou.qi[at]duke[dot]edu> \\
Tingjun Chen, Duke University <tingjun.chen[at]duke[dot]edu>

Last updated: Mar. 21, 2024



=== Prerequisites ===

In order to access COSMOS-SB2, create a reservation in COSMOS testbed 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 getting [https://wiki.cosmos-lab.org/wiki/GettingStarted started page] to get started.

=== Resources Required ===

* 2 USRP N310 SDRs ({{{sdr1-s1-lg1}}} and {{{sdr1-md1}}} in SB2)
* 2 IBM 28GHz PAAMs ({{{rfdev2-1}}} and {{{rfdev2-2}}} in SB2 )
* 1 Server ({{{srv1-lg1}}})

The current hardware connection in SB2 as shown below
* {{{sdr1-s1-lg1}}} RF2 TX/RX -- {{{rfdev2-1}}} IC0/TX/H, {{{sdr1-s1-lg1}}} RF2 RX2 -- {{{rfdev2-1}}} IC1/RX/H
* {{{sdr1-s1-lg1}}} RF3 TX/RX -- {{{rfdev2-1}}} IC0/TX/V, {{{sdr1-s1-lg1}}} RF3 RX2 -- {{{rfdev2-1}}} IC1/RX/V
* {{{sdr1-md1}}} RF2 TX/RX -- {{{rfdev2-2}}} IC0/TX/H, {{{sdr1-md1}}} RF2 RX2 -- {{{rfdev2-2}}} IC1/RX/H
* {{{sdr1-md1}}} RF3 TX/RX -- {{{rfdev2-2}}} IC0/TX/V, {{{sdr1-md1}}} RF2 RX2 -- {{{rfdev2-2}}} IC1/RX/V

|| [[Image(PAAM-2_2 .png, 600px)]] ||

The required software components used in this demo are already loaded to the {{{MobiCom24-MAMBAS.ndz}}} node image, the node image includes:
* Ubuntu 20.04, UHD 4.1.0
* PAAM Control to initialize the PAAM boards to integrate with USRPs. 
* MAMBAS.Please refer to **{{{main}}} branch** at [https://github.com/functions-lab/MAMBAS-MobiCom2024.git here] for more information.

=== Tutorial Setup ===

Follow the steps below to gain access to the sandbox 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 COSMOS SB2
 1. [Documentation/Short/Login Login] into sandbox console {{{console.sb2.cosmos-lab.org}}}) with **four** SSH sessions. 
 1. In **terminal 1**, make sure all the nodes and devices used in the experiment are turned off. Use the following command for SB2
    {{{#!shell
    omf tell -a offh -t sdr1-s1-lg1,sdr1-md1,rfdev2-1,rfdev2-2,srv1-lg1
    }}}
 1. Load {{{MobiCom24-MAMBAS.ndz}}} on the server.  
    {{{#!shell
    omf load -i MobiCom24-MAMBAS.ndz -t srv1-lg1 -r 0
    }}}
 1. Turn all the required resources on and check the status of all the resources. Use the following commands for SB2.
    {{{#!shell
    omf tell -a on -t sdr1-s1-lg1,sdr1-md1,rfdev2-1,rfdev2-2,srv1-lg1
    }}}
    {{{#!shell
    omf stat -t all
    }}}
 1. {{{ssh}}} to the server with option -X for using GUI for our live demo. 
    {{{#!shell
    ssh -X root@srv1-lg1
    }}}

==== Find and prepare USRPs  ====
* Upon logging into the server, set up the 10G data interfaces DATA1, DATA2 in **terminal 1**. 
    {{{#!shell
    ifconfig DATA1 10.117.1.1 netmask 255.255.0.0 mtu 9000 up
    ifconfig DATA2 10.118.1.1 netmask 255.255.0.0 mtu 9000 up
    }}}
    {{{#!shell
    sudo sysctl -w net.core.rmem_max=536870912
    sudo sysctl -w net.core.wmem_max=536870912
    }}}
   After running the above commands, you should see that the data interfaces have the appropriate IP addresses assigned. 
   {{{#!shell
root@srv1-lg1:~# ifconfig DATA1
DATA1: flags=4163<UP,BROADCAST,RUNNING,MULTICAST>  mtu 1500
        inet6 fe80::1e34:daff:fe42:d4c  prefixlen 64  scopeid 0x20<link>
        ether 1c:34:da:42:0d:4c  txqueuelen 1000  (Ethernet)
        RX packets 21092  bytes 1881634 (1.8 MB)
        RX errors 0  dropped 19183  overruns 0  frame 0
        TX packets 686  bytes 204975 (204.9 KB)
        TX errors 0  dropped 0 overruns 0  carrier 0  collisions 0
root@srv1-lg1:~# ifconfig DATA2
DATA2: flags=4163<UP,BROADCAST,RUNNING,MULTICAST>  mtu 1500
        inet6 fe80::1e34:daff:fe42:d4d  prefixlen 64  scopeid 0x20<link>
        ether 1c:34:da:42:0d:4d  txqueuelen 1000  (Ethernet)
        RX packets 21091  bytes 1881530 (1.8 MB)
        RX errors 0  dropped 19184  overruns 0  frame 0
        TX packets 690  bytes 226549 (226.5 KB)
        TX errors 0  dropped 0 overruns 0  carrier 0  collisions 0
   }}}

* Run {{{uhd_find_devices}}} to make sure that both USRP N310s can be reached:
   {{{#!shell
[INFO] [UHD] linux; GNU C++ version 9.4.0; Boost_107100; UHD_4.1.0.HEAD-0-g25d617ca
--------------------------------------------------
-- UHD Device 3
--------------------------------------------------
Device Address:
    serial: 315A35A
    addr: 10.117.2.1
    claimed: False
    fpga: XG
    mgmt_addr: 10.116.2.1
    mgmt_addr: 10.117.2.1
    product: n310
    type: n3xx


--------------------------------------------------
-- UHD Device 4
--------------------------------------------------
Device Address:
    serial: 3176DF7
    addr: 10.118.3.1
    claimed: False
    fpga: XG
    mgmt_addr: 10.116.3.1
    mgmt_addr: 10.118.3.1
    product: n310
    type: n3xx
   }}}


==== Configure IBM 28GHz PAAM ====
COSMOS uses the IBM 28GHz PAAM API to configure and initialize the PAAM boards. 
Under the console in **terminal 2**, please run the following 4 commands:
    {{{#!shell
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/configure?dev_name=rfdev2-1.sb2.cosmos-lab.org&ics=0&num_elements=16&txrx=tx&pol=h&theta=0&phi=0"
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/configure?dev_name=rfdev2-1.sb2.cosmos-lab.org&ics=0&num_elements=16&txrx=tx&pol=v&theta=0&phi=0"
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/configure?dev_name=rfdev2-2.sb2.cosmos-lab.org&ics=1&num_elements=16&txrx=rx&pol=h&theta=0&phi=0"
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/configure?dev_name=rfdev2-2.sb2.cosmos-lab.org&ics=1&num_elements=16&txrx=rx&pol=v&theta=0&phi=0"
    }}}
An example message will print out to after each command to indicate that the PAAM board is being successfully configured:
    {{{#!shell
<?xml version="1.0" encoding="UTF-8"?>
<response status="OK">
  <action service="array_mgmt" name="configure" ipaddr="10.116.5.2">
    <step name="open" duration="3.780022"/>
    <step name="initializaition" duration="0.125465"/>
    <step name="enabling" duration="0.022732"/>
    <step name="steering" duration="0.006349" theta="0" phi = "0" ipaddr = "10.116.5.2" />
    <state PAAM_ID="0x23" LO_switch="PLL" if_sw1="0xF" if_sw2="0xF" if_sw3="0xF" if_sw4="0xF" txrx="rx" polarization="v" />
    <adc>
      <conv index="0" name="1v2" tADC="114" tVolt="0.279" tCurr="0.139"/>
      <conv index="1" name="1v5" tADC="214" tVolt="0.523" tCurr="1.046"/>
      <conv index="2" name="1v8" tADC="4" tVolt="0.010" tCurr="0.005"/>
      <conv index="3" name="2v7_0" tADC="13" tVolt="0.032" tCurr="0.064"/>
      <conv index="4" name="2v7_1" tADC="183" tVolt="0.447" tCurr="0.894"/>
      <conv index="5" name="2v7_2" tADC="18" tVolt="0.044" tCurr="0.088"/>
      <conv index="6" name="2v7_3" tADC="40" tVolt="0.098" tCurr="0.196"/>
      <conv index="7" name="3v3_pll" tADC="303" tVolt="0.740" tCurr="0.370"/>
      <conv index="8" name="5v_uzed" tADC="276" tVolt="0.674" tCurr="0.674"/>
      <conv index="9" name="12v" tADC="140" tVolt="0.342" tCurr="1.140"/>
      <conv index="10" name="0V" tADC="0" tVolt="0.000"/>
      <conv index="11" name="1V8" tADC="735" tVolt="1.796"/>
    </adc>
    <step name="status" duration="0.069065"/>
    <step name="close" duration="0.100179"/>
  </action>
</response>
    }}}

=== Experiment Execution ===
==== Activate MATLAB ====
MATLAB are preinstalled to the image, users are expected to activate MATLAB with their **own MATLAB license** as the following in **terminal 1**:
    {{{#!shell
    root@srv1-lg1:# cd /usr/local/MATLAB/R2022b/bin
    root@srv1-lg1:/usr/local/MATLAB/R2022b/bin# ./deactivate_matlab.sh
    root@srv1-lg1:/usr/local/MATLAB/R2022b/bin# ./activate_matlab.sh
    }}}


The codebase is preloaded to the image, in **terminal 1**, please direct to the {{{~/MAMBAS_new/MAMBAS-MobiCom2024}}} folder

Open MATLAB interface as background as
{{{#!shell
root@srv1-lg1:# cd ~/MAMBAS_new/MAMBAS-MobiCom2024
root@srv1-lg1:~/MAMBAS_new/MAMBAS-MobiCom2024# matlab &
}}}

==== Configure USRP parameters ====
In MATLAB, open {{{~/MAMBAS_new/MAMBAS-MobiCom2024/5g-phy-implementation/GetParam.m}}}, and make sure the parameters are configured as below:

{{{#!shell
% USRP Setting
param.carrier = 3.0e9;

param.subdevTx = "B:1";
param.deviceTx = "10.117.2.1";
param.gainTx = 30;
    
param.deviceRx = "10.117.3.1";
param.subdevRx = "B:1";
param.gainRx = 40;
}}}

{{{param.carrier}}}: the carrier frequency of the TX and RX. Please set it as {{{3.0e9}}} for 3 GHz carrier frequency to the IBM 28 GHz PAAM.

{{{param.deviceTx}}} and {{{param.deviceRx}}}: the IP address of the TX/RX USRP, which is {{{10.117.2.1}}} and {{{10.117.3.1}}}.

{{{param.subdevTx}}} and {{{param.subdevRX}}}: the subdevice settings of the TX/RX USRP. The connection on the sb2 requires to set both parameters as {{{B:1}}} to use the port {{{RF3}}}.

{{{param.gainTx}}} and {{{param.gainRx}}}: the TX/RX gain of the USRPs, whose range varies over different USRP types, which can be found by running {{{uhd_usrp_probe}}} command in the terminal. In sb2, the recommended value for {{{param.gainTx}}} is {{{30}}}, for {{{param.gainRx}}} is {{{40}}}.

==== Conduct the transmission ====

In MATLAB, open {{{main.m}}}, and directly run this script.

The displayed information includes:

{{{CFO}}}: carrier frequency offset

{{{SNR}}}: signal-to-noise ratio

{{{EVM}}}: error vector magnitude

{{{BLER}}}: block error rate (only one block is transmitted and it can be either 0 for success and 1 for failure);

{{{BER}}}: bit error rate

{{{Constel.png}}}: the saved constellation plot.

==== Change the SNR/MCS ====

To change SNR, you may either

Change the amplitude (by default, {{{0.5}}}) of the generated waveform in line 13 of {{{main.m}}}, or

Change the TX gain {{{param.gainTx}}} in {{{GetParam.m}}}.

To change MCS, open {{{GetParam.m}}} and customize {{{param.modu}}} for modulation and {{{param.code}}} for code rate.

For the 28 levels of MCSs in 5G, you may refer to the table {{{Table 5.1.3.1-2: MCS index table 2 for PDSCH}}} in the link below:

[https://www.sharetechnote.com/html/5G/5G_MCS_TBS_CodeRate.html]

==== Finish the experiments ====
When the experiments are completed, make sure to clean up and turn off the PAAMs as the following in **terminal 2**
{{{#!shell
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/cleanup?dev_name=rfdev2-1.sb2.cosmos-lab.org"
    <user_name>@console:~$ omf tell -a offh -t rfdev2-1.sb2.cosmos-lab.org
    <user_name>@console:~$ curl "http://am1.orbit-lab.org:5054/array_mgmt/cleanup?dev_name=rfdev2-2.sb2.cosmos-lab.org"
    <user_name>@console:~$ omf tell -a offh -t rfdev2-2.sb2.cosmos-lab.org
}}}