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unison/examples/wireless/wifi-spectrum-per-interference.cc
Sébastien Deronne 544086503f wifi: Specify units of magic numbers
2025-01-03 16:32:31 +01:00

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/*
* Copyright (c) 2009 MIRKO BANCHI
* Copyright (c) 2015 University of Washington
*
* SPDX-License-Identifier: GPL-2.0-only
*
* Authors: Mirko Banchi <mk.banchi@gmail.com>
* Sebastien Deronne <sebastien.deronne@gmail.com>
* Tom Henderson <tomhend@u.washington.edu>
*
* Adapted from wifi-ht-network.cc example
*/
#include "ns3/command-line.h"
#include "ns3/config.h"
#include "ns3/internet-stack-helper.h"
#include "ns3/ipv4-address-helper.h"
#include "ns3/mobility-helper.h"
#include "ns3/multi-model-spectrum-channel.h"
#include "ns3/non-communicating-net-device.h"
#include "ns3/on-off-helper.h"
#include "ns3/packet-sink-helper.h"
#include "ns3/packet-sink.h"
#include "ns3/propagation-loss-model.h"
#include "ns3/spectrum-wifi-helper.h"
#include "ns3/ssid.h"
#include "ns3/string.h"
#include "ns3/udp-client-server-helper.h"
#include "ns3/udp-server.h"
#include "ns3/waveform-generator-helper.h"
#include "ns3/waveform-generator.h"
#include "ns3/wifi-net-device.h"
#include "ns3/yans-wifi-channel.h"
#include "ns3/yans-wifi-helper.h"
#include <iomanip>
// This is a simple example of an IEEE 802.11n Wi-Fi network with a
// non-Wi-Fi interferer. It is an adaptation of the wifi-spectrum-per-example
//
// Unless the --waveformPower argument is passed, it will operate similarly to
// wifi-spectrum-per-example. Adding --waveformPower=value for values
// greater than 0.0001 will result in frame losses beyond those that
// result from the normal SNR based on distance path loss.
//
// If YansWifiPhy is selected as the wifiType, --waveformPower will have
// no effect.
//
// Network topology:
//
// Wi-Fi 192.168.1.0
//
// STA AP
// * <-- distance --> *
// | |
// n1 n2
//
// Users may vary the following command-line arguments in addition to the
// attributes, global values, and default values typically available:
//
// --simulationTime: Simulation time [10s]
// --udp: UDP if set to 1, TCP otherwise [true]
// --distance: meters separation between nodes [50]
// --index: restrict index to single value between 0 and 31 [256]
// --wifiType: select ns3::SpectrumWifiPhy or ns3::YansWifiPhy [ns3::SpectrumWifiPhy]
// --errorModelType: select ns3::NistErrorRateModel or ns3::YansErrorRateModel
// [ns3::NistErrorRateModel]
// --enablePcap: enable pcap output [false]
// --waveformPower: Waveform power (linear W) [0]
//
// By default, the program will step through 32 index values, corresponding
// to the following MCS, channel width, and guard interval combinations:
// index 0-7: MCS 0-7, long guard interval, 20 MHz channel
// index 8-15: MCS 0-7, short guard interval, 20 MHz channel
// index 16-23: MCS 0-7, long guard interval, 40 MHz channel
// index 24-31: MCS 0-7, short guard interval, 40 MHz channel
// and send UDP for 10 seconds using each MCS, using the SpectrumWifiPhy and the
// NistErrorRateModel, at a distance of 50 meters. The program outputs
// results such as:
//
// wifiType: ns3::SpectrumWifiPhy distance: 50m; time: 10; TxPower: 16 dBm (40 mW)
// index MCS Rate (Mb/s) Tput (Mb/s) Received Signal (dBm)Noi+Inf(dBm) SNR (dB)
// 0 0 6.50 5.77 7414 -64.69 -93.97 29.27
// 1 1 13.00 11.58 14892 -64.69 -93.97 29.27
// 2 2 19.50 17.39 22358 -64.69 -93.97 29.27
// 3 3 26.00 23.23 29875 -64.69 -93.97 29.27
// ...
//
using namespace ns3;
// Global variables for use in callbacks.
double g_signalDbmAvg; //!< Average signal power [dBm]
double g_noiseDbmAvg; //!< Average noise power [dBm]
uint32_t g_samples; //!< Number of samples
/**
* Monitor sniffer Rx trace
*
* @param packet The sensed packet.
* @param channelFreqMhz The channel frequency [MHz].
* @param txVector The Tx vector.
* @param aMpdu The aMPDU.
* @param signalNoise The signal and noise dBm.
* @param staId The STA ID.
*/
void
MonitorSniffRx(Ptr<const Packet> packet,
uint16_t channelFreqMhz,
WifiTxVector txVector,
MpduInfo aMpdu,
SignalNoiseDbm signalNoise,
uint16_t staId)
{
g_samples++;
g_signalDbmAvg += ((signalNoise.signal - g_signalDbmAvg) / g_samples);
g_noiseDbmAvg += ((signalNoise.noise - g_noiseDbmAvg) / g_samples);
}
NS_LOG_COMPONENT_DEFINE("WifiSpectrumPerInterference");
Ptr<SpectrumModel> SpectrumModelWifi5180MHz; //!< Spectrum model at 5180 MHz.
Ptr<SpectrumModel> SpectrumModelWifi5190MHz; //!< Spectrum model at 5190 MHz.
/** Initializer for a static spectrum model centered around 5180 MHz */
class static_SpectrumModelWifi5180MHz_initializer
{
public:
static_SpectrumModelWifi5180MHz_initializer()
{
BandInfo bandInfo;
bandInfo.fc = 5180e6;
bandInfo.fl = 5180e6 - 10e6;
bandInfo.fh = 5180e6 + 10e6;
Bands bands;
bands.push_back(bandInfo);
SpectrumModelWifi5180MHz = Create<SpectrumModel>(bands);
}
};
/// Static instance to initizlize the spectrum model around 5180 MHz.
static_SpectrumModelWifi5180MHz_initializer static_SpectrumModelWifi5180MHz_initializer_instance;
/** Initializer for a static spectrum model centered around 5190 MHz */
class static_SpectrumModelWifi5190MHz_initializer
{
public:
static_SpectrumModelWifi5190MHz_initializer()
{
BandInfo bandInfo;
bandInfo.fc = 5190e6;
bandInfo.fl = 5190e6 - 10e6;
bandInfo.fh = 5190e6 + 10e6;
Bands bands;
bands.push_back(bandInfo);
SpectrumModelWifi5190MHz = Create<SpectrumModel>(bands);
}
};
/// Static instance to initizlize the spectrum model around 5190 MHz.
static_SpectrumModelWifi5190MHz_initializer static_SpectrumModelWifi5190MHz_initializer_instance;
int
main(int argc, char* argv[])
{
bool udp{true};
meter_u distance{50};
Time simulationTime{"10s"};
uint16_t index{256};
std::string wifiType{"ns3::SpectrumWifiPhy"};
std::string errorModelType{"ns3::NistErrorRateModel"};
bool enablePcap{false};
const uint32_t tcpPacketSize{1448};
Watt_u waveformPower{0};
CommandLine cmd(__FILE__);
cmd.AddValue("simulationTime", "Simulation time", simulationTime);
cmd.AddValue("udp", "UDP if set to 1, TCP otherwise", udp);
cmd.AddValue("distance", "meters separation between nodes", distance);
cmd.AddValue("index", "restrict index to single value between 0 and 31", index);
cmd.AddValue("wifiType", "select ns3::SpectrumWifiPhy or ns3::YansWifiPhy", wifiType);
cmd.AddValue("errorModelType",
"select ns3::NistErrorRateModel or ns3::YansErrorRateModel",
errorModelType);
cmd.AddValue("enablePcap", "enable pcap output", enablePcap);
cmd.AddValue("waveformPower", "Waveform power (linear W)", waveformPower);
cmd.Parse(argc, argv);
uint16_t startIndex = 0;
uint16_t stopIndex = 31;
if (index < 32)
{
startIndex = index;
stopIndex = index;
}
std::cout << "wifiType: " << wifiType << " distance: " << distance
<< "m; time: " << simulationTime << "; TxPower: 16 dBm (40 mW)" << std::endl;
std::cout << std::setw(5) << "index" << std::setw(6) << "MCS" << std::setw(13) << "Rate (Mb/s)"
<< std::setw(12) << "Tput (Mb/s)" << std::setw(10) << "Received " << std::setw(12)
<< "Signal (dBm)" << std::setw(12) << "Noi+Inf(dBm)" << std::setw(9) << "SNR (dB)"
<< std::endl;
for (uint16_t i = startIndex; i <= stopIndex; i++)
{
uint32_t payloadSize;
if (udp)
{
payloadSize = 972; // 1000 bytes IPv4
}
else
{
payloadSize = 1448; // 1500 bytes IPv6
Config::SetDefault("ns3::TcpSocket::SegmentSize", UintegerValue(payloadSize));
}
NodeContainer wifiStaNode;
wifiStaNode.Create(1);
NodeContainer wifiApNode;
wifiApNode.Create(1);
NodeContainer interferingNode;
interferingNode.Create(1);
YansWifiPhyHelper phy;
SpectrumWifiPhyHelper spectrumPhy;
Ptr<MultiModelSpectrumChannel> spectrumChannel;
uint16_t frequency = (i <= 15 ? 5180 : 5190);
if (wifiType == "ns3::YansWifiPhy")
{
YansWifiChannelHelper channel;
channel.AddPropagationLoss("ns3::FriisPropagationLossModel",
"Frequency",
DoubleValue(frequency * 1e6));
channel.SetPropagationDelay("ns3::ConstantSpeedPropagationDelayModel");
phy.SetChannel(channel.Create());
phy.Set("ChannelSettings",
StringValue(std::string("{") + (frequency == 5180 ? "36" : "38") +
", 0, BAND_5GHZ, 0}"));
}
else if (wifiType == "ns3::SpectrumWifiPhy")
{
spectrumChannel = CreateObject<MultiModelSpectrumChannel>();
Ptr<FriisPropagationLossModel> lossModel = CreateObject<FriisPropagationLossModel>();
lossModel->SetFrequency(frequency * 1e6);
spectrumChannel->AddPropagationLossModel(lossModel);
Ptr<ConstantSpeedPropagationDelayModel> delayModel =
CreateObject<ConstantSpeedPropagationDelayModel>();
spectrumChannel->SetPropagationDelayModel(delayModel);
spectrumPhy.SetChannel(spectrumChannel);
spectrumPhy.SetErrorRateModel(errorModelType);
// channel 36 at 20 MHz, 38 at 40 MHz
spectrumPhy.Set("ChannelSettings",
StringValue(std::string("{") + (frequency == 5180 ? "36" : "38") +
", 0, BAND_5GHZ, 0}"));
}
else
{
NS_FATAL_ERROR("Unsupported WiFi type " << wifiType);
}
WifiHelper wifi;
wifi.SetStandard(WIFI_STANDARD_80211n);
WifiMacHelper mac;
Ssid ssid = Ssid("ns380211n");
double datarate = 0;
StringValue DataRate;
if (i == 0)
{
DataRate = StringValue("HtMcs0");
datarate = 6.5;
}
else if (i == 1)
{
DataRate = StringValue("HtMcs1");
datarate = 13;
}
else if (i == 2)
{
DataRate = StringValue("HtMcs2");
datarate = 19.5;
}
else if (i == 3)
{
DataRate = StringValue("HtMcs3");
datarate = 26;
}
else if (i == 4)
{
DataRate = StringValue("HtMcs4");
datarate = 39;
}
else if (i == 5)
{
DataRate = StringValue("HtMcs5");
datarate = 52;
}
else if (i == 6)
{
DataRate = StringValue("HtMcs6");
datarate = 58.5;
}
else if (i == 7)
{
DataRate = StringValue("HtMcs7");
datarate = 65;
}
else if (i == 8)
{
DataRate = StringValue("HtMcs0");
datarate = 7.2;
}
else if (i == 9)
{
DataRate = StringValue("HtMcs1");
datarate = 14.4;
}
else if (i == 10)
{
DataRate = StringValue("HtMcs2");
datarate = 21.7;
}
else if (i == 11)
{
DataRate = StringValue("HtMcs3");
datarate = 28.9;
}
else if (i == 12)
{
DataRate = StringValue("HtMcs4");
datarate = 43.3;
}
else if (i == 13)
{
DataRate = StringValue("HtMcs5");
datarate = 57.8;
}
else if (i == 14)
{
DataRate = StringValue("HtMcs6");
datarate = 65;
}
else if (i == 15)
{
DataRate = StringValue("HtMcs7");
datarate = 72.2;
}
else if (i == 16)
{
DataRate = StringValue("HtMcs0");
datarate = 13.5;
}
else if (i == 17)
{
DataRate = StringValue("HtMcs1");
datarate = 27;
}
else if (i == 18)
{
DataRate = StringValue("HtMcs2");
datarate = 40.5;
}
else if (i == 19)
{
DataRate = StringValue("HtMcs3");
datarate = 54;
}
else if (i == 20)
{
DataRate = StringValue("HtMcs4");
datarate = 81;
}
else if (i == 21)
{
DataRate = StringValue("HtMcs5");
datarate = 108;
}
else if (i == 22)
{
DataRate = StringValue("HtMcs6");
datarate = 121.5;
}
else if (i == 23)
{
DataRate = StringValue("HtMcs7");
datarate = 135;
}
else if (i == 24)
{
DataRate = StringValue("HtMcs0");
datarate = 15;
}
else if (i == 25)
{
DataRate = StringValue("HtMcs1");
datarate = 30;
}
else if (i == 26)
{
DataRate = StringValue("HtMcs2");
datarate = 45;
}
else if (i == 27)
{
DataRate = StringValue("HtMcs3");
datarate = 60;
}
else if (i == 28)
{
DataRate = StringValue("HtMcs4");
datarate = 90;
}
else if (i == 29)
{
DataRate = StringValue("HtMcs5");
datarate = 120;
}
else if (i == 30)
{
DataRate = StringValue("HtMcs6");
datarate = 135;
}
else
{
DataRate = StringValue("HtMcs7");
datarate = 150;
}
wifi.SetRemoteStationManager("ns3::ConstantRateWifiManager",
"DataMode",
DataRate,
"ControlMode",
DataRate);
NetDeviceContainer staDevice;
NetDeviceContainer apDevice;
if (wifiType == "ns3::YansWifiPhy")
{
mac.SetType("ns3::StaWifiMac", "Ssid", SsidValue(ssid));
staDevice = wifi.Install(phy, mac, wifiStaNode);
mac.SetType("ns3::ApWifiMac", "Ssid", SsidValue(ssid));
apDevice = wifi.Install(phy, mac, wifiApNode);
}
else if (wifiType == "ns3::SpectrumWifiPhy")
{
mac.SetType("ns3::StaWifiMac", "Ssid", SsidValue(ssid));
staDevice = wifi.Install(spectrumPhy, mac, wifiStaNode);
mac.SetType("ns3::ApWifiMac", "Ssid", SsidValue(ssid));
apDevice = wifi.Install(spectrumPhy, mac, wifiApNode);
}
bool shortGuardIntervalSupported = (i > 7 && i <= 15) || (i > 23);
Config::Set("/NodeList/*/DeviceList/*/$ns3::WifiNetDevice/HtConfiguration/"
"ShortGuardIntervalSupported",
BooleanValue(shortGuardIntervalSupported));
// mobility.
MobilityHelper mobility;
Ptr<ListPositionAllocator> positionAlloc = CreateObject<ListPositionAllocator>();
positionAlloc->Add(Vector(0.0, 0.0, 0.0));
positionAlloc->Add(Vector(distance, 0.0, 0.0));
positionAlloc->Add(Vector(distance, distance, 0.0));
mobility.SetPositionAllocator(positionAlloc);
mobility.SetMobilityModel("ns3::ConstantPositionMobilityModel");
mobility.Install(wifiApNode);
mobility.Install(wifiStaNode);
mobility.Install(interferingNode);
/* Internet stack*/
InternetStackHelper stack;
stack.Install(wifiApNode);
stack.Install(wifiStaNode);
Ipv4AddressHelper address;
address.SetBase("192.168.1.0", "255.255.255.0");
Ipv4InterfaceContainer staNodeInterface;
Ipv4InterfaceContainer apNodeInterface;
staNodeInterface = address.Assign(staDevice);
apNodeInterface = address.Assign(apDevice);
/* Setting applications */
ApplicationContainer serverApp;
if (udp)
{
// UDP flow
uint16_t port = 9;
UdpServerHelper server(port);
serverApp = server.Install(wifiStaNode.Get(0));
serverApp.Start(Seconds(0));
serverApp.Stop(simulationTime + Seconds(1));
const auto packetInterval = payloadSize * 8.0 / (datarate * 1e6);
UdpClientHelper client(staNodeInterface.GetAddress(0), port);
client.SetAttribute("MaxPackets", UintegerValue(4294967295U));
client.SetAttribute("Interval", TimeValue(Seconds(packetInterval)));
client.SetAttribute("PacketSize", UintegerValue(payloadSize));
ApplicationContainer clientApp = client.Install(wifiApNode.Get(0));
clientApp.Start(Seconds(1));
clientApp.Stop(simulationTime + Seconds(1));
}
else
{
// TCP flow
uint16_t port = 50000;
Address localAddress(InetSocketAddress(Ipv4Address::GetAny(), port));
PacketSinkHelper packetSinkHelper("ns3::TcpSocketFactory", localAddress);
serverApp = packetSinkHelper.Install(wifiStaNode.Get(0));
serverApp.Start(Seconds(0));
serverApp.Stop(simulationTime + Seconds(1));
OnOffHelper onoff("ns3::TcpSocketFactory", Ipv4Address::GetAny());
onoff.SetAttribute("OnTime", StringValue("ns3::ConstantRandomVariable[Constant=1]"));
onoff.SetAttribute("OffTime", StringValue("ns3::ConstantRandomVariable[Constant=0]"));
onoff.SetAttribute("PacketSize", UintegerValue(payloadSize));
onoff.SetAttribute("DataRate", DataRateValue(datarate * 1e6));
AddressValue remoteAddress(InetSocketAddress(staNodeInterface.GetAddress(0), port));
onoff.SetAttribute("Remote", remoteAddress);
ApplicationContainer clientApp = onoff.Install(wifiApNode.Get(0));
clientApp.Start(Seconds(1));
clientApp.Stop(simulationTime + Seconds(1));
}
// Configure waveform generator
Ptr<SpectrumValue> wgPsd =
Create<SpectrumValue>(i <= 15 ? SpectrumModelWifi5180MHz : SpectrumModelWifi5190MHz);
*wgPsd = waveformPower / 20e6; // PSD spread across 20 MHz
NS_LOG_INFO("wgPsd : " << *wgPsd
<< " integrated power: " << Integral(*(GetPointer(wgPsd))));
if (wifiType == "ns3::SpectrumWifiPhy")
{
WaveformGeneratorHelper waveformGeneratorHelper;
waveformGeneratorHelper.SetChannel(spectrumChannel);
waveformGeneratorHelper.SetTxPowerSpectralDensity(wgPsd);
waveformGeneratorHelper.SetPhyAttribute("Period", TimeValue(Seconds(0.0007)));
waveformGeneratorHelper.SetPhyAttribute("DutyCycle", DoubleValue(1));
NetDeviceContainer waveformGeneratorDevices =
waveformGeneratorHelper.Install(interferingNode);
Simulator::Schedule(Seconds(0.002),
&WaveformGenerator::Start,
waveformGeneratorDevices.Get(0)
->GetObject<NonCommunicatingNetDevice>()
->GetPhy()
->GetObject<WaveformGenerator>());
}
Config::ConnectWithoutContext("/NodeList/0/DeviceList/*/Phy/MonitorSnifferRx",
MakeCallback(&MonitorSniffRx));
if (enablePcap)
{
phy.SetPcapDataLinkType(WifiPhyHelper::DLT_IEEE802_11_RADIO);
std::stringstream ss;
ss << "wifi-spectrum-per-example-" << i;
phy.EnablePcap(ss.str(), apDevice);
}
g_signalDbmAvg = 0;
g_noiseDbmAvg = 0;
g_samples = 0;
// Make sure we are tuned to 5180 MHz; if not, the example will
// not work properly
Ptr<NetDevice> staDevicePtr = staDevice.Get(0);
Ptr<WifiPhy> wifiPhyPtr = staDevicePtr->GetObject<WifiNetDevice>()->GetPhy();
if (i <= 15)
{
NS_ABORT_MSG_IF(wifiPhyPtr->GetChannelWidth() != MHz_u{20},
"Error: Channel width must be 20 MHz if MCS index <= 15");
NS_ABORT_MSG_IF(
wifiPhyPtr->GetFrequency() != MHz_u{5180},
"Error: Wi-Fi nodes must be tuned to 5180 MHz to match the waveform generator");
}
else
{
NS_ABORT_MSG_IF(wifiPhyPtr->GetChannelWidth() != MHz_u{40},
"Error: Channel width must be 40 MHz if MCS index > 15");
NS_ABORT_MSG_IF(
wifiPhyPtr->GetFrequency() != MHz_u{5190},
"Error: Wi-Fi nodes must be tuned to 5190 MHz to match the waveform generator");
}
Simulator::Stop(simulationTime + Seconds(1));
Simulator::Run();
auto throughput = 0.0;
auto totalPacketsThrough = 0.0;
if (udp)
{
// UDP
totalPacketsThrough = DynamicCast<UdpServer>(serverApp.Get(0))->GetReceived();
throughput =
totalPacketsThrough * payloadSize * 8 / simulationTime.GetMicroSeconds(); // Mbit/s
}
else
{
// TCP
auto totalBytesRx = DynamicCast<PacketSink>(serverApp.Get(0))->GetTotalRx();
totalPacketsThrough = totalBytesRx / tcpPacketSize;
throughput = totalBytesRx * 8 / simulationTime.GetMicroSeconds(); // Mbit/s
}
std::cout << std::setw(5) << i << std::setw(6) << (i % 8) << std::setprecision(2)
<< std::fixed << std::setw(10) << datarate << std::setw(12) << throughput
<< std::setw(8) << totalPacketsThrough;
if (totalPacketsThrough > 0)
{
std::cout << std::setw(12) << g_signalDbmAvg << std::setw(12) << g_noiseDbmAvg
<< std::setw(12) << (g_signalDbmAvg - g_noiseDbmAvg) << std::endl;
}
else
{
std::cout << std::setw(12) << "N/A" << std::setw(12) << "N/A" << std::setw(12) << "N/A"
<< std::endl;
}
Simulator::Destroy();
}
return 0;
}
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