.. include:: replace.txt
.. highlight:: cpp
Wifi
----
|ns3| nodes can contain a collection of NetDevice objects, much like an actual
computer contains separate interface cards for Ethernet, Wifi, Bluetooth, etc.
This chapter describes the |ns3| WifiNetDevice and related models. By adding
WifiNetDevice objects to |ns3| nodes, one can create models of 802.11-based
infrastructure and ad hoc networks.
Overview of the model
*********************
The WifiNetDevice models a wireless network interface controller based
on the IEEE 802.11 standard [ieee80211]_. We will go into more detail below but in brief,
|ns3| provides models for these aspects of 802.11:
* basic 802.11 DCF with **infrastructure** and **adhoc** modes
* **802.11a**, **802.11b**, **802.11g** and **802.11n** (both 2.4 and 5 GHz bands) physical layers
* **MSDU aggregation** extension of 802.11n
* QoS-based EDCA and queueing extensions of **802.11e**
* the ability to use different propagation loss models and propagation delay models,
please see the chapter on :ref:`Propagation` for more detail
* various rate control algorithms including **Aarf, Arf, Cara, Onoe, Rraa,
ConstantRate, and Minstrel**
* 802.11s (mesh), described in another chapter
The set of 802.11 models provided in |ns3| attempts to provide an accurate
MAC-level implementation of the 802.11 specification and to provide a
not-so-slow PHY-level model of the 802.11a specification and a not-so-slow PHY-level model of the 802.11a/b/g/n specifications.
In |ns3|, nodes can have multiple WifiNetDevices on separate channels, and the
WifiNetDevice can coexist with other device types; this removes an architectural
limitation found in |ns2|. Presently, however, there is no model for
cross-channel interference or coupling.
The source code for the WifiNetDevice lives in the directory
``src/wifi``.
The implementation is modular and provides roughly four levels of models:
* the **PHY layer models**
* the so-called **MAC low models**: they implement DCF and EDCAF
* the so-called **MAC high models**: they implement the MAC-level beacon
generation, probing, and association state machines, and
* a set of **Rate control algorithms** used by the MAC low models
Next, we provide some overview of each layer.
More detailed information will be discussed later.
MAC high models
===============
There are presently three **MAC high models** that provide for the three
(non-mesh; the mesh equivalent, which is a sibling of these with common
parent ``ns3::RegularWifiMac``, is not discussed here) Wi-Fi topological
elements - Access Point (AP) (``ns3::ApWifiMac``),
non-AP Station (STA) (``ns3::StaWifiMac``), and STA in an Independent
Basic Service Set (IBSS - also commonly referred to as an ad hoc
network (``ns3::AdhocWifiMac``).
The simplest of these is ``ns3::AdhocWifiMac``, which implements a
Wi-Fi MAC that does not perform any kind of beacon generation,
probing, or association. The ``ns3::StaWifiMac`` class implements
an active probing and association state machine that handles automatic
re-association whenever too many beacons are missed. Finally,
``ns3::ApWifiMac`` implements an AP that generates periodic
beacons, and that accepts every attempt to associate.
These three MAC high models share a common parent in
``ns3::RegularWifiMac``, which exposes, among other MAC
configuration, an attribute ``QosSupported`` that allows
configuration of 802.11e/WMM-style QoS support and an attribute ``HtSupported`` that allows configuration of 802.11n High Throughput style support.
MAC low layer
==============
The **MAC low layer** is split into three components:
#. ``ns3::MacLow`` which takes care of RTS/CTS/DATA/ACK transactions.
#. ``ns3::DcfManager`` and ``ns3::DcfState`` which implements the DCF and EDCAF
functions.
#. ``ns3::DcaTxop`` and ``ns3::EdcaTxopN`` which handle the packet queue,
packet fragmentation, and packet retransmissions if they are needed.
The ``ns3::DcaTxop`` object is used high MACs that are not QoS-enabled,
and for transmission of frames (e.g., of type Management)
that the standard says should access the medium using the DCF.
``ns3::EdcaTxopN`` is is used by QoS-enabled high MACs and also
performs 802.11n-style MSDU aggregation.
Rate control algorithms
=======================
There are also several **rate control algorithms** that can be used by the
MAC low layer. A complete list of available rate control algorithms is
provided in a separate section.
PHY layer models
================
The PHY layer implements a single model in the ``ns3::WifiPhy`` class: the
physical layer model implemented there is described fully in a paper entitled
`Yet Another Network Simulator <http://cutebugs.net/files/wns2-yans.pdf>`_
Validation results for 802.11b are available in this
`technical report <http://www.nsnam.org/~pei/80211b.pdf>`_
.. _wifi-architecture:
.. figure:: figures/WifiArchitecture.*
WifiNetDevice architecture.
Using the WifiNetDevice
***********************
The modularity provided by the implementation makes low-level configuration of
the WifiNetDevice powerful but complex. For this reason, we provide some helper
classes to perform common operations in a simple matter, and leverage the |ns3|
attribute system to allow users to control the parametrization of the underlying
models.
Users who use the low-level |ns3| API and who wish to add a WifiNetDevice to
their node must create an instance of a WifiNetDevice, plus a number of
constituent objects, and bind them together appropriately (the WifiNetDevice is
very modular in this regard, for future extensibility). At the low-level API,
this can be done with about 20 lines of code (see ``ns3::WifiHelper::Install``,
and ``ns3::YansWifiPhyHelper::Create``). They also must create, at some point, a
WifiChannel, which also contains a number of constituent objects (see
``ns3::YansWifiChannelHelper::Create``).
However, a few helpers are available for users to add these devices and channels
with only a few lines of code, if they are willing to use defaults, and the
helpers provide additional API to allow the passing of attribute values to
change default values. Commonly used attribute values are listed in the
Attributes section. The scripts in ``examples/wireless`` can be browsed to
see how this is done. Next, we describe the common steps to create a WifiNetDevice
from the bottom layer (WifiChannel) up to the device layer (WifiNetDevice).
To create a WifiNetDevice, users need to configure mainly five steps:
* Configure the WifiChannel: WifiChannel takes care of getting signal
from one device to other devices on the same wifi channel.
The main configurations of WifiChannel are propagation loss model and propagation delay model.
* Configure the WifiPhy: WifiPhy takes care of actually sending and receiving wireless
signal from WifiChannel. Here, WifiPhy decides whether each frame will be successfully
decoded or not depending on the received signal strength and noise. Thus, the main
configuration of WifiPhy is the error rate model, which is the one that actually
calculates the probability of successfully decoding the frame based on the signal.
* Configure WifiMac: this step is more on related to the architecture and device level.
The users configure the wifi architecture (i.e. ad-hoc or ap-sta) and whether QoS (802.11e) and/or HT (802.11n) features are supported or not.
* Create WifiDevice: at this step, users configure the desired wifi standard
(e.g. **802.11b**, **802.11g**, **802.11a** or **802.11n**) and rate control algorithm
* Configure mobility: finally, mobility model is (usually) required before WifiNetDevice
can be used.
YansWifiChannelHelper
=====================
The YansWifiChannelHelper has an unusual name. Readers may wonder why it is
named this way. The reference is to the `yans simulator
<http://cutebugs.net/files/wns2-yans.pdf>`_ from which this model is taken. The
helper can be used to create a WifiChannel with a default PropagationLoss and
PropagationDelay model.
Users will typically type code such as::
YansWifiChannelHelper wifiChannelHelper = YansWifiChannelHelper::Default ();
Ptr<WifiChannel> wifiChannel = wifiChannelHelper.Create ();
to get the defaults. Specifically, the default is a channel model with a
propagation delay equal to a constant, the speed of light (``ns3::ConstantSpeedPropagationDelayModel``),
and a propagation loss based on a default log distance model (``ns3::LogDistancePropagationLossModel``)), using a default exponent of 3.
Please note that the default log distance model is configured with a reference
loss of 46.6777 dB at reference distance of 1m. The reference loss of 46.6777 dB
was calculated using Friis propagation loss model at 5.15 GHz. The reference loss
must be changed if **802.11b**, **802.11g** or **802.11n** (at 2.4 GHz) are used since they operate at 2.4 Ghz.
Note the distinction above in creating a helper object vs. an actual simulation
object. In |ns3|, helper objects (used at the helper API only) are created on
the stack (they could also be created with operator new and later deleted).
However, the actual |ns3| objects typically inherit from ``class ns3::Object``
and are assigned to a smart pointer. See the chapter in the |ns3| manual for
a discussion of the |ns3| object model, if you are not familiar with it.
The following two methods are useful when configuring YansWifiChannelHelper:
* ``YansWifiChannelHelper::AddPropagationLoss`` adds a PropagationLossModel
to a chain of PropagationLossModel
* ``YansWifiChannelHelper::SetPropagationDelay`` sets a PropagationDelayModel
YansWifiPhyHelper
=================
Physical devices (base class ``ns3::WifiPhy``) connect to ``ns3::WifiChannel`` models in
|ns3|. We need to create WifiPhy objects appropriate for the YansWifiChannel; here
the ``YansWifiPhyHelper`` will do the work.
The YansWifiPhyHelper class configures an object factory to create instances of
a ``YansWifiPhy`` and adds some other objects to it, including possibly a
supplemental ErrorRateModel and a pointer to a MobilityModel. The user code is
typically::
YansWifiPhyHelper wifiPhyHelper = YansWifiPhyHelper::Default ();
wifiPhyHelper.SetChannel (wifiChannel);
The default YansWifiPhyHelper is configured with NistErrorRateModel
(``ns3::NistErrorRateModel``). You can change the error rate model by
calling the ``YansWifiPhyHelper::SetErrorRateModel`` method.
Optionally, if pcap tracing is needed, a user may use the following
command to enable pcap tracing::
YansWifiPhyHelper::SetPcapDataLinkType (enum SupportedPcapDataLinkTypes dlt)
|ns3| supports RadioTap and Prism tracing extensions for 802.11.
Note that we haven't actually created any WifiPhy objects yet; we've just
prepared the YansWifiPhyHelper by telling it which channel it is connected to.
The Phy objects are created in the next step.
802.11n PHY layer can use either 20 or 40 MHz channel width, and either long (800 ns) or short (400 ns) OFDM guard intervals. To configure those parameters, the following lines of code could be used (in this example, it configures a 40 MHz channel width with a short guard interval)::
wifiPhyHelper.Set (« ChannelBonding,BooleanValue(true));
wifiPhyHelper.Set ("ShortGuardEnabled",BooleanValue(true));
Furthermore, 802.11n provides an optional mode (GreenField mode) to reduce preamble durations and which is only compatible with 802.11n devices. This mode is enabled as follows::
wifiPhyHelper.Set ("GreenfieldEnabled",BooleanValue(true));
WifiMacHelper
=============
The next step is to configure the MAC model.
We use WifiMacHelper to accomplish this.
WifiMacHelper takes care of both the MAC low model and MAC high model.
A user must decide if 802.11/WMM-style QoS and/or 802.11n-style High throughput (HT) support is required.
NqosWifiMacHelper and QosWifiMacHelper
++++++++++++++++++++++++++++++++++++++
The ``ns3::NqosWifiMacHelper`` and ``ns3::QosWifiMacHelper`` configure an
object factory to create instances of a ``ns3::WifiMac``. They are used to
configure MAC parameters like type of MAC.
The former, ``ns3::NqosWifiMacHelper``, supports creation of MAC
instances that do not have 802.11e/WMM-style QoS nor 802.11n-style High throughput (HT) support enabled.
For example the following user code configures a non-QoS and non-HT MAC that
will be a non-AP STA in an infrastructure network where the AP has
SSID ``ns-3-ssid``::
NqosWifiMacHelper wifiMacHelper = NqosWifiMacHelper::Default ();
Ssid ssid = Ssid ("ns-3-ssid");
wifiMacHelper.SetType ("ns3::StaWifiMac",
"Ssid", SsidValue (ssid),
"ActiveProbing", BooleanValue (false));
To create MAC instances with QoS support enabled,
``ns3::QosWifiMacHelper`` is used in place of
``ns3::NqosWifiMacHelper``.
The following code shows an example use of ``ns3::QosWifiMacHelper`` to
create an AP with QoS enabled::
QosWifiMacHelper wifiMacHelper = QosWifiMacHelper::Default ();
wifiMacHelper.SetType ("ns3::ApWifiMac",
"Ssid", SsidValue (ssid),
"BeaconGeneration", BooleanValue (true),
"BeaconInterval", TimeValue (Seconds (2.5)));
With QoS-enabled MAC models it is possible to work with traffic belonging to
four different Access Categories (ACs): **AC_VO** for voice traffic,
**AC_VI** for video traffic, **AC_BE** for best-effort
traffic and **AC_BK** for background traffic. In order for the
MAC to determine the appropriate AC for an MSDU, packets forwarded
down to these MAC layers should be marked using **ns3::QosTag** in
order to set a TID (traffic id) for that packet otherwise it will be
considered belonging to **AC_BE**.
To create ad-hoc MAC instances, simply use ``ns3::AdhocWifiMac`` instead of ``ns3::StaWifiMac`` or ``ns3::ApWifiMac``.
HtWifiMacHelper
+++++++++++++++
The ``ns3::HtWifiMacHelper`` configures an
object factory to create instances of a ``ns3::WifiMac``. It is used to
supports creation of MAC instances that have 802.11n-style High throughput (HT) and QoS support enabled. In particular, this object can be also used to set:
* an MSDU aggregator for a particular Access Category (AC) in order to use
802.11n MSDU aggregation feature;
* block ack parameters like threshold (number of packets for which block ack
mechanism should be used) and inactivity timeout.
For example the following user code configures a HT MAC that
will be a non-AP STA with QoS enabled, aggregation on AC_VO, and Block Ack on AC_BE, in an infrastructure network where the AP has
SSID ``ns-3-ssid``::
HtWifiMacHelper wifiMacHelper = HtWifiMacHelper::Default ();
Ssid ssid = Ssid ("ns-3-ssid");
wifiMacHelper.SetType ("ns3::StaWifiMac",
"Ssid", SsidValue (ssid),
"ActiveProbing", BooleanValue (false));
wifiMacHelper.SetMsduAggregatorForAc (AC_VO, "ns3::MsduStandardAggregator",
"MaxAmsduSize", UintegerValue (3839));
wifiMacHelper.SetBlockAckThresholdForAc (AC_BE, 10);
wifiMacHelper.SetBlockAckInactivityTimeoutForAc (AC_BE, 5);
This object can be also used to set in the same way as ``ns3::QosWifiMacHelper``.
WifiHelper
==========
We're now ready to create WifiNetDevices. First, let's create
a WifiHelper with default settings::
WifiHelper wifiHelper = WifiHelper::Default ();
What does this do? It sets the default wifi standard to **802.11a** and sets the RemoteStationManager to
``ns3::ArfWifiManager``. You can change the RemoteStationManager by calling the
``WifiHelper::SetRemoteStationManager`` method. To change the wifi standard, call the
``WifiHelper::SetStandard`` method with the desired standard.
Now, let's use the wifiPhyHelper and wifiMacHelper created above to install WifiNetDevices
on a set of nodes in a NodeContainer "c"::
NetDeviceContainer wifiContainer = WifiHelper::Install (wifiPhyHelper, wifiMacHelper, c);
This creates the WifiNetDevice which includes also a WifiRemoteStationManager, a
WifiMac, and a WifiPhy (connected to the matching WifiChannel).
There are many |ns3| attributes that can be set on the above helpers to
deviate from the default behavior; the example scripts show how to do some of
this reconfiguration.
Mobility configuration
======================
Finally, a mobility model must be configured on each node with Wi-Fi device.
Mobility model is used for calculating propagation loss and propagation delay.
Two examples are provided in the next section.
Users are referred to the chapter on :ref:`Mobility` module for detailed information.
Example configuration
=====================
We provide two typical examples of how a user might configure a Wi-Fi network --
one example with an ad-hoc network and one example with an infrastructure network.
The two examples were modified from the two examples in the ``examples/wireless`` folder
(``wifi-simple-adhoc.cc`` and ``wifi-simple-infra.cc``).
Users are encouraged to see examples in the ``examples/wireless`` folder.
AdHoc WifiNetDevice configuration
+++++++++++++++++++++++++++++++++
In this example, we create two ad-hoc nodes equipped with 802.11a Wi-Fi devices.
We use the ``ns3::ConstantSpeedPropagationDelayModel`` as the propagation delay model and
``ns3::LogDistancePropagationLossModel`` with the exponent of 3.0 as the propagation loss model.
Both devices are configured with ``ConstantRateWifiManager`` at the fixed rate of 12Mbps.
Finally, we manually place them by using the ``ns3::ListPositionAllocator``::
std::string phyMode ("OfdmRate12Mbps");
NodeContainer c;
c.Create (2);
WifiHelper wifi;
wifi.SetStandard (WIFI_PHY_STANDARD_80211a);
YansWifiPhyHelper wifiPhy = YansWifiPhyHelper::Default ();
// ns-3 supports RadioTap and Prism tracing extensions for 802.11
wifiPhy.SetPcapDataLinkType (YansWifiPhyHelper::DLT_IEEE802_11_RADIO);
YansWifiChannelHelper wifiChannel;
wifiChannel.SetPropagationDelay ("ns3::ConstantSpeedPropagationDelayModel");
wifiChannel.AddPropagationLoss ("ns3::LogDistancePropagationLossModel",
"Exponent", DoubleValue (3.0));
wifiPhy.SetChannel (wifiChannel.Create ());
// Add a non-QoS upper mac, and disable rate control (i.e. ConstantRateWifiManager)
NqosWifiMacHelper wifiMac = NqosWifiMacHelper::Default ();
wifi.SetRemoteStationManager ("ns3::ConstantRateWifiManager",
"DataMode",StringValue (phyMode),
"ControlMode",StringValue (phyMode));
// Set it to adhoc mode
wifiMac.SetType ("ns3::AdhocWifiMac");
NetDeviceContainer devices = wifi.Install (wifiPhy, wifiMac, c);
// Configure mobility
MobilityHelper mobility;
Ptr<ListPositionAllocator> positionAlloc = CreateObject<ListPositionAllocator> ();
positionAlloc->Add (Vector (0.0, 0.0, 0.0));
positionAlloc->Add (Vector (5.0, 0.0, 0.0));
mobility.SetPositionAllocator (positionAlloc);
mobility.SetMobilityModel ("ns3::ConstantPositionMobilityModel");
mobility.Install (c);
// other set up (e.g. InternetStack, Application)
Infrastructure (access point and clients) WifiNetDevice configuration
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
This is a typical example of how a user might configure an access point and a set of clients.
In this example, we create one access point and two clients.
Each node is equipped with 802.11b Wi-Fi device::
std::string phyMode ("DsssRate1Mbps");
NodeContainer ap;
ap.Create (1);
NodeContainer sta;
sta.Create (2);
WifiHelper wifi;
wifi.SetStandard (WIFI_PHY_STANDARD_80211b);
YansWifiPhyHelper wifiPhy = YansWifiPhyHelper::Default ();
// ns-3 supports RadioTap and Prism tracing extensions for 802.11
wifiPhy.SetPcapDataLinkType (YansWifiPhyHelper::DLT_IEEE802_11_RADIO);
YansWifiChannelHelper wifiChannel;
// reference loss must be changed since 802.11b is operating at 2.4GHz
wifiChannel.SetPropagationDelay ("ns3::ConstantSpeedPropagationDelayModel");
wifiChannel.AddPropagationLoss ("ns3::LogDistancePropagationLossModel",
"Exponent", DoubleValue (3.0),
"ReferenceLoss", DoubleValue (40.0459));
wifiPhy.SetChannel (wifiChannel.Create ());
// Add a non-QoS upper mac, and disable rate control
NqosWifiMacHelper wifiMac = NqosWifiMacHelper::Default ();
wifi.SetRemoteStationManager ("ns3::ConstantRateWifiManager",
"DataMode",StringValue (phyMode),
"ControlMode",StringValue (phyMode));
// Setup the rest of the upper mac
Ssid ssid = Ssid ("wifi-default");
// setup ap.
wifiMac.SetType ("ns3::ApWifiMac",
"Ssid", SsidValue (ssid));
NetDeviceContainer apDevice = wifi.Install (wifiPhy, wifiMac, ap);
NetDeviceContainer devices = apDevice;
// setup sta.
wifiMac.SetType ("ns3::StaWifiMac",
"Ssid", SsidValue (ssid),
"ActiveProbing", BooleanValue (false));
NetDeviceContainer staDevice = wifi.Install (wifiPhy, wifiMac, sta);
devices.Add (staDevice);
// Configure mobility
MobilityHelper mobility;
Ptr<ListPositionAllocator> positionAlloc = CreateObject<ListPositionAllocator> ();
positionAlloc->Add (Vector (0.0, 0.0, 0.0));
positionAlloc->Add (Vector (5.0, 0.0, 0.0));
positionAlloc->Add (Vector (0.0, 5.0, 0.0));
mobility.SetPositionAllocator (positionAlloc);
mobility.SetMobilityModel ("ns3::ConstantPositionMobilityModel");
mobility.Install (ap);
mobility.Install (sta);
// other set up (e.g. InternetStack, Application)
The WifiChannel and WifiPhy models
**********************************
The WifiChannel subclass can be used to connect together a set of
``ns3::WifiNetDevice`` network interfaces. The class ``ns3::WifiPhy`` is the
object within the WifiNetDevice that receives bits from the channel.
For the channel propagation modeling, the propagation module is used; see section :ref:`Propagation` for details.
This section summarizes the description of the BER calculations found in the
yans paper taking into account the Forward Error Correction present in 802.11a
and describes the algorithm we implemented to decide whether or not a packet can
be successfully received. See `"Yet Another Network Simulator"
<http://cutebugs.net/files/wns2-yans.pdf>`_ for more details.
The PHY layer can be in one of five states:
#. TX: the PHY is currently transmitting a signal on behalf of its associated
MAC
#. RX: the PHY is synchronized on a signal and is waiting until it has received
its last bit to forward it to the MAC.
#. IDLE: the PHY is not in the TX, RX, or CCA BUSY states.
#. CCA Busy: the PHY is not in TX or RX state but the measured energy is higher than the energy detection threshold.
#. SLEEP: the PHY is in a power save mode and cannot send nor receive frames.
When the first bit of a new packet is received while the PHY is not IDLE (that
is, it is already synchronized on the reception of another earlier packet or it
is sending data itself), the received packet is dropped. Otherwise, if the PHY
is IDLE or CCA Busy, we calculate the received energy of the first bit of this new signal
and compare it against our Energy Detection threshold (as defined by the Clear
Channel Assessment function mode 1). If the energy of the packet k is higher,
then the PHY moves to RX state and schedules an event when the last bit of the
packet is expected to be received. Otherwise, the PHY stays in IDLE
or CCA Busy state and drops the packet.
The energy of the received signal is assumed to be zero outside of the reception
interval of packet k and is calculated from the transmission power with a
path-loss propagation model in the reception interval. where the path loss
exponent, :math:`n`, is chosen equal to :math:`3`, the reference distance,
:math:`d_0` is choosen equal to :math:`1.0m` and the reference energy is based
based on a Friis propagation model.
When the last bit of the packet upon which the PHY is synchronized is received,
we need to calculate the probability that the packet is received with any error
to decide whether or not the packet on which we were synchronized could be
successfully received or not: a random number is drawn from a uniform
distribution and is compared against the probability of error.
To evaluate the probability of error, we start from the piecewise linear
functions shown in Figure :ref:`snir` and calculate the
SNIR function.
.. _snir:
.. figure:: figures/snir.*
*SNIR function over time.*
From the SNIR function we can derive the Bit Error Rate (BER) and Packet Error Rate (PER) for
the modulation and coding scheme being used for the transmission. Please refer to [pei80211ofdm]_, [pei80211b]_
and [lacage2006yans]_ for a detailed description of the available BER/PER models.
WifiChannel configuration
=========================
The WifiChannel implementation uses the propagation loss and delay models provided within the |ns3| :ref:`Propagation` module.
The MAC model
*************
The 802.11 Distributed Coordination Function is used to calculate when to grant
access to the transmission medium. While implementing the DCF would have been
particularly easy if we had used a recurring timer that expired every slot, we
chose to use the method described in [ji2004sslswn]_
where the backoff timer duration is lazily calculated whenever needed since it
is claimed to have much better performance than the simpler recurring timer
solution.
The backoff procedure of DCF is described in section 9.2.5.2 of [ieee80211]_.
* “The backoff procedure shall be invoked for a STA to transfer a frame
when finding the medium busy as indicated by either the physical or
virtual CS mechanism.”
* “A backoff procedure shall be performed immediately after the end of
every transmission with the More Fragments bit set to 0 of an MPDU of
type Data, Management, or Control with subtype PS-Poll, even if no
additional transmissions are currently queued.”
Thus, if the queue is empty, a newly arrived packet should be transmitted
immediately after channel is sensed idle for DIFS. If queue is not empty
and after a successful MPDU that has no more fragments, a node should
also start the backoff timer.
Some users have observed that the 802.11 MAC with an empty queue on an
idle channel will transmit the first frame arriving to the model
immediately without waiting for DIFS or backoff, and wonder whether this
is compliant. According to the standard, “The backoff procedure shall
be invoked for a STA to transfer a frame when finding the medium busy
as indicated by either the physical or virtual CS mechanism.” So in
this case, the medium is not found to be busy in recent past and the
station can transmit immediately.
The higher-level MAC functions are implemented in a set of other C++ classes and
deal with:
* packet fragmentation and defragmentation,
* use of the RTS/CTS protocol,
* rate control algorithm,
* connection and disconnection to and from an Access Point,
* the MAC transmission queue,
* beacon generation,
* MSDU aggregation,
* etc.
Rate control algorithms
***********************
Multiple rate control algorithms are available in |ns3|.
Some rate control algorithms are modeled after real algorithms used in real devices;
others are found in literature.
The following rate control algorithms can be used by the MAC low layer:
Algorithms found in real devices:
* ``ArfWifiManager`` (default for ``WifiHelper``)
* ``OnoeWifiManager``
* ``ConstantRateWifiManager``
* ``MinstrelWifiManager``
Algorithms in literature:
* ``IdealWifiManager``
* ``AarfWifiManager`` [lacage2004aarfamrr]_
* ``AmrrWifiManager`` [lacage2004aarfamrr]_
* ``CaraWifiManager`` [kim2006cara]_
* ``RraaWifiManager`` [wong2006rraa]_
* ``AarfcdWifiManager`` [maguolo2008aarfcd]_
ConstantRateWifiManager
=======================
The constant rate control algorithm always uses the same
transmission mode for every packet. Users can set a desired
'DataMode' for all 'unicast' packets and 'ControlMode' for all
'request' control packets (e.g. RTS).
To specify different data mode for non-unicast packets, users
must set the 'NonUnicastMode' attribute of the
WifiRemoteStationManager. Otherwise, WifiRemoteStationManager
will use a mode with the lowest rate for non-unicast packets.
The 802.11 standard is quite clear on the rules for selection
of transmission parameters for control response frames (e.g.
CTS and ACK). |ns3| follows the standard and selects the rate
of control response frames from the set of basic rates or
mandatory rates. This means that control response frames may
be sent using different rate even though the ConstantRateWifiManager
is used. The ControlMode attribute of the ConstantRateWifiManager
is used for RTS frames only. The rate of CTS and ACK frames are
selected according to the 802.11 standard. However, users can still
manually add WifiMode to the basic rate set that will allow control
response frames to be sent at other rates. Please consult the
`project wiki <http://www.nsnam.org/wiki>`_ on how to do this.
Available attributes:
* DataMode (default WifiMode::OfdmRate6Mbps): specify a mode for
all non-unicast packets
* ControlMode (default WifiMode::OfdmRate6Mbps): specify a mode for
all 'request' control packets
IdealWifiManager
================
The ideal rate control algorithm selects the best
mode according to the SNR of the previous packet sent.
Consider node *A* sending a unicast packet to node *B*.
When *B* successfully receives the packet sent from *A*,
*B* records the SNR of the received packet into a ``ns3::SnrTag``
and adds the tag to an ACK back to *A*.
By doing this, *A* is able to learn the SNR of the packet sent to *B*
using an out-of-band mechanism (thus the name 'ideal').
*A* then uses the SNR to select a transmission mode based
on a set of SNR thresholds, which was built from a target BER and
mode-specific SNR/BER curves.
Available attribute:
* BerThreshold (default 10e-6): The maximum Bit Error Rate
that is used to calculate the SNR threshold for each mode.
MinstrelWifiManager
===================
The minstrel rate control algorithm is a rate control algorithm originated from
madwifi project. It is currently the default rate control algorithm of the Linux kernel.
Minstrel keeps track of the probability of successfully sending a frame of each available rate.
Minstrel then calculates the expected throughput by multiplying the probability with the rate.
This approach is chosen to make sure that lower rates are not selected in favor of the higher
rates (since lower rates are more likely to have higher probability).
In minstrel, roughly 10 percent of transmissions are sent at the so-called lookaround rate.
The goal of the lookaround rate is to force minstrel to try higher rate than the currently used rate.
For a more detailed information about minstrel, see [linuxminstrel]_.
Modifying Wifi model
********************
Modifying the default wifi model is one of the common tasks when performing research.
We provide an overview of how to make changes to the default wifi model in this section.
Depending on your goal, the common tasks are (in no particular order):
* Creating or modifying the default Wi-Fi frames/headers by making changes to ``wifi-mac-header.*``.
* MAC low modification. For example, handling new/modified control frames (think RTS/CTS/ACK/Block ACK),
making changes to two-way transaction/four-way transaction. Users usually make changes to
``mac-low.*`` to accomplish this. Handling of control frames is performed in
``MacLow::ReceiveOk``.
* MAC high modification. For example, handling new management frames (think beacon/probe),
beacon/probe generation. Users usually make changes to ``regular-wifi-mac.*``,
``sta-wifi-mac.*``, ``ap-wifi-mac.*``, or ``adhoc-wifi-mac.*`` to accomplish this.
* Wi-Fi queue management. The files ``dca-txop.*`` and ``edca-txop-n.*`` are of interested for this task.
* Channel access management. Users should modify the files ``dcf-manager.*``, which grant access to
``DcaTxop`` and ``EdcaTxopN``.
* Fragmentation and RTS threholds are handled by Wi-Fi remote station manager. Note that Wi-Fi remote
station manager simply indicates if fragmentation and RTS are needed. Fragmentation is handled by
``DcaTxop`` or ``EdcaTxopN`` while RTS/CTS transaction is hanled by ``MacLow``.
* Modifying or creating new rate control algorithms can be done by creating a new child class of Wi-Fi remote
station manager or modifying the existing ones.
Note on the current implementation
**********************************
* 802.11g does not support 9 microseconds slot
* PHY_RXSTART is not supported
* 802.11e TXOP is not supported
* 802.11n MIMO is not supported
* MPDU aggregation is not supported
Wifi Tracing
************
Should link to the list of traces exported by Doxygen
References
**********
.. [ieee80211] IEEE Std 802.11-2007 *Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications*
.. [pei80211b] \G. Pei and Tom Henderson, `Validation of ns-3 802.11b PHY model <http://www.nsnam.org/~pei/80211b.pdf>`__
.. [pei80211ofdm] \G. Pei and Tom Henderson, `Validation of OFDM error rate model in ns-3 <http://www.nsnam.org/~pei/80211ofdm.pdf>`__
.. [lacage2006yans] \M. Lacage and T. Henderson, `Yet another Network Simulator <http://cutebugs.net/files/wns2-yans.pdf>`__
.. [ji2004sslswn] \Z. Ji, J. Zhou, M. Takai and R. Bagrodia, *Scalable simulation of large-scale wireless networks with bounded inaccuracies*, in Proc. of the Seventh ACM Symposium on Modeling, Analysis and Simulation of Wireless and Mobile Systems, October 2004.
.. [linuxminstrel] `minstrel linux wireless <http://wireless.kernel.org/en/developers/Documentation/mac80211/RateControl/minstrel>`_
.. [lacage2004aarfamrr] \ M. Lacage, H. Manshaei, and T. Turletti, *IEEE 802.11 rate adaptation: a practical approach*, in Proc. 7th ACM International Symposium on Modeling, Analysis and Simulation of Wireless and Mobile Systems, 2004.
.. [kim2006cara] \ J. Kim, S. Kim, S. Choi, and D. Qiao, *CARA: Collision-Aware Rate Adaptation for IEEE 802.11 WLANs*, in Proc. 25th IEEE International Conference on Computer Communications, 2006
.. [wong2006rraa] \ S. Wong, H. Yang, S. Lu, and V. Bharghavan, *Robust Rate Adaptation for 802.11 Wireless Networks*, in Proc. 12th Annual International Conference on Mobile Computing and Networking, 2006
.. [maguolo2008aarfcd] \ F. Maguolo, M. Lacage, and T. Turletti, *Efficient collision detection for auto rate fallback algorithm*, in IEEE Symposium on Computers and Communications, 2008