.. include:: replace.txt

Wifi NetDevice
--------------

|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. 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** and **802.11b** physical layers
* QoS-based EDCA and queueing extensions of **802.11e**
* various propagation loss models including **Nakagami, Rayleigh, Friis,
  LogDistance, FixedRss, Random**
* two propagation delay models, a distance-based and random model
* 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.

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

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) (implemented in class ``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. 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**.

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 QoS operations like 802.11n-style MSDU aggregation.

There are also several **rate control algorithms** that can be used by the Mac low layer:

* ``ns3::ArfMacStations``
* ``ns3::AArfMacStations``
* ``ns3::IdealMacStations``
* ``ns3::CrMacStations``
* ``ns3::OnoeMacStations``
* ``ns3::AmrrMacStations``

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>`_

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 ns-2. Presently, however, there is no model for
cross-channel interference or coupling.

The source code for the Wifi NetDevice lives in the directory
``src/devices/wifi``.

.. _wifi-architecture:

.. figure:: figures/WifiArchitecture.*
   
   Wifi NetDevice 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. The scripts in ``src/examples`` can be browsed to see how
this is done.

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.  Specifically, the default is a channel model with a
propagation delay equal to a constant, the speed of light, and a propagation
loss based on a log distance model with a reference loss of 46.6777 dB at
reference distance of 1m.

Users will typically type code such as:::

  YansWifiChannelHelper wifiChannelHelper = YansWifiChannelHelper::Default ();
  Ptr<WifiChannel> wifiChannel = wifiChannelHelper.Create ();

to get the defaults.  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 on
:ref:`Object model` for a discussion of the |ns3| object model, if you are not
familiar with it.

*Todo: Add notes about how to configure attributes with this helper API*

YansWifiPhyHelper
+++++++++++++++++

Physical devices (base class ``ns3::Phy``) connect to ``ns3::Channel`` models in
|ns3|.  We need to create Phy 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);

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.

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 support enabled. 

For example the following user code configures a non-QoS 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``.  This object can be also used to set:

* a 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.

The following code shows an example use of ``ns3::QosWifiMacHelper`` to 
create an AP with QoS enabled, aggregation on AC_VO, and Block Ack on AC_BE:::

  QosWifiMacHelper wifiMacHelper = QosWifiMacHelper::Default ();
  wifiMacHelper.SetType ("ns3::ApWifiMac",
                         "Ssid", SsidValue (ssid),
                         "BeaconGeneration", BooleanValue (true),
                         "BeaconInterval", TimeValue (Seconds (2.5)));
  wifiMacHelper.SetMsduAggregatorForAc (AC_VO, "ns3::MsduStandardAggregator",
                                        "MaxAmsduSize", UintegerValue (3839));
  wifiMacHelper.SetBlockAckThresholdForAc (AC_BE, 10);
  wifiMacHelper.SetBlockAckInactivityTimeoutForAc (AC_BE, 5);

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 RemoteStationManager to
``ns3::ArfWifiManager``.
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| :ref:`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.

AdHoc WifiNetDevice configuration 
+++++++++++++++++++++++++++++++++

This is a typical example of how a user might configure an adhoc network.

*To be completed*

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. 

*To be completed*

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.  A
WifiChannel contains a ``ns3::PropagationLossModel`` and a
``ns3::PropagationDelayModel`` which can be overridden by the
WifiChannel::SetPropagationLossModel and the
WifiChannel::SetPropagationDelayModel methods. By default, no propagation models
are set.

The WifiPhy models an 802.11a channel, in terms of frequency, modulation, and
bit rates, and interacts with the PropagationLossModel and PropagationDelayModel
found in the channel.  

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 three 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 or RX states.

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, 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 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 bit error rates for BPSK and QAM
modulations.  Then, for each interval l where BER is constant, we define the
upper bound of a probability that an error is present in the chunk of bits
located in the interval l for packet k.  If we assume an AWGN channel, binary
convolutional coding (which is the case in 802.11a) and hard-decision Viterbi
decoding, the error rate is thus derived, and the packet error probability for
packet k can be computed. 

WifiChannel configuration
+++++++++++++++++++++++++

WifiChannel models include both a PropagationDelayModel and a 
PropagationLossModel. The following PropagationDelayModels are available:

* ConstantSpeedPropagationDelayModel
* RandomPropagationDelayModel

The following PropagationLossModels are available:

* RandomPropagationLossModel
* FriisPropagationLossModel
* LogDistancePropagationLossModel
* JakesPropagationLossModel
* CompositePropagationLossModel

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 *(missing reference here from Yans paper)*
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 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.

Wifi Attributes
***************

The WifiNetDevice makes heavy use of the |ns3| :ref:`Attributes` subsystem for
configuration and default value management. Presently, approximately 100 values
are stored in this system.

For instance, class ``ns-3::WifiMac`` exports these attributes:

* CtsTimeout: When this timeout expires, the RTS/CTS handshake has failed.
* AckTimeout: When this timeout expires, the DATA/ACK handshake has failed.
* Sifs: The value of the SIFS constant.
* EifsNoDifs: The value of EIFS-DIFS
* Slot: The duration of a Slot.
* Pifs: The value of the PIFS constant.
* MaxPropagationDelay: The maximum propagation delay. Unused for now.
* MaxMsduSize: The maximum size of an MSDU accepted by the MAC layer.This value
  conforms to the specification.
* Ssid: The ssid we want to belong to.

Wifi Tracing
************

*This needs revised/updating based on the latest Doxygen*

|ns3| has a sophisticated tracing infrastructure that allows users to hook into
existing trace sources, or to define and export new ones.  

Wifi-related trace sources that are available by default include:::

* ``ns3::WifiNetDevice``

    * Rx: Received payload from the MAC layer.
    * Tx: Send payload to the MAC layer.

* ``ns3::WifiPhy``

    * State: The WifiPhy state
    * RxOk: A packet has been received successfully.
    * RxError: A packet has been received unsuccessfully.
    * Tx: Packet transmission is starting.

Briefly, this means, for example, that a user can hook a processing function to
the "State" tracing hook above and be notified whenever the WifiPhy model
changes state.