ns3::HalfDuplexIdealPhy Class Reference

#include <half-duplex-ideal-phy.h>

Inheritance diagram for ns3::HalfDuplexIdealPhy:

Collaboration diagram for ns3::HalfDuplexIdealPhy:

Public Types
enum	State { IDLE, TX, RX }
Public Member Functions
void	SetChannel (Ptr< SpectrumChannel > c)
void	SetMobility (Ptr< Object > m)
void	SetDevice (Ptr< Object > d)
Ptr< Object >	GetMobility ()
Ptr< Object >	GetDevice ()
Ptr< const SpectrumModel >	GetRxSpectrumModel () const
void	StartRx (Ptr< PacketBurst > p, Ptr< const SpectrumValue > rxPsd, SpectrumType st, Time duration)
SpectrumType	GetSpectrumType ()
void	SetTxPowerSpectralDensity (Ptr< SpectrumValue > txPsd)
void	SetNoisePowerSpectralDensity (Ptr< const SpectrumValue > noisePsd)
bool	StartTx (Ptr< Packet > p)
void	SetRate (DataRate rate)
DataRate	GetRate () const
void	SetPhyMacTxEndCallback (PhyMacTxEndCallback c)
void	SetPhyMacRxStartCallback (PhyMacRxStartCallback c)
void	SetPhyMacRxEndErrorCallback (PhyMacRxEndErrorCallback c)
void	SetPhyMacRxEndOkCallback (PhyMacRxEndOkCallback c)
Static Public Member Functions
static TypeId	GetTypeId (void)
	This method returns the TypeId associated to ns3::HalfDuplexIdealPhy.

Detailed Description

This PHY layer implementation realizes an ideal OFDM PHY which transmits half-duplex (i.e., it can either receive or transmit at a given time). The device is ideal in the sense that: 1) it uses an error model based on the Shannon capacity, which assumes ideal channel coding; 2) it uses ideal signal acquisition, i.e., preamble detection and synchronization are always successful 3) it has no PHY layer overhead

Being half duplex, if a RX is ongoing but a TX is requested, the RX is aborted and the TX is started. Of course, no RX can be performed while there is an ongoing TX.

The use of OFDM is modeled by means of the Spectrum framework. By calling the method SetTxPowerSpectralDensity(), the user can specify how much of the spectrum is used, how many subcarriers are used, and what power is allocated to each subcarrier.

The user can also specify the PHY rate at which communications take place by using SetRate(). This is equivalent to choosing a particular modulation and coding scheme.

The use of the ShannonSpectrumErrorModel allows us to account for the following aspects in determining whether a transmission is successful or not:

the PHY rate (trades off communication speed with reliability)
the power spectral density (trade-off among total power consumed, total bandwidth used (i.e., how much of the spectrum is occupied), and communication reliability)
the signal propagation

Member Enumeration Documentation

enum ns3::HalfDuplexIdealPhy::State

PHY states

Member Function Documentation

Ptr<Object> ns3::HalfDuplexIdealPhy::GetDevice ( ) [virtual]

get the associated NetDevice instance

Returns:: a Ptr to the associated NetDevice instance

Implements ns3::SpectrumPhy.

Ptr<Object> ns3::HalfDuplexIdealPhy::GetMobility ( ) [virtual]

get the associated MobilityModel instance

Returns:: a Ptr to the associated NetDevice instance

Implements ns3::SpectrumPhy.

DataRate ns3::HalfDuplexIdealPhy::GetRate ( ) const

Returns:: the PHY rate used by this PHY.

Ptr<const SpectrumModel> ns3::HalfDuplexIdealPhy::GetRxSpectrumModel ( ) const [virtual]

Returns:: returns the SpectrumModel that this SpectrumPhy expects to be used for all SpectrumValues that are passed to StartRx. If 0 is returned, it means that any model will be accepted.

Implements ns3::SpectrumPhy.

SpectrumType ns3::HalfDuplexIdealPhy::GetSpectrumType ( )

Get the SpectrumType used by this PHY

Returns:

static TypeId ns3::HalfDuplexIdealPhy::GetTypeId ( void ) [static]

This method returns the TypeId associated to ns3::HalfDuplexIdealPhy.

This object is accessible through the following paths with Config::Set and Config::Connect:

/NodeList/[i]/DeviceList/[i]/$ns3::AlohaNoackNetDevice/Phy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::AlohaNoackNetDevice/Phy/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/BsIpcsPacketClassifier/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/BsIpcsPacketClassifier/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/LinkManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/LinkManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/SSManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/SSManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/ServiceFlowManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::BaseStationNetDevice/ServiceFlowManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::NonCommunicatingNetDevice/Phy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::NonCommunicatingNetDevice/Phy/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/Classifier/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/Classifier/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/LinkManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/LinkManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/SSScheduler/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::SubscriberStationNetDevice/SSScheduler/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Channel/NoiseModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Channel/NoiseModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Channel/PropagationModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Channel/PropagationModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Mac/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Mac/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Phy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Phy/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Transducer/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::UanNetDevice/Transducer/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/BsIpcsPacketClassifier/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/BsIpcsPacketClassifier/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/LinkManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/LinkManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/SSManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/SSManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/ServiceFlowManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::BaseStationNetDevice/ServiceFlowManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/Classifier/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/Classifier/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/LinkManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/LinkManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/SSScheduler/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/$ns3::SubscriberStationNetDevice/SSScheduler/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/BandwidthManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/BandwidthManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/BurstProfileManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/BurstProfileManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Channel/$ns3::UanChannel/NoiseModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Channel/$ns3::UanChannel/NoiseModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Channel/$ns3::UanChannel/PropagationModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Channel/$ns3::UanChannel/PropagationModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/ConnectionManager/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/ConnectionManager/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Phy/Channel/$ns3::UanChannel/NoiseModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Phy/Channel/$ns3::UanChannel/NoiseModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Phy/Channel/$ns3::UanChannel/PropagationModel/$ns3::HalfDuplexIdealPhy
/NodeList/[i]/DeviceList/[i]/$ns3::WimaxNetDevice/Phy/Channel/$ns3::UanChannel/PropagationModel/$ns3::SpectrumPhy/$ns3::HalfDuplexIdealPhy

Attributes defined for this type:

Rate: The PHY rate used by this device
- Set with class: DataRateValue
- Underlying type: DataRate
- Initial value: 1000000bps
- Flags: construct write read

TraceSources defined for this type:

TxStart: Trace fired when a new transmission is started
TxEnd: Trace fired when a previosuly started transmission is finished
RxStart: Trace fired when the start of a signal is detected
RxAbort: Trace fired when a previously started RX is aborted before time
RxEndOk: Trace fired when a previosuly started RX terminates successfully
RxEndError: Trace fired when a previosuly started RX terminates with an error (packet is corrupted)

Reimplemented from ns3::SpectrumPhy.

void ns3::HalfDuplexIdealPhy::SetChannel ( Ptr< SpectrumChannel > c ) [virtual]

Set the channel attached to this device.

Parameters:

c

the channel

Implements ns3::SpectrumPhy.

void ns3::HalfDuplexIdealPhy::SetDevice ( Ptr< Object > d ) [virtual]

set the associated NetDevice instance

Parameters:

d

the NetDevice instance

Implements ns3::SpectrumPhy.

void ns3::HalfDuplexIdealPhy::SetMobility ( Ptr< Object > m ) [virtual]

Set the mobility model associated with this device.

Parameters:

m

the mobility model

Implements ns3::SpectrumPhy.

void ns3::HalfDuplexIdealPhy::SetNoisePowerSpectralDensity ( Ptr< const SpectrumValue > noisePsd )

Parameters:

noisePsd

the Noise Power Spectral Density in power units (Watt, Pascal...) per Hz.

void ns3::HalfDuplexIdealPhy::SetPhyMacRxEndErrorCallback ( PhyMacRxEndErrorCallback c )

set the callback for the end of a RX in error, as part of the interconnections betweenthe PHY and the MAC

Parameters:

c

the callback

void ns3::HalfDuplexIdealPhy::SetPhyMacRxEndOkCallback ( PhyMacRxEndOkCallback c )

set the callback for the successful end of a RX, as part of the interconnections betweenthe PHY and the MAC

Parameters:

c

the callback

void ns3::HalfDuplexIdealPhy::SetPhyMacRxStartCallback ( PhyMacRxStartCallback c )

set the callback for the start of RX, as part of the interconnections betweenthe PHY and the MAC

Parameters:

c

the callback

void ns3::HalfDuplexIdealPhy::SetPhyMacTxEndCallback ( PhyMacTxEndCallback c )

set the callback for the end of a TX, as part of the interconnections betweenthe PHY and the MAC

Parameters:

c

the callback

void ns3::HalfDuplexIdealPhy::SetRate ( DataRate rate )

set the PHY rate to be used by this PHY.

Parameters:

rate

void ns3::HalfDuplexIdealPhy::SetTxPowerSpectralDensity ( Ptr< SpectrumValue > txPsd )

set the Power Spectral Density of outgoing signals in power units (Watt, Pascal...) per Hz.

Parameters:

txPsd

void ns3::HalfDuplexIdealPhy::StartRx	(	Ptr< PacketBurst >	p,
		Ptr< const SpectrumValue >	rxPsd,
		SpectrumType	st,
		Time	duration
	)			`[virtual]`

Notify the SpectrumPhy instance of an incoming waveform

Parameters:

	p	the PacketBurst associated with the incoming waveform
	rxPsd	the Power Spectral Density of the incoming waveform. The units of the PSD are the same specified for SpectrumChannel::StartTx().
	st	spectrum type
	duration	the duration of the incoming waveform

Implements ns3::SpectrumPhy.

bool ns3::HalfDuplexIdealPhy::StartTx ( Ptr< Packet > p )

Start a transmission

Parameters:

p

the packet to be transmitted

Returns:: true if an error occurred and the transmission was not started, false otherwise.

The documentation for this class was generated from the following files:

src/devices/spectrum/half-duplex-ideal-phy.h
doc/introspected-doxygen.h

ns3::HalfDuplexIdealPhy Class Reference

Public Types

Public Member Functions

Static Public Member Functions

Detailed Description

Member Enumeration Documentation

Member Function Documentation