Description

Provides access to the properties and methods defining an Transmitter object.

Public Methods

IsRefractionTypeSupported	Gets a value indicating whether the specified type can be used
SetModel	Sets the current transmitter model by name.

Public Properties

Graphics	Get the 2D Graphics properties for the transmitter.
LaserEnvironment	Gets the object laser environment settings.
Model	Gets the current transmitter model.
Refraction	Refraction method, a member of the AgESnRefractionType enumeration.
RefractionModel	Gets a refraction model
RefractionSupportedTypes	Returns an array of valid choices
RFEnvironment	Gets the object RF environment settings.
SupportedModels	Gets an array of supported model names.
UseRefractionInAccess	Flag controls whether refraction is applied when computing relative position in Access
VO	Get the 3D Graphics properties for the transmitter.

Interfaces

Implemented Interface
IAgStkObject
IAgLifetimeInformation
IAgDisplayTm

CoClasses that Implement IAgTransmitter

Name
AgTransmitter

Example

Compute a link budget for a Transmtiter and Receiver pair, using simple models

[C#]

IAgStkObject xmtrAsStkObject = geoTransmitter as IAgStkObject;
IAgStkObject rcvrAsStkObject = facilityReceiver as IAgStkObject;

//Set the transmitter to the simple model
geoTransmitter.SetModel("Simple Transmitter Model");
IAgTransmitterModelSimple simpleTrans = geoTransmitter.Model as IAgTransmitterModelSimple;

//Set the simple transmitter model's frequency to 3.2 GHz
simpleTrans.Frequency = 3.2;

//Set the simple transmitter model's EIRP to 60 dBW
simpleTrans.Eirp = 60.0;

//Set the receiver to the simple model
facilityReceiver.SetModel("Simple Receiver Model");
IAgReceiverModelSimple simpleRcvr = facilityReceiver.Model as IAgReceiverModelSimple;

//Set the simple receiver model's G/T to 60 dB/K
simpleRcvr.GOverT = 60.0;

//Create an access object for the access between the transmitter and recevier objects
IAgStkAccess linkAccess = xmtrAsStkObject.GetAccessToObject(rcvrAsStkObject);

//Compute access
linkAccess.ComputeAccess();

// Get the access intervals 
IAgIntervalCollection accessIntervals = linkAccess.ComputedAccessIntervalTimes;

// Extract the access intervals and the range information for each access interval 
Array dataPrvElements = new object[] { "Time", "Eb/No", "BER" };

IAgDataPrvTimeVar dp = linkAccess.DataProviders["Link Information"] as IAgDataPrvTimeVar;

for (int index0 = 0; index0 < accessIntervals.Count; ++index0)
{
    object startTime = null, stopTime = null;
    accessIntervals.GetInterval(index0, out startTime, out stopTime);

    IAgDrResult result = dp.ExecElements(startTime, stopTime, 60, ref dataPrvElements);

    Array timeValues = result.DataSets[0].GetValues();
    Array ebno = result.DataSets[1].GetValues();
    Array ber = result.DataSets[2].GetValues();

    for (int index1 = 0; index1 < timeValues.GetLength(0); ++index1)
    {
        string time = (string)timeValues.GetValue(index1);
        double ebnoVal = (double)ebno.GetValue(index1);
        double berVal = (double)ber.GetValue(index1);
        Console.WriteLine("{0}: Eb/No={1} BER={2}", time, ebnoVal, berVal);
    }

    Console.WriteLine();
}

Compute a link budget for a Transmtiter and Receiver pair, using complex models

[C#]

IAgStkObject xmtrAsStkObject = geoTransmitter as IAgStkObject;
IAgStkObject rcvrAsStkObject = facilityReceiver as IAgStkObject;

//Enable the rain loss computation on the scenario RF environment
scenarioRFEnv.PropagationChannel.EnableRainLoss = true;

//Set the transmitter to the complex model
geoTransmitter.SetModel("Complex Transmitter Model");
IAgTransmitterModelComplex complexTrans = geoTransmitter.Model as IAgTransmitterModelComplex;

//Set the complex transmitter model's frequency to 3.2 GHz
complexTrans.Frequency = 3.2;

//Set the complex transmitter model's Power to 50 dBW
complexTrans.Power = 50.0;

//Set the complex transmitter's embedded antenna model to helix
complexTrans.AntennaControl.SetEmbeddedModel("Helix");

//Set the beamwidth of the parablic antenna to 2 degrees
IAgAntennaModelHelix helix = complexTrans.AntennaControl.EmbeddedModel as IAgAntennaModelHelix;
helix.NumberOfTurns = 30.0;

//Orient the complex transmitter embedded antenna's boresight to point directly at the receiver's location
complexTrans.AntennaControl.EmbeddedModelOrientation.AssignAzEl(287.2, 83.4, AgEAzElAboutBoresight.eAzElAboutBoresightRotate);

//Set the receiver to the complex model
facilityReceiver.SetModel("Complex Receiver Model");
IAgReceiverModelComplex complexRcvr = facilityReceiver.Model as IAgReceiverModelComplex;

//Configure the complex receiver to use the antenna object on the same parent facility, by linking
complexRcvr.AntennaControl.ReferenceType = AgEAntennaControlRefType.eAntennaControlRefTypeLink;
complexRcvr.AntennaControl.LinkedAntennaObject = "Antenna/FacilityDish";

//Enable rain loss computation on the receiver
complexRcvr.UseRain = true;
complexRcvr.RainOutagePercent = 0.001;

//Enable the receiver system noise temperature computation.
complexRcvr.SystemNoiseTemperature.ComputeType = AgENoiseTempComputeType.eNoiseTempComputeTypeCalculate;

//Enable the antenna noise temperature computation
complexRcvr.SystemNoiseTemperature.AntennaNoiseTemperature.ComputeType = AgENoiseTempComputeType.eNoiseTempComputeTypeCalculate;
complexRcvr.SystemNoiseTemperature.AntennaNoiseTemperature.UseRain = true;

//Orient the antenna object's boresight to point directly at the transmitter's location
facilityDish.Orientation.AssignAzEl(202.6, 41.2, AgEAzElAboutBoresight.eAzElAboutBoresightRotate);

//Set the antenna object's model to parabolic
facilityDish.SetModel("Parabolic");

//Set the antenan object's design frequency to match the transmitter's 3.2 GHz
facilityDish.Model.DesignFrequency = 3.2;

//Set the antenna object's parabolic model diameter to 5 m.
IAgAntennaModelParabolic parabolic = facilityDish.Model as IAgAntennaModelParabolic;
parabolic.InputType = AgEAntennaModelInputType.eAntennaModelInputTypeDiameter;
parabolic.Diameter = 5.0;

//Create an access object for the access between the transmitter and recevier objects
IAgStkAccess linkAccess = xmtrAsStkObject.GetAccessToObject(rcvrAsStkObject);

//Compute access
linkAccess.ComputeAccess();

// Get the access intervals 
IAgIntervalCollection accessIntervals = linkAccess.ComputedAccessIntervalTimes;

// Extract the access intervals and the range information for each access interval 
Array dataPrvElements = new object[] { "Time", "Xmtr Gain", "Rcvr Gain", "Eb/No", "BER" };

IAgDataPrvTimeVar dp = linkAccess.DataProviders["Link Information"] as IAgDataPrvTimeVar;

for (int index0 = 0; index0 < accessIntervals.Count; ++index0)
{
    object startTime = null, stopTime = null;

    accessIntervals.GetInterval(index0, out startTime, out stopTime);

    IAgDrResult result = dp.ExecElements(startTime, stopTime, 60, ref dataPrvElements);

    Array timeValues = result.DataSets[0].GetValues();
    Array xmtrGain = result.DataSets[1].GetValues();
    Array rcvrGain = result.DataSets[2].GetValues();
    Array ebno = result.DataSets[3].GetValues();
    Array ber = result.DataSets[4].GetValues();

    for (int index1 = 0; index1 < timeValues.GetLength(0); ++index1)
    {
        string time = (string)timeValues.GetValue(index1);
        double xmtrGainVal = (double)xmtrGain.GetValue(index1);
        double rcvrGainVal = (double)rcvrGain.GetValue(index1);
        double ebnoVal = (double)ebno.GetValue(index1);
        double berVal = (double)ber.GetValue(index1);
        Console.WriteLine("{0}: Xmtr Gain = {1} Rcvr Gain = {2} Eb/No={3} BER={4}", time, xmtrGainVal, rcvrGainVal, ebnoVal, berVal);
    }

    Console.WriteLine();
}

Compute a link budget for a Transmtiter and Receiver pair, using simple models

[Visual Basic .NET]

Dim xmtrAsStkObject As IAgStkObject = TryCast(geoTransmitter, IAgStkObject)
Dim rcvrAsStkObject As IAgStkObject = TryCast(facilityReceiver, IAgStkObject)

'Set the transmitter to the simple model
geoTransmitter.SetModel("Simple Transmitter Model")
Dim simpleTrans As IAgTransmitterModelSimple = TryCast(geoTransmitter.Model, IAgTransmitterModelSimple)

'Set the simple transmitter model's frequency to 3.2 GHz
simpleTrans.Frequency = 3.2

'Set the simple transmitter model's EIRP to 60 dBW
simpleTrans.Eirp = 60

'Set the receiver to the simple model
facilityReceiver.SetModel("Simple Receiver Model")
Dim simpleRcvr As IAgReceiverModelSimple = TryCast(facilityReceiver.Model, IAgReceiverModelSimple)

'Set the simple receiver model's G/T to 60 dB/K
simpleRcvr.GOverT = 60

'Create an access object for the access between the transmitter and recevier objects
Dim linkAccess As IAgStkAccess = xmtrAsStkObject.GetAccessToObject(rcvrAsStkObject)

'Compute access
linkAccess.ComputeAccess()

' Get the access intervals 
Dim accessIntervals As IAgIntervalCollection = linkAccess.ComputedAccessIntervalTimes

' Extract the access intervals and the range information for each access interval 
Dim dataPrvElements As Array = New Object() {"Time", "Eb/No", "BER"}

Dim dp As IAgDataPrvTimeVar = TryCast(linkAccess.DataProviders("Link Information"), IAgDataPrvTimeVar)

Dim index0 As Integer = 0
While index0 < accessIntervals.Count
	Dim startTime As Object = Nothing, stopTime As Object = Nothing
	accessIntervals.GetInterval(index0, startTime, stopTime)

	Dim result As IAgDrResult = dp.ExecElements(startTime, stopTime, 60, dataPrvElements)

	Dim timeValues As Array = result.DataSets(0).GetValues()
	Dim ebno As Array = result.DataSets(1).GetValues()
	Dim ber As Array = result.DataSets(2).GetValues()

	Dim index1 As Integer = 0
	While index1 < timeValues.GetLength(0)
		Dim time As String = DirectCast(timeValues.GetValue(index1), String)
		Dim ebnoVal As Double = DirectCast(ebno.GetValue(index1), Double)
		Dim berVal As Double = DirectCast(ber.GetValue(index1), Double)
		Console.WriteLine("{0}: Eb/No={1} BER={2}", time, ebnoVal, berVal)
		System.Threading.Interlocked.Increment(index1)
	End While

	Console.WriteLine()
	System.Threading.Interlocked.Increment(index0)
End While

Compute a link budget for a Transmtiter and Receiver pair, using complex models

[Visual Basic .NET]

Dim xmtrAsStkObject As IAgStkObject = TryCast(geoTransmitter, IAgStkObject)
Dim rcvrAsStkObject As IAgStkObject = TryCast(facilityReceiver, IAgStkObject)

'Enable the rain loss computation on the scenario RF environment
scenarioRFEnv.PropagationChannel.EnableRainLoss = True

'Set the transmitter to the complex model
geoTransmitter.SetModel("Complex Transmitter Model")
Dim complexTrans As IAgTransmitterModelComplex = TryCast(geoTransmitter.Model, IAgTransmitterModelComplex)

'Set the complex transmitter model's frequency to 3.2 GHz
complexTrans.Frequency = 3.2

'Set the complex transmitter model's Power to 50 dBW
complexTrans.Power = 50

'Set the complex transmitter's embedded antenna model to helix
complexTrans.AntennaControl.SetEmbeddedModel("Helix")

'Set the beamwidth of the parablic antenna to 2 degrees
Dim helix As IAgAntennaModelHelix = TryCast(complexTrans.AntennaControl.EmbeddedModel, IAgAntennaModelHelix)
helix.NumberOfTurns = 30

'Orient the complex transmitter embedded antenna's boresight to point directly at the receiver's location
complexTrans.AntennaControl.EmbeddedModelOrientation.AssignAzEl(287.2, 83.4, AgEAzElAboutBoresight.eAzElAboutBoresightRotate)

'Set the receiver to the complex model
facilityReceiver.SetModel("Complex Receiver Model")
Dim complexRcvr As IAgReceiverModelComplex = TryCast(facilityReceiver.Model, IAgReceiverModelComplex)

'Configure the complex receiver to use the antenna object on the same parent facility, by linking
complexRcvr.AntennaControl.ReferenceType = AgEAntennaControlRefType.eAntennaControlRefTypeLink
complexRcvr.AntennaControl.LinkedAntennaObject = "Antenna/FacilityDish"

'Enable rain loss computation on the receiver
complexRcvr.UseRain = True
complexRcvr.RainOutagePercent = 0.001

'Enable the receiver system noise temperature computation.
complexRcvr.SystemNoiseTemperature.ComputeType = AgENoiseTempComputeType.eNoiseTempComputeTypeCalculate

'Enable the antenna noise temperature computation
complexRcvr.SystemNoiseTemperature.AntennaNoiseTemperature.ComputeType = AgENoiseTempComputeType.eNoiseTempComputeTypeCalculate
complexRcvr.SystemNoiseTemperature.AntennaNoiseTemperature.UseRain = True

'Orient the antenna object's boresight to point directly at the transmitter's location
facilityDish.Orientation.AssignAzEl(202.6, 41.2, AgEAzElAboutBoresight.eAzElAboutBoresightRotate)

'Set the antenna object's model to parabolic
facilityDish.SetModel("Parabolic")

'Set the antenan object's design frequency to match the transmitter's 3.2 GHz
facilityDish.Model.DesignFrequency = 3.2

'Set the antenna object's parabolic model diameter to 5 m.
Dim parabolic As IAgAntennaModelParabolic = TryCast(facilityDish.Model, IAgAntennaModelParabolic)
parabolic.InputType = AgEAntennaModelInputType.eAntennaModelInputTypeDiameter
parabolic.Diameter = 5

'Create an access object for the access between the transmitter and recevier objects
Dim linkAccess As IAgStkAccess = xmtrAsStkObject.GetAccessToObject(rcvrAsStkObject)

'Compute access
linkAccess.ComputeAccess()

' Get the access intervals 
Dim accessIntervals As IAgIntervalCollection = linkAccess.ComputedAccessIntervalTimes

' Extract the access intervals and the range information for each access interval 
Dim dataPrvElements As Array = New Object() {"Time", "Xmtr Gain", "Rcvr Gain", "Eb/No", "BER"}

Dim dp As IAgDataPrvTimeVar = TryCast(linkAccess.DataProviders("Link Information"), IAgDataPrvTimeVar)

Dim index0 As Integer = 0
While index0 < accessIntervals.Count
	Dim startTime As Object = Nothing, stopTime As Object = Nothing

	accessIntervals.GetInterval(index0, startTime, stopTime)

	Dim result As IAgDrResult = dp.ExecElements(startTime, stopTime, 60, dataPrvElements)

	Dim timeValues As Array = result.DataSets(0).GetValues()
	Dim xmtrGain As Array = result.DataSets(1).GetValues()
	Dim rcvrGain As Array = result.DataSets(2).GetValues()
	Dim ebno As Array = result.DataSets(3).GetValues()
	Dim ber As Array = result.DataSets(4).GetValues()

	Dim index1 As Integer = 0
	While index1 < timeValues.GetLength(0)
		Dim time As String = DirectCast(timeValues.GetValue(index1), String)
		Dim xmtrGainVal As Double = DirectCast(xmtrGain.GetValue(index1), Double)
		Dim rcvrGainVal As Double = DirectCast(rcvrGain.GetValue(index1), Double)
		Dim ebnoVal As Double = DirectCast(ebno.GetValue(index1), Double)
		Dim berVal As Double = DirectCast(ber.GetValue(index1), Double)
		Console.WriteLine("{0}: Xmtr Gain = {1} Rcvr Gain = {2} Eb/No={3} BER={4}", time, xmtrGainVal, rcvrGainVal, ebnoVal, berVal)
		System.Threading.Interlocked.Increment(index1)
	End While

	Console.WriteLine()
	System.Threading.Interlocked.Increment(index0)
End While

Create a New Transmitter Object

[Python - STK API]

# IAgStkObject satellite: STK object
transmitter = satellite.Children.New(AgESTKObjectType.eTransmitter, 'MyTransmitter')

Modify Transmitter Model Type

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model')
txModel = transmitter.Model
txModel.Frequency = 14  # GHz
txModel.Power = 25  # dBW
txModel.DataRate = 15  # Mb/sec

Modify Transmitter Embedded Antenna

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
transmitter.SetModel("Complex Transmitter Model")
txModel = transmitter.Model
antennaControl = txModel.AntennaControl
antennaControl.SetEmbeddedModel('Isotropic')
antennaControl.EmbeddedModel.Efficiency = 85  # Percent

Modify Transmitter Polarization Properties

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
transmitter.SetModel("Complex Transmitter Model")
txModel = transmitter.Model
txModel.EnablePolarization = True
txModel.SetPolarizationType(AgEPolarizationType.ePolarizationTypeLinear)
polarization = txModel.Polarization
polarization.ReferenceAxis = AgEPolarizationReferenceAxis.ePolarizationReferenceAxisY
polarization.TiltAngle = 15  # deg

Modify Transmitter Orientation and Position

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
transmitter.SetModel("Complex Transmitter Model")
txModel = transmitter.Model
antennaControl = txModel.AntennaControl
antOrientation = antennaControl.EmbeddedModelOrientation
antOrientation.AssignAzEl(0, 90, 1)  # 1 represents Rotate About Boresight
antOrientation.PositionOffset.X = 0.0  # m
antOrientation.PositionOffset.Y = 1  # m
antOrientation.PositionOffset.Z = 0.25  # m

Modify Transmitter Modulator Properties

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model
txModel.SetModulator('BPSK')
txModel.Modulator.AutoScaleBandwidth = True

Modify Transmitter Filter

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model
txModel.EnableFilter = True
txModel.SetFilter('Butterworth')
recFilter = txModel.Filter
recFilter.LowerBandwidthLimit = -20
recFilter.UpperBandwidthLimit = 20
recFilter.CutoffFrequency = 10

Transmitter additional Gain

[Python - STK API]

# IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model
gain = txModel.PostTransmitGainsLosses.Add(-5)  # dB
gain.Identifier = 'Example Loss'

Create a New Transmitter Object

[MATLAB]

% IAgStkObject satellite: STK object
transmitter = satellite.Children.New('eTransmitter', 'MyTransmitter');

Modify Transmitter Model Type

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model');
txModel = transmitter.Model;
txModel.Frequency = 14; % GHz
txModel.Power = 25; % dBW
txModel.DataRate = 15; % Mb/sec

Modify Transmitter Embedded Antenna

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model');
txModel = transmitter.Model;
antennaControl = txModel.AntennaControl;
antennaControl.SetEmbeddedModel('Isotropic');
antennaControl.EmbeddedModel.Efficiency = 85; % Percent

Modify the Linked Antenna

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model')
transmitter.Model.AntennaControl.ReferenceType = 'eAntennaControlRefTypeLink';
transmitter.Model.AntennaControl.LinkedAntennaObject = 'Antenna/MyAntenna';

Modify Transmitter Polarization Properties

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model');
txModel = transmitter.Model;
txModel.EnablePolarization = true;
txModel.SetPolarizationType('ePolarizationTypeLinear');
polarization = txModel.Polarization;
polarization.ReferenceAxis = 'ePolarizationReferenceAxisY';
polarization.TiltAngle = 15; % deg

Modify Transmitter Orientation and Position

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
transmitter.SetModel('Complex Transmitter Model');
txModel = transmitter.Model;
antennaControl = txModel.AntennaControl;
antOrientation = antennaControl.EmbeddedModelOrientation;
antOrientation.AssignAzEl(0, 90, 1); % 1 represents Rotate About Boresight
antOrientation.PositionOffset.X = 0.0; % m
antOrientation.PositionOffset.Y = 1; % m
antOrientation.PositionOffset.Z = 0.25; % m

Modify Transmitter Modulator Properties

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model;
txModel.SetModulator('BPSK');
txModel.Modulator.AutoScaleBandwidth = true;

Modify Transmitter Filter

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model;
txModel.EnableFilter = true;
txModel.SetFilter('Butterworth');
recFilter = txModel.Filter;
recFilter.LowerBandwidthLimit = -20;
recFilter.UpperBandwidthLimit = 20;
recFilter.CutoffFrequency = 10;

Transmitter additional Gain

[MATLAB]

% IAgTransmitter transmitter: Transmitter object
txModel = transmitter.Model;
gain = txModel.PostTransmitGainsLosses.Add(-5); % dB
gain.Identifier = 'Example Loss';

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IAgTransmitter Interface