private PhasorCollection CreateECAPhasorCollection(TypeMapping typeMapping)
{
Dictionary <string, FieldMapping> fieldLookup = typeMapping.FieldMappings.ToDictionary(mapping => mapping.Field.Identifier);
PhasorCollection obj = new PhasorCollection();
{
// Create Phasor UDT array for "Phasors" field
ArrayMapping arrayMapping = (ArrayMapping)fieldLookup["Phasors"];
PushWindowFrame(arrayMapping);
List <Phasor> list = new List <Phasor>();
int count = GetUDTArrayTypeMappingCount(arrayMapping);
for (int i = 0; i < count; i++)
{
TypeMapping nestedMapping = GetUDTArrayTypeMapping(arrayMapping, i);
list.Add(CreateECAPhasor(nestedMapping));
}
obj.Phasors = list.ToArray();
PopWindowFrame(arrayMapping);
}
return(obj);
}
internal static Output Execute(PhasorCollection inputData, _PhasorCollectionMeta inputMeta)
{
Output output = Output.CreateNew();
try
{
// TODO: Implement your algorithm here...
// You can also write messages to the main window:
MainWindow.WriteMessage("Hello, World!");
}
catch (Exception ex)
{
// Display exceptions to the main window
MainWindow.WriteError(new InvalidOperationException($"Algorithm exception: {ex.Message}", ex));
}
return(output);
}
public static Output Execute(PhasorCollection inputData, _PhasorCollectionMeta inputMeta)
{
Output output = new Output();
if (m_frameCount == 100)
{
m_frameCount = 0;
}
try
{
m_network.Model.InputKeyValuePairs.Clear();
m_network.Model.ClearValues();
for (int i = 0; i < inputData.Phasors.Length; i++)
{
Phasor phasor = inputData.Phasors[i];
_PhasorMeta metaData = inputMeta.Phasors[i];
string magnitudeKey = HistorianIdFromGuid(inputMeta.Phasors[i].Magnitude.ID);
string angleKey = HistorianIdFromGuid(inputMeta.Phasors[i].Angle.ID);
m_network.Model.InputKeyValuePairs.Add(magnitudeKey, phasor.Magnitude);
m_network.Model.InputKeyValuePairs.Add(angleKey, phasor.Angle);
}
m_network.Model.OnNewMeasurements();
m_network.RunNetworkReconstructionCheck();
if (m_network.HasChangedSincePreviousFrame)
{
m_network.Model.DetermineActiveCurrentFlows();
m_network.Model.DetermineActiveCurrentInjections();
}
if (m_network.HasChangedSincePreviousFrame)
{
m_network.Model.ResolveToObservedBuses();
m_network.Model.ResolveToSingleFlowBranches();
}
m_network.ComputeSystemState();
if (m_frameCount % 33 == 0)
{
// UNCOMMENT FOR TEST HARNESS DEMO
//MainWindow.WriteMessage("");
//MainWindow.WriteMessage("Sampled Output");
//MainWindow.WriteMessage("");
//foreach (Substation substation in m_network.Model.Substations)
//{
// MainWindow.WriteMessage($"{substation.Name}");
// foreach (Node node in substation.Nodes)
// {
// MainWindow.WriteMessage($"{node.Name}: {node.Voltage.PositiveSequence.Estimate.PrettyStringValue}");
// }
// MainWindow.WriteMessage("");
//}
// UNCOMMENT FOR TOPOLOGY DETECTION DEMO
MainWindow.WriteMessage("");
MainWindow.WriteMessage("Level 2 Topology Assessment");
MainWindow.WriteMessage("");
foreach (Substation substation in m_network.Model.Substations)
{
if (substation.Name == "Rannish")
{
MainWindow.WriteMessage($"{substation.Name}");
foreach (CircuitBreaker breaker in substation.CircuitBreakers)
{
if (breaker.CrossDevicePhasors != null)
{
if (breaker.CrossDevicePhasors.GroupA != null && breaker.CrossDevicePhasors.GroupB != null)
{
MainWindow.WriteMessage($"{breaker.FromNode.Name} to {breaker.ToNode.Name}: {breaker.InferredState}");
}
}
}
}
}
}
}
catch (Exception ex)
{
// Display exceptions to the main window
MainWindow.WriteError(new InvalidOperationException($"Algorithm exception: {ex.Message}", ex));
}
m_frameCount++;
return(output);
}
