static void Main(string[] args)
{
string inputDir = @"C:\CSSLWaferFab\Input\";
string outputDir = @"C:\CSSLWaferFab\Output\WaferFabSim\";
string parameters = @"FittedEPTParameters - 2019-8-1_4months.csv";
DateTime initialDateTime = new DateTime(2019, 8, 1);
Settings.WriteOutput = true;
Settings.FixSeed = true;
ShellModel WaferFabSim = new ShellModel(outputDir);
// Load WaferFab settings
AutoDataReader reader = new AutoDataReader(inputDir + @"CSVs\", inputDir + @"SerializedFiles\");
WaferFabSettings waferFabSettings = reader.ReadWaferFabSettings(parameters, true, true, DispatcherBase.Type.EPTOVERTAKING);
waferFabSettings.SampleInterval = 1 * 60 * 60; // seconds
waferFabSettings.LotStartsFrequency = 1; // hours
waferFabSettings.UseRealLotStartsFlag = true;
// MIVS Settings
//waferFabSettings.WIPTargets = reader.ReadWIPTargets(waferFabSettings.LotSteps, "WIPTargets.csv");
//waferFabSettings.MIVSjStepBack = 2;
//waferFabSettings.MIVSkStepAhead = 2;
// Read Initial Lots
WaferFabSim.ReadRealSnaphots(inputDir + @$ "SerializedFiles\RealSnapShots_2019-{initialDateTime.Month}-1_2019-{initialDateTime.Month + 1}-1_1h.dat");
waferFabSettings.InitialRealLots = WaferFabSim.RealSnapshotReader.RealSnapshots.Where(x => x.Time.Date == initialDateTime).OrderBy(x => x.Time).First().GetRealLots(1);
// Experiment settings
ExperimentSettings experimentSettings = new ExperimentSettings();
int count = waferFabSettings.InitialRealLots.Where(x => x.StartTime == null).Count();
experimentSettings.NumberOfReplications = 30;
experimentSettings.LengthOfReplication = 121 * 24 * 60 * 60; // seconds
experimentSettings.LengthOfWarmUp = 0 * 60 * 60; // seconds
// Connect settings
WaferFabSim.MyWaferFabSettings = waferFabSettings;
WaferFabSim.MyExperimentSettings = experimentSettings;
// Run simulation
WaferFabSim.RunSimulation();
// Report summary
SimulationReporter reporter = WaferFabSim.MySimulation.MakeSimulationReporter();
reporter.PrintSummaryToFile();
reporter.PrintSummaryToConsole();
}
static void Main(string[] args)
{
string inputDir = @"C:\Users\nx008314\OneDrive - Nexperia\Work\WaferFab\";
string outputDir = @"C:\CSSLWaferFab\";
Settings.Output = true;
Settings.FixSeed = true;
ShellModel WaferFabSim = new ShellModel(inputDir, outputDir);
// Load WaferFab settings
//ManualDataReader reader = new ManualDataReader(inputDir + "CSVs");
AutoDataReader reader = new AutoDataReader(inputDir + "Auto");
WaferFabSettings waferFabSettings = reader.ReadWaferFabSettings();
waferFabSettings.SampleInterval = 1 * 60 * 60; // seconds
waferFabSettings.LotStartsFrequency = 1; // hours
waferFabSettings.UseRealLotStartsFlag = true;
// Read Initial Lots
WaferFabSim.ReadRealSnaphots(inputDir + @"SerializedFiles\RealSnapshots_2019-12-1_2020-1-1_1h.dat");
waferFabSettings.InitialRealLots = WaferFabSim.RealSnapshotReader.RealSnapshots.First().RealLots;
// Experiment settings
ExperimentSettings experimentSettings = new ExperimentSettings();
experimentSettings.NumberOfReplications = 1;
experimentSettings.LengthOfReplication = 1 * 24 * 60 * 60; // seconds
experimentSettings.LengthOfWarmUp = 0 * 60 * 60; // seconds
// Connect settings
WaferFabSim.MyWaferFabSettings = waferFabSettings;
WaferFabSim.MyExperimentSettings = experimentSettings;
// Run simulation
WaferFabSim.RunSimulation();
// Report summary
SimulationReporter reporter = WaferFabSim.MySimulation.MakeSimulationReporter();
reporter.PrintSummaryToFile();
reporter.PrintSummaryToConsole();
}
public static void RunNormalSimulation()
{
string inputDir = Path.GetFullPath(Path.Combine(Directory.GetCurrentDirectory(), @"..\..\..\", "Parameters", ParametersDirectory));
string outputDir = @"C:\CSSLWaferFab\Output\RLToyFab\";
CSSL.Modeling.Settings.WriteOutput = true;
// Fab settings
//IDataReader reader = new DataReader1(inputDir);
IDataReader reader = new DataReader2(inputDir);
ToyFabSettings toyFabSettings = reader.ReadToyFabSettings();
// Build Fab
Simulation sim = new Simulation("RLToyFab", outputDir);
// Experiment settings
sim.MyExperiment.NumberOfReplications = 10;
sim.MyExperiment.LengthOfWarmUp = LengthOfWarmUp;
sim.MyExperiment.LengthOfReplication = LengthOfReplication;
// Build the model
ToyFab toyFab = new ToyFab(sim.MyModel, "WaferFab")
{
LotSteps = toyFabSettings.LotSteps,
LengthOfWarmUp = LengthOfWarmUp
};
AddWorkStations(toyFab, toyFabSettings, sim);
foreach (var sequence in toyFabSettings.Sequences)
{
toyFab.AddSequence(sequence.Key, sequence.Value);
}
toyFab.SetLotGenerator(new LotGenerator(toyFab, "LotGenerator", NumberOfLots));
sim.Run();
// Report summary
SimulationReporter reporter = sim.MakeSimulationReporter();
reporter.PrintSummaryToFile();
reporter.PrintSummaryToConsole();
}
static void Main(string[] args)
{
string inputDirectory = @"C:\CSSLWaferFab\Input\WSC2021paper";
string outputDirectory = @"C:\CSSLWaferFab\Output\WSC2021paper";
string eptParameterFile = @"FittedEPTParameters - 2019-6-1.csv";
List <string> workcenters = new List <string> {
"PHOTOLITH", "FURNACING", "DRY ETCH"
};
List <string> SOvsLDO = new List <string> {
"SO", "LDO"
};
//List<string> SOvsLDO = new List<string> { "LDO"};
foreach (string wc in workcenters)
{
WaferFabSettings waferFabSettings = Deserializer.DeserializeWaferFabSettings(Path.Combine(inputDirectory, "SerializedFiles", $"WaferFabSettings_{wc}_WithLotStarts.dat"));
foreach (string overtaking in SOvsLDO)
{
bool lotStepOvertaking = overtaking == "SO" ? false : true;
#region Initializing simulation
Simulation simulation = new Simulation(wc, outputDirectory);
#endregion
#region Experiment settings
simulation.MyExperiment.NumberOfReplications = 10;
simulation.MyExperiment.LengthOfReplication = 60 * 60 * 24 * 91; // September and October
simulation.MyExperiment.LengthOfWarmUp = 60 * 60 * 24 * 30;
DateTime initialDateTime = new DateTime(2019, 08, 01);
#endregion
#region WaferFab settings
EPTDistributionReader distributionReader = new EPTDistributionReader(Path.Combine(inputDirectory, "CSVs"), waferFabSettings.WorkCenters, waferFabSettings.LotStepsPerWorkStation);
waferFabSettings.WCServiceTimeDistributions = distributionReader.GetServiceTimeDistributions(eptParameterFile);
waferFabSettings.WCOvertakingDistributions = distributionReader.GetOvertakingDistributions(lotStepOvertaking);
waferFabSettings.WCDispatcherTypes[wc] = DispatcherBase.Type.EPTOVERTAKING;
#endregion
#region Make starting lots
AutoDataReader dataReader = new AutoDataReader(Path.Combine(inputDirectory, "Auto"), Path.Combine(inputDirectory, "SerializedFiles"));
#endregion
#region Building the model
WaferFab waferFab = new WaferFab(simulation.MyModel, "WaferFab", new ConstantDistribution(60 * 60 * 24), initialDateTime);
WorkCenter workCenter = new WorkCenter(waferFab, $"WorkCenter_{wc}", waferFabSettings.WCServiceTimeDistributions[wc], waferFabSettings.LotStepsPerWorkStation[wc]);
// Connect workcenter to WIPDependentDistribution
EPTDistribution distr = (EPTDistribution)waferFabSettings.WCServiceTimeDistributions[wc];
distr.WorkCenter = workCenter;
EPTOvertakingDispatcher dispatcher = new EPTOvertakingDispatcher(workCenter, workCenter.Name + "_EPTOvertakingDispatcher", waferFabSettings.WCOvertakingDistributions[wc]);
workCenter.SetDispatcher(dispatcher);
// Connect workcenter to OvertakingDistribution
waferFabSettings.WCOvertakingDistributions[wc].WorkCenter = workCenter;
waferFab.AddWorkCenter(workCenter.Name, workCenter);
// Sequences
foreach (var sequence in waferFabSettings.Sequences)
{
waferFab.AddSequence(sequence.Key, sequence.Value);
}
// LotSteps
waferFab.LotSteps = waferFab.Sequences.Select(x => x.Value).Select(x => x.GetCurrentStep(0)).ToDictionary(x => x.Name);
// LotGenerator
waferFab.SetLotGenerator(new LotGenerator(waferFab, "LotGenerator", new ConstantDistribution(60), true));
// Add lotstarts
waferFab.LotStarts = waferFabSettings.LotStarts;
// Add observers
LotOutObserver lotOutObserver = new LotOutObserver(simulation, wc + "_" + overtaking + "LotOutObserver");
dispatcher.Subscribe(lotOutObserver);
OptimiserObserver optimiserObserver = new OptimiserObserver(simulation, "TotalQueueObserver");
workCenter.Subscribe(optimiserObserver);
#endregion
#region Read initial lots
//RealSnapshotReader reader = new RealSnapshotReader();
//List<RealSnapshot> realSnapshots = reader.Read(Path.Combine(inputDirectory, "SerializedFiles", reader.GetRealSnapshotString(initialDateTime)), 1);
//RealSnapshot realSnapShot = realSnapshots.Where(x => x.Time == initialDateTime).First();
//List<string> lotSteps = workCenter.LotSteps.Select(x => x.Name).ToList();
//List<RealLot> initialRealLots = realSnapShot.GetRealLots(1).Where(x => lotSteps.Contains(x.IRDGroup)).ToList();
//List<Lot> initialLots = initialRealLots.Select(x => x.ConvertToLotArea(0, waferFabSettings.Sequences, initialDateTime)).ToList();
//waferFab.InitialLots = initialLots;
#endregion
simulation.Run();
#region Reporting
SimulationReporter reporter = simulation.MakeSimulationReporter();
reporter.PrintSummaryToConsole();
#endregion
}
}
}
static void Main(string[] args)
{
List <string> workcenters = new List <string>()
{
"BACKGRIND", "BATCH UP", "CMP", "DICE", "DRY ETCH", "ELEC TEST", "EVAPORATION", "FURNACING", "IMPLANT",
"INSPECTION", "LPCVD", "MERCURY", "NITRIDE DEP", "OFF LINE INK", "PACK", "PHOTOLITH", "PROBE", "REPORTING",
"SAMPLE TEST", "SPUTTERING", "WET ETCH"
};
DateTime initialDateTime = new DateTime(2019, 10, 1);
string inputDirectory = @"C:\CSSLWaferFab\Input";
string outputDirectory = @"C:\CSSLWaferFab\Output\WaferFabArea";
string eptParameterFile = @"FittedEPTParameters - 2019-6-1.csv";
RealSnapshotReader reader = new RealSnapshotReader();
List <RealSnapshot> realSnapshots = reader.Read(Path.Combine(inputDirectory, "SerializedFiles", reader.GetRealSnapshotString(initialDateTime)), 1);
RealSnapshot realSnapShot = realSnapshots.Where(x => x.Time == initialDateTime).First();
//workcenters = new List<string>() {"INSPECTION"};
foreach (string workcenter in workcenters)
{
#region Parameters
string wc = workcenter;
bool isFitted = false; // true = fitted, false = optimised
bool lotStepOvertaking = true;
#endregion
#region Initializing simulation
Simulation simulation = new Simulation(wc, outputDirectory);
#endregion
#region Experiment settings
simulation.MyExperiment.NumberOfReplications = 30;
DateTime finalDateTime = new DateTime(2019, initialDateTime.Month + 2, 1);
simulation.MyExperiment.LengthOfReplication = (finalDateTime - initialDateTime).TotalSeconds; // Number of seconds between two months
simulation.MyExperiment.LengthOfWarmUp = 60 * 60 * 24 * 0;
#endregion
#region WaferFab settings
WaferFabSettings waferFabSettings = Deserializer.DeserializeWaferFabSettings(Path.Combine(inputDirectory, "SerializedFiles", $"WaferFabSettings_{wc}_WithLotStarts.dat"));
EPTDistributionReader distributionReader = new EPTDistributionReader(Path.Combine(inputDirectory, "CSVs"), waferFabSettings.WorkCenters, waferFabSettings.LotStepsPerWorkStation);
waferFabSettings.WCServiceTimeDistributions = distributionReader.GetServiceTimeDistributions(eptParameterFile);
waferFabSettings.WCOvertakingDistributions = distributionReader.GetOvertakingDistributions(lotStepOvertaking);
waferFabSettings.WCDispatcherTypes[workcenter] = DispatcherBase.Type.EPTOVERTAKING;
#endregion
#region Make starting lots
AutoDataReader dataReader = new AutoDataReader(Path.Combine(inputDirectory, "Auto"), Path.Combine(inputDirectory, "SerializedFiles"));
#endregion
#region Building the model
WaferFab waferFab = new WaferFab(simulation.MyModel, "WaferFab", new ConstantDistribution(60 * 60 * 24), initialDateTime);
WorkCenter workCenter = new WorkCenter(waferFab, $"WorkCenter_{wc}", waferFabSettings.WCServiceTimeDistributions[wc], waferFabSettings.LotStepsPerWorkStation[wc]);
// Connect workcenter to WIPDependentDistribution
EPTDistribution distr = (EPTDistribution)waferFabSettings.WCServiceTimeDistributions[wc];
distr.WorkCenter = workCenter;
EPTOvertakingDispatcher dispatcher = new EPTOvertakingDispatcher(workCenter, workCenter.Name + "_EPTOvertakingDispatcher", waferFabSettings.WCOvertakingDistributions[wc]);
workCenter.SetDispatcher(dispatcher);
// Connect workcenter to OvertakingDistribution
waferFabSettings.WCOvertakingDistributions[wc].WorkCenter = workCenter;
waferFab.AddWorkCenter(workCenter.Name, workCenter);
// Sequences
foreach (var sequence in waferFabSettings.Sequences)
{
waferFab.AddSequence(sequence.Key, sequence.Value);
}
// LotSteps
waferFab.LotSteps = waferFab.Sequences.Select(x => x.Value).Select(x => x.GetCurrentStep(0)).ToDictionary(x => x.Name);
// LotGenerator
waferFab.SetLotGenerator(new LotGenerator(waferFab, "LotGenerator", new ConstantDistribution(60), true));
// Add lotstarts
waferFab.LotStarts = waferFabSettings.LotStarts;
// Add initial lots
List <RealLot> initialRealLots = realSnapShot.GetRealLots(1).Where(x => x.LotActivity.WorkStation == wc).ToList();
waferFab.InitialLots = initialRealLots.Select(x => x.ConvertToLotArea(0, waferFabSettings.Sequences, initialDateTime)).ToList();
// Add observers
LotOutObserver lotOutObserver = new LotOutObserver(simulation, wc + "_LotOutObserver");
dispatcher.Subscribe(lotOutObserver);
TotalQueueObserver totalQueueObserver = new TotalQueueObserver(simulation, wc + "_TotalQueueObserver");
workCenter.Subscribe(totalQueueObserver);
#endregion
simulation.Run();
#region Reporting
SimulationReporter reporter = simulation.MakeSimulationReporter();
reporter.PrintSummaryToConsole();
#endregion
}
}
private static void Experiment(string control, DateTime startDate, string experimentOutputDirectory, bool dynamic, bool stochastic, double weightA, double weightB, double weightC, Dictionary <string, double> deterministicNonProductiveTimesRMS, Dictionary <string, double> deterministicNonProductiveTimesARMS, int CPTimeLimit = 0)
{
string outputDir = experimentOutputDirectory;
Simulation sim = new Simulation("LithographyAreaSim", outputDir);
// Parameters
double simulationLength = 30 * 24 * 3600 + 1;
string productionControl = control;
// The experiment part
sim.MyExperiment.LengthOfReplication = simulationLength;
sim.MyExperiment.LengthOfWarmUp = 0;
if (stochastic)
{
sim.MyExperiment.NumberOfReplications = 1;
}
else
{
sim.MyExperiment.NumberOfReplications = 1;
}
// The model part
// Create lithographyarea
LithographyArea lithographyarea = new LithographyArea(sim.MyModel, "LithographyArea", startDate, simulationLength, dynamic, stochastic, weightA, weightB, weightC, deterministicNonProductiveTimesRMS, deterministicNonProductiveTimesARMS);
// Property dispatcherBase
DispatcherBase dispatcher = null;
// Create chosen dispatcher
if (productionControl == "FIFO")
{
dispatcher = new FIFODispatcher(lithographyarea, "FIFODispatcher");
}
else if (productionControl == "EDD")
{
dispatcher = new EDDDispatcher(lithographyarea, "EDDDispatcher");
}
else if (productionControl == "SPT")
{
dispatcher = new SPTDispatcher(lithographyarea, "SPTDispatcher");
}
else if (productionControl == "CurrentProductionControl")
{
dispatcher = new CurrentDispatcher(lithographyarea, "CurrentDispatcher");
}
else if (productionControl == "ILPScheduling")
{
dispatcher = new ILPSchedulingDispatcher(lithographyarea, "ILPSchedulingDispatcher");
}
else if (productionControl == "CPScheduling")
{
dispatcher = new CPDispatcher(lithographyarea, "CPDispatcher", CPTimeLimit);
}
// Set dispatcher
lithographyarea.SetDispatcher(dispatcher);
// Create and set lotGenerator
LotGenerator lotGenerator = new LotGenerator(lithographyarea, "LotGenerator", dispatcher);
lithographyarea.SetLotGenerator(lotGenerator);
// Create and set machines
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#1", dispatcher, 1));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#2", dispatcher, 2));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#3", dispatcher, 3));
lithographyarea.AddMachine(new Machine(lithographyarea, "ASML#4", dispatcher, 4));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#5", dispatcher, 5));
lithographyarea.AddMachine(new Machine(lithographyarea, "ASML#6", dispatcher, 6));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#7", dispatcher, 7));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#8", dispatcher, 8));
lithographyarea.AddMachine(new Machine(lithographyarea, "ASML#9", dispatcher, 9));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#10", dispatcher, 10));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#11", dispatcher, 11));
lithographyarea.AddMachine(new Machine(lithographyarea, "StepCluster#13", dispatcher, 12));
// The observer part
LithographyAreaObserver lithographyAreaObserver = new LithographyAreaObserver(sim, startDate);
lithographyarea.Subscribe(lithographyAreaObserver);
foreach (Machine machine in lithographyarea.Machines)
{
MachineObserver machineObserver = new MachineObserver(sim, startDate);
machine.Subscribe(machineObserver);
}
// Run
sim.Run();
// The reporting part
SimulationReporter reporter = sim.MakeSimulationReporter();
reporter.PrintSummaryToFile();
reporter.PrintSummaryToConsole();
}
static void Main(string[] args)
{
Simulation sim = new Simulation("SomeSimulation", @"C:\CSSL");
Settings.WriteOutput = false;
Settings.NotifyObservers = true;
// Parameters...
double dispatchTime = 1E-3;
double lambda = 100;
int numberServerpools = 10;
int numberServerpoolsToChooseFrom = 10;
// The experiment part...
sim.MyExperiment.NumberOfReplications = 3;
sim.MyExperiment.LengthOfReplication = 10;
sim.MyExperiment.LengthOfWarmUp = 2;
// The model part...
DataCenter dataCenter = new DataCenter(sim.MyModel, "DataCenter");
for (int i = 0; i < numberServerpools; i++)
{
dataCenter.AddServerpool(new ServerPool(dataCenter, $"Serverpool_{i}"));
}
Dispatcher dispatcher = new Dispatcher(dataCenter, "Dispatcher", new ExponentialDistribution(1), double.PositiveInfinity, dataCenter.ServerPools, dispatchTime, numberServerpoolsToChooseFrom);
dataCenter.SetDispatcher(dispatcher);
JobGenerator jobGenerator = new JobGenerator(dataCenter, "JobGenerator", new ExponentialDistribution(lambda), dispatcher);
dataCenter.SetJobGenerator(jobGenerator);
// The observer part...
DispatcherObserver dispatcherObserver = new DispatcherObserver(sim);
dispatcher.Subscribe(dispatcherObserver);
DataCenterObserver dataCenterObserver = new DataCenterObserver(sim);
dataCenter.Subscribe(dataCenterObserver);
foreach (ServerPool serverpool in dataCenter.ServerPools)
{
ServerPoolObserver serverpoolObserver = new ServerPoolObserver(sim);
serverpool.Subscribe(serverpoolObserver);
}
// Run...
sim.Run();
// The reporting part...
SimulationReporter reporter = sim.MakeSimulationReporter();
reporter.PrintSummaryToFile();
reporter.PrintSummaryToConsole();
}
public Tuple <double, double> RunSim(Dictionary <string, Distribution> dict)
{
EPTDistribution dist = (EPTDistribution)dict.First().Value;
WIPDepDistParameters x = dist.Par;
waferFabSettings.WCServiceTimeDistributions = new Dictionary <string, Distribution> {
{ wc, new EPTDistribution(x) }
};
#region Initializing simulation
Simulation simulation = new Simulation("CSSLWaferFabArea", outputDirectory);
#endregion
#region Experiment settings
simulation.MyExperiment.NumberOfReplications = 10;
DateTime finalDateTime = new DateTime(2019, initialDateTime.Month + 2, 1);
simulation.MyExperiment.LengthOfReplication = (finalDateTime - initialDateTime).TotalSeconds; // Number of seconds between two months
simulation.MyExperiment.LengthOfWarmUp = 60 * 60 * 24 * 0;
#endregion
#region Building the model
WaferFab waferFab = new WaferFab(simulation.MyModel, "WaferFab", new ConstantDistribution(60 * 60 * 24), initialDateTime);
WorkCenter workCenter = new WorkCenter(waferFab, $"WorkCenter_{wc}", waferFabSettings.WCServiceTimeDistributions[wc], waferFabSettings.LotStepsPerWorkStation[wc]);
// Connect workcenter to WIPDependentDistribution
EPTDistribution distr = (EPTDistribution)waferFabSettings.WCServiceTimeDistributions[wc];
distr.WorkCenter = workCenter;
EPTOvertakingDispatcher dispatcher = new EPTOvertakingDispatcher(workCenter, workCenter.Name + "_EPTOvertakingDispatcher", waferFabSettings.WCOvertakingDistributions[wc]);
workCenter.SetDispatcher(dispatcher);
// Connect workcenter to OvertakingDistribution
waferFabSettings.WCOvertakingDistributions[wc].WorkCenter = workCenter;
waferFab.AddWorkCenter(workCenter.Name, workCenter);
// Sequences
foreach (var sequence in waferFabSettings.Sequences)
{
waferFab.AddSequence(sequence.Key, sequence.Value);
}
// LotSteps
waferFab.LotSteps = waferFab.Sequences.Select(x => x.Value).Select(x => x.GetCurrentStep(0)).ToDictionary(x => x.Name);
// LotGenerator
waferFab.SetLotGenerator(new LotGenerator(waferFab, "LotGenerator", new ConstantDistribution(60), true));
// Add lotstarts
waferFab.LotStarts = waferFabSettings.LotStarts;
// Add initial lots
if (useInitialLots)
{
List <Lot> initialLotsDeepCopy = initialLots.ConvertAll(x => new Lot(x));
waferFab.InitialLots = initialLotsDeepCopy;
}
// Add observers
OptimiserObserver optimiserObs = new OptimiserObserver(simulation, wc + "_TotalQueueObserver");
workCenter.Subscribe(optimiserObs); // Total queue for workcenter
#endregion
simulation.Run();
#region Reporting
SimulationReporter reporter = simulation.MakeSimulationReporter();
reporter.PrintSummaryToConsole();
#endregion
Tuple <double, double> results = new Tuple <double, double>(optimiserObs.QueueLengthStatistic.Average(), optimiserObs.QueueLengthStatistic.StandardDeviation());
return(results);
}
