//---------------------------------------------------------------------
//private static void WriteAnnualLog(IEcoregion ecoregion, int year, AnnualClimate_Monthly annualClimateMonthly, AnnualClimate_Daily annualClimate_Daily)
private static void WriteAnnualLog(IEcoregion ecoregion, int year, AnnualClimate_Monthly annualClimateMonthly)
{
AnnualLog.Clear();
AnnualLog al = new AnnualLog();
//al.SimulationPeriod = TBD
al.Time = year;
al.EcoregionName = ecoregion.Name;
al.EcoregionIndex = ecoregion.Index;
//if (future_allData_granularity == TemporalGranularity.Daily)
// al.BeginGrow = annualClimate_Daily.BeginGrowing;
//else
al.BeginGrow = annualClimateMonthly.BeginGrowing;
//if (future_allData_granularity == TemporalGranularity.Daily)
// al.EndGrow = annualClimate_Daily.EndGrowing;
//else
al.EndGrow = annualClimateMonthly.EndGrowing;
al.TAP = annualClimateMonthly.TotalAnnualPrecip;
al.MAT = annualClimateMonthly.MeanAnnualTemperature;
al.PDSI = Future_MonthlyData[year][ecoregion.Index].PDSI;
// VS: might need FWI in annual climate
//al.FWI = Future_MonthlyData[year][ecoregion.Index].FWI;
AnnualLog.AddObject(al);
AnnualLog.WriteToFile();
}
public static void GenerateEcoregionClimateData(IEcoregion ecoregion, int startYear, double latitude, double fieldCapacity, double wiltingPoint)
{
// JM: these next three lines are not currently used, but may need to be modified if used:
//int numberOftimeSteps = Climate.ModelCore.EndTime - Climate.ModelCore.StartTime;
//annualPDSI = new double[Climate.ModelCore.Ecoregions.Count, future_allData.Count];
//landscapeAnnualPDSI = new double[future_allData.Count];
double[] temperature_normals = new double[12];
double[] precip_normals = new double[12];
double availableWaterCapacity = fieldCapacity - wiltingPoint;
Climate.ModelCore.UI.WriteLine(" Core.StartTime = {0}, Core.EndTime = {1}.", ModelCore.StartTime, ModelCore.EndTime);
//Climate.ModelCore.UI.WriteLine(" Climate.LandscapeAnnualPDSI.Length = {0}.", Climate.LandscapeAnnualPDSI.Length);
//First Calculate Climate Normals from Spin-up data
int timeStepIndex = 0;
foreach (KeyValuePair <int, AnnualClimate_Monthly[]> timeStep in Spinup_MonthlyData)
{
//Climate.ModelCore.UI.WriteLine(" Calculating Weather for SPINUP: timeStep = {0}, actualYear = {1}", timeStep.Key, startYear + timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, latitude, Climate.Phase.SpinUp_Climate, timeStep.Key, timeStepIndex);
Spinup_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] += annualClimateMonthly.MonthlyTemp[mo];
precip_normals[mo] += annualClimateMonthly.MonthlyPrecip[mo];
}
timeStepIndex++;
}
// Calculate AVERAGE T normal.
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] /= (double)Spinup_MonthlyData.Count;
precip_normals[mo] /= (double)Spinup_MonthlyData.Count;
//Climate.ModelCore.UI.WriteLine("Month = {0}, Original Monthly T normal = {1}", mo, month_Temp_normal[mo]);
}
timeStepIndex = 0;
PDSI_Calculator.InitializeEcoregion_PDSI(temperature_normals, precip_normals, availableWaterCapacity, latitude, UnitSystem.metrics, ecoregion);
foreach (KeyValuePair <int, AnnualClimate_Monthly[]> timeStep in Future_MonthlyData)
{
//Climate.ModelCore.UI.WriteLine(" Completed calculations for Future_Climate: TimeStepYear = {0}, actualYear = {1}", timeStep.Key, startYear + timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, latitude, Climate.Phase.Future_Climate, timeStep.Key, timeStepIndex);
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
//---------------------------------------------------------------------------
public static double CalculateAnnualActualEvapotranspiration(AnnualClimate_Monthly annualClimate, double fieldCapacity)
{
//I don't think this method is every called.
// field capacity input as cm
// variable with xVariableName indicate conversion to mm
double xFieldCap = fieldCapacity * 10.0;
double waterAvail = 0.0;
double actualET = 0.0;
double oldWaterAvail = 0.0;
double accPotWaterLoss = 0.0;
for (int month = 0; month < 12; month++)
{
double monthlyRain = annualClimate.MonthlyPrecip[month];
double potentialET = annualClimate.MonthlyPET[month];
//Calc potential water loss this month
double potWaterLoss = monthlyRain - potentialET;
//If monthlyRain doesn't satisfy potentialET, add this month's potential
//water loss to accumulated water loss from soil
if (potWaterLoss < 0.0)
{
accPotWaterLoss += potWaterLoss;
double xAccPotWaterLoss = accPotWaterLoss * 10.0;
//Calc water retained in soil given so much accumulated potential
//water loss Pastor and Post. 1984. Can. J. For. Res. 14:466:467.
waterAvail = fieldCapacity *
System.Math.Exp((.000461 - 1.10559 / xFieldCap) * (-1.0 * xAccPotWaterLoss));
if (waterAvail < 0.0)
{
waterAvail = 0.0;
}
//changeSoilMoisture - during this month
double changeSoilMoisture = waterAvail - oldWaterAvail;
//Calc actual evapotranspiration (AET) if soil water is drawn down
actualET += (monthlyRain - changeSoilMoisture);
}
//If monthlyRain satisfies potentialET, don't draw down soil water
else
{
waterAvail = oldWaterAvail + potWaterLoss;
if (waterAvail >= fieldCapacity)
{
waterAvail = fieldCapacity;
}
double changeSoilMoisture = waterAvail - oldWaterAvail;
//If soil partially recharged, reduce accumulated potential
//water loss accordingly
accPotWaterLoss += changeSoilMoisture;
//If soil completely recharged, reset accumulated potential
//water loss to zero
if (waterAvail >= fieldCapacity)
{
accPotWaterLoss = 0.0;
}
//If soil water is not drawn upon, add potentialET to AET
actualET += potentialET;
}
oldWaterAvail = waterAvail;
//Climate.TextLog.WriteLine("Actual ET Calcs. Rain={0},PET={1}, potWaterLoss={2:0.0},,fieldcapacity={3:0.000}, oldwaterAvail={4:0.000}, actualET={5:0.000}", monthlyRain, potentialET, potWaterLoss, fieldCapacity, oldWaterAvail, actualET);
}
return(actualET);
}
//public static void GenerateClimate_GetPDSI(int startYear, int endYear, int latitude, double fieldCapacity, double wiltingPoint)
//{
// string outputFilePath = @"PDSI_BaseBDA_Genrated_Climate.csv";
// File.WriteAllText(outputFilePath, String.Empty);
// foreach (IEcoregion ecoregion in Climate.ModelCore.Ecoregions)
// {
// AnnualClimate_Monthly[] acs;
// int numOfYears = endYear - startYear + 1;
// acs = new AnnualClimate_Monthly[numOfYears];
// //foreach time step it should be called
// for (int i = startYear; i <= endYear; i++)
// {
// acs[i - startYear] = new AnnualClimate_Monthly(ecoregion, 0, latitude); // Latitude should be given
// //Climate.ModelCore.UI.WriteLine(ac.MonthlyTemp[0].ToString() + "\n");
// //Climate.ModelCore.UI.WriteLine(ac.MonthlyPrecip[0].ToString() + "\n");
// }
// double[] mon_T_normal = new double[12];//new double[12] { 19.693, 23.849, 34.988, 49.082, 60.467, 70.074, 75.505, 73.478, 64.484, 52.634, 36.201, 24.267 };
// IClimateRecord[] climateRecs = new ClimateRecord[12];
// //If timestep is 0 then calculate otherwise get the mon_T_normal for timestep 0
// Climate.TimestepData = future_allData[0];
// for (int mo = 0; mo < 12; mo++)
// {
// climateRecs[mo] = Climate.TimestepData[ecoregion.Index, mo];
// mon_T_normal[mo] = (climateRecs[mo].AvgMinTemp + climateRecs[mo].AvgMinTemp) / 2;
// }
// double AWC = fieldCapacity - wiltingPoint;
// //double latitude = Landis.Extension.Succession.Century.EcoregionData.Latitude[ecoregion];
// new PDSI_Calculator().CalculatePDSI(acs, mon_T_normal, AWC, latitude, /*outputFilePath,*/ UnitSystem.metrics);
// }
//}
//public static void GenerateEcoregionClimateData()
//{
//}
public static void GenerateEcoregionClimateData(IEcoregion ecoregion, int startYear, double latitude, double fieldCapacity, double wiltingPoint)
{
Climate.ModelCore.UI.WriteLine(" Generating Ecoregion Climate Data for ecoregion = {0}.", ecoregion.Name);
int numberOftimeSteps = Climate.ModelCore.EndTime - Climate.ModelCore.StartTime;
annualPDSI = new double[Climate.ModelCore.Ecoregions.Count, future_allData.Count]; //numberOftimeSteps + 1];
landscapeAnnualPDSI = new double[future_allData.Count]; //numberOftimeSteps+1];
double[] temperature_normals = new double[12];
double availableWaterCapacity = fieldCapacity - wiltingPoint;
//Climate.ModelCore.UI.WriteLine(" Latitude = {0}, Available Water = {1}.", latitude, availableWaterCapacity);
//IClimateRecord[] climateRecs = new ClimateRecord[12];
//int minimumTime = 5000;
//Firt Calculate Climate Normals from Spin-up data
foreach (KeyValuePair <int, IClimateRecord[, ]> timeStep in spinup_allData)
{
//Climate.ModelCore.UI.WriteLine(" Calculating Weather for SPINUP Year = {0}.", timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, startYear + timeStep.Key, latitude, Climate.Phase.SpinUp_Climate, timeStep.Key);
Spinup_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] += annualClimateMonthly.MonthlyTemp[mo];
}
}
// Calculate AVERAGE T normal.
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] /= (double)spinup_allData.Count;
//Climate.ModelCore.UI.WriteLine("Month = {0}, Original Monthly T normal = {1}", mo, month_Temp_normal[mo]);
}
int timestepIndex = 0;
// Next calculate PSDI for the future data
foreach (KeyValuePair <int, AnnualClimate_Monthly[]> timeStep in Future_MonthlyData)
//foreach (KeyValuePair<int, IClimateRecord[,]> timeStep in future_allData)
{
//if (timeStep.Key < minimumTime)
// minimumTime = timeStep.Key;
//if (timestepIndex > numberOftimeSteps)
// break;
//Climate.ModelCore.UI.WriteLine(" Calculating Weather for FUTURE Year = {0}.", timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, startYear + timeStep.Key, latitude, Climate.Phase.Future_Climate, timeStep.Key);
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI = PDSI_Calculator.CalculatePDSI(annualClimateMonthly, temperature_normals, availableWaterCapacity, latitude, UnitSystem.metrics, ecoregion);
Climate.LandscapeAnnualPDSI[timestepIndex] += (Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI / Climate.ModelCore.Ecoregions.Count);
//Climate.ModelCore.UI.WriteLine("Calculated PDSI for Ecoregion {0}, timestep {1}, PDSI Year {2}; PDSI={3:0.00}.", ecoregion.Name, timestepIndex, timeStep.Key, PDSI);
timestepIndex++;
}
}
//---------------------------------------------------------------------
private static void WriteAnnualLog(IEcoregion ecoregion, int year, AnnualClimate_Monthly annualClimateMonthly)
{
AnnualLog.Clear();
AnnualLog al = new AnnualLog();
//al.SimulationPeriod = TBD
al.Time = year;
al.EcoregionName = ecoregion.Name;
al.EcoregionIndex = ecoregion.Index;
al.BeginGrow = annualClimateMonthly.BeginGrowing;
al.EndGrow = annualClimateMonthly.EndGrowing;
al.TAP = annualClimateMonthly.TotalAnnualPrecip;
al.MAT = annualClimateMonthly.MeanAnnualTemperature;
al.PDSI = Future_MonthlyData[year][ecoregion.Index].PDSI;
AnnualLog.AddObject(al);
AnnualLog.WriteToFile();
}
public static void GenerateEcoregionClimateData(IEcoregion ecoregion, int startYear, double latitude, double fieldCapacity, double wiltingPoint)
{
// JM: these next three lines are not currently used, but may need to be modified if used:
//int numberOftimeSteps = Climate.ModelCore.EndTime - Climate.ModelCore.StartTime;
//annualPDSI = new double[Climate.ModelCore.Ecoregions.Count, future_allData.Count];
//landscapeAnnualPDSI = new double[future_allData.Count];
double[] temperature_normals = new double[12];
double[] precip_normals = new double[12];
double availableWaterCapacity = fieldCapacity - wiltingPoint;
Climate.TextLog.WriteLine("Core.StartTime = {0}, Core.EndTime = {1}.", ModelCore.StartTime, ModelCore.EndTime);
//Climate.TextLog.WriteLine(" Climate.LandscapeAnnualPDSI.Length = {0}.", Climate.LandscapeAnnualPDSI.Length);
//First Calculate Climate Normals from Spin-up data
int timeStepIndex = 0;
foreach (KeyValuePair<int, AnnualClimate_Monthly[]> timeStep in Spinup_MonthlyData)
{
//Climate.TextLog.WriteLine(" Calculating Weather for SPINUP: timeStep = {0}, actualYear = {1}", timeStep.Key, startYear + timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, latitude, Climate.Phase.SpinUp_Climate, timeStep.Key, timeStepIndex);
Spinup_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] += annualClimateMonthly.MonthlyTemp[mo];
precip_normals[mo] += annualClimateMonthly.MonthlyPrecip[mo];
}
timeStepIndex++;
}
// Calculate AVERAGE T normal.
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] /= (double)Spinup_MonthlyData.Count;
precip_normals[mo] /= (double)Spinup_MonthlyData.Count;
//Climate.TextLog.WriteLine("Month = {0}, Original Monthly T normal = {1}", mo, month_Temp_normal[mo]);
}
timeStepIndex = 0;
//PDSI_Calculator.InitializeEcoregion_PDSI(temperature_normals, precip_normals, availableWaterCapacity, latitude, UnitSystem.metrics, ecoregion);
foreach (KeyValuePair<int, AnnualClimate_Monthly[]> timeStep in Future_MonthlyData)
{
//Climate.TextLog.WriteLine(" Completed calculations for Future_Climate: TimeStepYear = {0}, actualYear = {1}", timeStep.Key, startYear + timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, latitude, Climate.Phase.Future_Climate, timeStep.Key, timeStepIndex);
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
// Next calculate PSDI for the future data
//Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI = PDSI_Calculator.CalculateEcoregion_PDSI(annualClimateMonthly, temperature_normals, precip_normals, availableWaterCapacity, latitude, UnitSystem.metrics, ecoregion);
//Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI = PDSI_Calculator.CalculateEcoregion_PDSI(annualClimateMonthly, temperature_normals, precip_normals, latitude, UnitSystem.metrics, ecoregion);
// Climate.LandscapeAnnualPDSI[timeStepIndex] += (Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI / Climate.ModelCore.Ecoregions.Count);
//Climate.TextLog.WriteLine("Calculated PDSI for Ecoregion {0}, timestep {1}, PDSI Year {2}; PDSI={3:0.00}.", ecoregion.Name, timeStepIndex, timeStep.Key, Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI);
timeStepIndex++;
WriteAnnualLog(ecoregion, startYear + timeStep.Key, annualClimateMonthly);
}
}
//---------------------------------------------------------------------------
public static double CalculateAnnualActualEvapotranspiration(AnnualClimate_Monthly annualClimate, double fieldCapacity)
{
//I don't think this method is every called.
// field capacity input as cm
// variable with xVariableName indicate conversion to mm
double xFieldCap = fieldCapacity * 10.0;
double waterAvail = 0.0;
double actualET = 0.0;
double oldWaterAvail = 0.0;
double accPotWaterLoss = 0.0;
for (int month = 0; month < 12; month++)
{
double monthlyRain = annualClimate.MonthlyPrecip[month];
double potentialET = annualClimate.MonthlyPET[month];
//Calc potential water loss this month
double potWaterLoss = monthlyRain - potentialET;
//If monthlyRain doesn't satisfy potentialET, add this month's potential
//water loss to accumulated water loss from soil
if (potWaterLoss < 0.0)
{
accPotWaterLoss += potWaterLoss;
double xAccPotWaterLoss = accPotWaterLoss * 10.0;
//Calc water retained in soil given so much accumulated potential
//water loss Pastor and Post. 1984. Can. J. For. Res. 14:466:467.
waterAvail = fieldCapacity *
System.Math.Exp((.000461 - 1.10559 / xFieldCap) * (-1.0 * xAccPotWaterLoss));
if (waterAvail < 0.0)
waterAvail = 0.0;
//changeSoilMoisture - during this month
double changeSoilMoisture = waterAvail - oldWaterAvail;
//Calc actual evapotranspiration (AET) if soil water is drawn down
actualET += (monthlyRain - changeSoilMoisture);
}
//If monthlyRain satisfies potentialET, don't draw down soil water
else
{
waterAvail = oldWaterAvail + potWaterLoss;
if (waterAvail >= fieldCapacity)
waterAvail = fieldCapacity;
double changeSoilMoisture = waterAvail - oldWaterAvail;
//If soil partially recharged, reduce accumulated potential
//water loss accordingly
accPotWaterLoss += changeSoilMoisture;
//If soil completely recharged, reset accumulated potential
//water loss to zero
if (waterAvail >= fieldCapacity)
accPotWaterLoss = 0.0;
//If soil water is not drawn upon, add potentialET to AET
actualET += potentialET;
}
oldWaterAvail = waterAvail;
//Climate.ModelCore.UI.WriteLine("Actual ET Calcs. Rain={0},PET={1}, potWaterLoss={2:0.0},,fieldcapacity={3:0.000}, oldwaterAvail={4:0.000}, actualET={5:0.000}", monthlyRain, potentialET, potWaterLoss, fieldCapacity, oldWaterAvail, actualET);
}
return actualET;
}
//public static void GenerateClimate_GetPDSI(int startYear, int endYear, int latitude, double fieldCapacity, double wiltingPoint)
//{
// string outputFilePath = @"PDSI_BaseBDA_Genrated_Climate.csv";
// File.WriteAllText(outputFilePath, String.Empty);
// foreach (IEcoregion ecoregion in Climate.ModelCore.Ecoregions)
// {
// AnnualClimate_Monthly[] acs;
// int numOfYears = endYear - startYear + 1;
// acs = new AnnualClimate_Monthly[numOfYears];
// //foreach time step it should be called
// for (int i = startYear; i <= endYear; i++)
// {
// acs[i - startYear] = new AnnualClimate_Monthly(ecoregion, 0, latitude); // Latitude should be given
// //Climate.ModelCore.UI.WriteLine(ac.MonthlyTemp[0].ToString() + "\n");
// //Climate.ModelCore.UI.WriteLine(ac.MonthlyPrecip[0].ToString() + "\n");
// }
// double[] mon_T_normal = new double[12];//new double[12] { 19.693, 23.849, 34.988, 49.082, 60.467, 70.074, 75.505, 73.478, 64.484, 52.634, 36.201, 24.267 };
// IClimateRecord[] climateRecs = new ClimateRecord[12];
// //If timestep is 0 then calculate otherwise get the mon_T_normal for timestep 0
// Climate.TimestepData = future_allData[0];
// for (int mo = 0; mo < 12; mo++)
// {
// climateRecs[mo] = Climate.TimestepData[ecoregion.Index, mo];
// mon_T_normal[mo] = (climateRecs[mo].AvgMinTemp + climateRecs[mo].AvgMinTemp) / 2;
// }
// double AWC = fieldCapacity - wiltingPoint;
// //double latitude = Landis.Extension.Succession.Century.EcoregionData.Latitude[ecoregion];
// new PDSI_Calculator().CalculatePDSI(acs, mon_T_normal, AWC, latitude, /*outputFilePath,*/ UnitSystem.metrics);
// }
//}
//public static void GenerateEcoregionClimateData()
//{
//}
public static void GenerateEcoregionClimateData(IEcoregion ecoregion, int startYear, double latitude, double fieldCapacity, double wiltingPoint)
{
Climate.ModelCore.UI.WriteLine(" Generating Ecoregion Climate Data for ecoregion = {0}.", ecoregion.Name);
int numberOftimeSteps = Climate.ModelCore.EndTime - Climate.ModelCore.StartTime;
annualPDSI = new double[Climate.ModelCore.Ecoregions.Count, future_allData.Count]; //numberOftimeSteps + 1];
landscapeAnnualPDSI = new double[future_allData.Count]; //numberOftimeSteps+1];
double[] temperature_normals = new double[12];
double availableWaterCapacity = fieldCapacity - wiltingPoint;
//Climate.ModelCore.UI.WriteLine(" Latitude = {0}, Available Water = {1}.", latitude, availableWaterCapacity);
//IClimateRecord[] climateRecs = new ClimateRecord[12];
//int minimumTime = 5000;
//Firt Calculate Climate Normals from Spin-up data
foreach (KeyValuePair<int, IClimateRecord[,]> timeStep in spinup_allData)
{
//Climate.ModelCore.UI.WriteLine(" Calculating Weather for SPINUP Year = {0}.", timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, startYear + timeStep.Key, latitude, Climate.Phase.SpinUp_Climate, timeStep.Key);
Spinup_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] += annualClimateMonthly.MonthlyTemp[mo];
}
}
// Calculate AVERAGE T normal.
for (int mo = 0; mo < 12; mo++)
{
temperature_normals[mo] /= (double)spinup_allData.Count;
//Climate.ModelCore.UI.WriteLine("Month = {0}, Original Monthly T normal = {1}", mo, month_Temp_normal[mo]);
}
int timestepIndex = 0;
// Next calculate PSDI for the future data
foreach (KeyValuePair<int, AnnualClimate_Monthly[]> timeStep in Future_MonthlyData)
//foreach (KeyValuePair<int, IClimateRecord[,]> timeStep in future_allData)
{
//if (timeStep.Key < minimumTime)
// minimumTime = timeStep.Key;
//if (timestepIndex > numberOftimeSteps)
// break;
//Climate.ModelCore.UI.WriteLine(" Calculating Weather for FUTURE Year = {0}.", timeStep.Key);
AnnualClimate_Monthly annualClimateMonthly = new AnnualClimate_Monthly(ecoregion, startYear + timeStep.Key, latitude, Climate.Phase.Future_Climate, timeStep.Key);
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index] = annualClimateMonthly;
Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI = PDSI_Calculator.CalculatePDSI(annualClimateMonthly, temperature_normals, availableWaterCapacity, latitude, UnitSystem.metrics, ecoregion);
Climate.LandscapeAnnualPDSI[timestepIndex] += (Future_MonthlyData[startYear + timeStep.Key][ecoregion.Index].PDSI / Climate.ModelCore.Ecoregions.Count);
//Climate.ModelCore.UI.WriteLine("Calculated PDSI for Ecoregion {0}, timestep {1}, PDSI Year {2}; PDSI={3:0.00}.", ecoregion.Name, timestepIndex, timeStep.Key, PDSI);
timestepIndex++;
}
}
