public override double?[] GetZynos(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData,
IReadOnlyList <TimeVariantInputDTO> timeVariantData,
double?[] unitOutput)
{
// We return negative value here because output value measure "Financial Benefits & Costs - OMA"
// is defined as "Positive Weighting" for Value Function Usage, and it is used as output measure by mulitple Value Models.
return(ConvertUnitsToZynos(HelperFunctions.scaleValues(months, unitOutput, -1d), CommonConstants.DollarToZynoConversionFactor));
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
var result = new double?[months];
// return 0 values after the end of spend
FillWithValueAfterEndOfSpend(months, timeInvariantData.InvestmentSpendByAccountType, ref result, 0);
return(result);
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.NERC_32_Dollars.HasValue && timeInvariantData.NERC_32_Dollars.Value > 0)
{
return(PopulateOutputWithValue(months, CustomerConstants.probabilities_AlmostCertain / CommonConstants.MonthsInYear));
}
return(null);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.Account_32_Type.ValueAsInteger != CustomerConstants.OMAAccountNumber)
{
return(null);
}
return(PopulateOutputWithValue(months, 0d));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => (x.Number_32_of_32_Employees_32_Affected *
timeInvariantData.Hours_32_Saved_32_per_32_Employee *
timeInvariantData.SystemLabour_32_Cost_32_Per_32_hour *
timeInvariantData.SystemProbability_32_of_32_Repurposing
))));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.Cost_32_Savings_Cost_32_Savings_32__45__32_OMA_ConsqUnitOutput_B == null)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => (x.Costs_32_Saved))));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.Additional_32_Costs_Additional_32_Costs_32__32__45__32_Capital_ConsqUnitOutput_B == null)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => - 1d * x.Additional_32_Costs)));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.NERC_32_Dollars.HasValue && timeInvariantData.NERC_32_Dollars.Value > 0)
{
return(PopulateOutputWithValue(months,
(2 * timeInvariantData.NERC_32_Dollars * CommonConstants.DollarToZynoConversionFactor)));
}
return(null);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.Account_32_Type.ValueAsInteger != CustomerConstants.OMAAccountNumber)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => x.Costs_32_incurred_32_after_32_this_32_investment_32_is_32_undertaken)));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
if (timeInvariantData.InvestmentSpendByResource == null)
{
return(null);
}
var internalLabourHours = HelperFunctions.GetResourceCurrencyUnitsFromForecast(months, CustomerConstants.internalLabourCode, timeInvariantData.InvestmentSpendByResource);
var contractLabourHours = HelperFunctions.GetResourceCurrencyUnitsFromForecast(months, CustomerConstants.contractLabourCode, timeInvariantData.InvestmentSpendByResource);
return(HelperFunctions.CombineSeries(months, internalLabourHours, contractLabourHours));
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula assumes that "BESS Risk Issue" is used consistently accross the all time-variant answers (i.e. once true - always true).
// Measure ouptut is eliminated if "BESS Risk Issue" is true
if (timeVariantData.Any(answer => answer.BES_32_Risk_32_Issue == true))
{
return(null);
}
return(PopulateOutputWithValue(months, CustomerConstants.annualExposurePercentage / 100d
/ CommonConstants.MonthsInYear));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// Cannot calculate cosequence if system parameters are missing or have no values
if (!timeInvariantData.SystemValue_32_of_32_Improvement_32_Affecting_32_All_32_Public.HasValue)
{
return(null);
}
var publicPerceptionValue = timeInvariantData.SystemValue_32_of_32_Improvement_32_Affecting_32_All_32_Public.Value *
timeInvariantData.Percentage_32_Public / 100d;
return(PopulateOutputWithValue(months, publicPerceptionValue));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula presumes that COF & POF values, if entered, are consistently used accross all time-variant answers.
// When COF amount is used, we invalidate entire value measure
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(null);
}
return(PopulateOutputWithValue(months, CustomerConstants.consequence_Major));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// Risk consequence is the COF if it was entered in the questionnaire
// NOTE: Formula presumes that COF value, once entered, is consistently used accross all time-variant answers.
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => x.COF * CommonConstants.DollarToZynoConversionFactor))); // COF is in Dollars ($)
}
return(null);
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula presumes that COF & POF values, if entered, are consistently used accross all time-variant answers.
// When COF amount is used, we invalidate entire value measure
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(null);
}
// Risk likelihood is the POF value if it was entered in the questionnaire.
// Otherwise, risk likelihood is calculated using Condition and Design Life.
// The likelihood is then being modified by the probability modifying values.
var probabilityModifyingValues = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear,
months, (x => (x.Number_32_of_32_Assets ?? 1)
* (x.Self_32_Monitored ? 0.33 : 1)
* ((x.Manufacturer_32_Support && x.Standard_32_OS) ? 1 : 3)
* ((x.Additional_32_Failures_32_Required.HasValue && x.Additional_32_Failures_32_Required.Value > 0)
? (System.Math.Pow(0.1, x.Additional_32_Failures_32_Required.Value))
: 1)));
if (answers != null && answers.POF != null)
{
var pofMonthlyProbabilities = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => x.POF / 100d / CommonConstants.MonthsInYear));
return(HelperFunctions.MultiplySeries(months, pofMonthlyProbabilities, probabilityModifyingValues));
}
else
{
var condition = timeInvariantData.Transmission_32_Electronic_32_Asset_32_Risk_Transmission_32_Electronic_32__45__32_Condition_ConsqUnitOutput;
if (condition == null)
{
return(null);
}
var eomConditionToFailureCurve = HelperFunctions.GenericEndOfLifeModel.constructGenericEndOfLifePofCurve();
var monthlyProbabilities = ConvertConditionToMonthlyProbability(
condition, eomConditionToFailureCurve, treatProbabilityAsFrequency: true);
return(HelperFunctions.MultiplySeries(months, monthlyProbabilities, probabilityModifyingValues));
}
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula assumes that "BESS Risk Issue" is used consistently accross the all time-variant answers (i.e. once true - always true).
// Measure is calculated only if "BESS Risk Issue" is true
if (timeVariantData.Any(answer => answer.BES_32_Risk_32_Issue == true))
{
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => x.BES_32_Risk_32_Issue
? (CustomerConstants.probabilities_AlmostCertain / CommonConstants.MonthsInYear)
: CustomerConstants.probabilities_None)));
}
return(null);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula assumes that "BESS Risk Issue" is used consistently accross the all time-variant answers (i.e. once true - always true).
// Measure is calculated only if "BESS Risk Issue" is true
if (timeVariantData.Any(answer => answer.BES_32_Risk_32_Issue == true))
{
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => x.BES_32_Risk_32_Issue
? (CustomerConstants.consequence_Catastrophic)
: CustomerConstants.consequence_None)));
}
return(null);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
var renewableCapacityValues = timeInvariantData.SystemRenewable_32_Capacity_32_Value_32__40__36__47_MW_41__32_TimeSeries;
var renewableCapacityAdded = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => x.Renewable_32_Capacity_32_Added));
if (renewableCapacityValues == null || renewableCapacityAdded == null)
{
return(null);
}
var result = HelperFunctions.scaleValues(startFiscalYear, months, renewableCapacityAdded, renewableCapacityValues);
return(result);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
var cO2Prices = timeInvariantData.SystemCO2_32_Credits_32_Value_32__40__36__32__47__32_MWh_41__32_TimeSeries;
var tonsCO2Avoided = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x => x.CO2_32_Reduction));
if (cO2Prices == null || tonsCO2Avoided == null)
{
return(null);
}
var result = HelperFunctions.scaleValues(startFiscalYear, months, tonsCO2Avoided, cO2Prices);
return(result);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// Do not produce any result unless there is a baseline calculated
var baselineFinRiskConsequences = timeInvariantData.Transmission_32_Line_32_Risk_Transmission_32_Line_32__45__32_Financial_ConsqUnitOutput_B;
if (baselineFinRiskConsequences == null)
{
return(null);
}
// Return 0 values after the end of spend
var result = new double?[months];
FillWithValueAfterEndOfSpend(months, timeInvariantData.InvestmentSpendByAccountType, ref result, 0);
return(result);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula presumes that COF & POF values, if entered, are consistently used accross all time-variant answers.
// When COF amount is used, we invalidate entire value measure
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => x.Consequence_32_of_32_Environment_32_Risk != null
? x.Consequence_32_of_32_Environment_32_Risk.Value
: 0)));
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// In case COF is provided, we invalidate the entire measure calculation based on the Reliability Risk output
var monthlyReliabilityProbabilities = timeInvariantData.Transmission_32_Line_32_Risk_Transmission_32_Line_32__45__32_Reliability_LikelihoodUnitOutput_B;
if (monthlyReliabilityProbabilities == null)
{
return(null);
}
// Return 0 values after the end of spend
var result = new double?[months];
FillWithValueAfterEndOfSpend(months, timeInvariantData.InvestmentSpendByAccountType, ref result, 0);
return(result);
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// In baseline Compliance likelihood is not provided, do not output Automatic Output
var monthlyBaselineComplianceProbabilities = timeInvariantData.Transmission_32_Electronic_32_Asset_32_Risk_Transmission_32_Electronic_32__45__32_Compliance_ConsqUnitOutput_B;
if (monthlyBaselineComplianceProbabilities == null)
{
return(null);
}
// Return 0 values after the end of spend
var result = new double?[months];
FillWithValueAfterEndOfSpend(months, timeInvariantData.InvestmentSpendByAccountType, ref result, 0);
return(result);
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula presumes that COF & POF values, if entered, are consistently used accross all time-variant answers.
// When COF amount is used, we invalidate entire value measure
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(null);
}
// The LineVoltage is in USD/Day (in zynos), and the TimeToRepair is ih Hours
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => (x.Line_32_Voltage != null ?
(x.Line_32_Voltage.Value / CommonConstants.HoursInDay) : 0)
* (x.Time_32_to_32_Repair ?? 0))));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// Cannot calculate cosequence if system parameters are missing or have no values
if (!timeInvariantData.SystemEmployee_32_Productivity_32_Cost_32_Per_32_Year.HasValue ||
!timeInvariantData.SystemImpact_32_to_32_Critical_32_Process.HasValue)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => (x.Business_32_Continuity_32_Employees_32_Affected
* x.Productivity_32_Impact.Value
* timeInvariantData.SystemEmployee_32_Productivity_32_Cost_32_Per_32_Year.Value)
+ ((timeInvariantData.BIA_32_Critical ? 1 : 0)
* (timeInvariantData.Interruption_32_Exceeds_32_RTO ? 1 : 0)
* timeInvariantData.SystemImpact_32_to_32_Critical_32_Process)
)));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// We cannot use prompts in Automatic Outcome questionnaire, so we cannot check for the selected Account Type directly.
// Instead, we are checking if the Capital related measure has any output
// This will return null if the Capital account type is not selected by user.
var capitalSpends = timeInvariantData.Cost_32_Avoidance_Cost_32_Avoidance_32__32__45__32_Capital_ConsqUnitOutput_B;
if (capitalSpends == null)
{
return(null); // this eliminate measure output
}
// Return 0 values after the end of spend
var result = new double?[months];
FillWithValueAfterEndOfSpend(months, timeInvariantData.InvestmentSpendByAccountType, ref result, 0);
return(result); // this eliminate risk at the end of investment
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
var estimatedDesignLifeMeasure = timeInvariantData.Transmission_32_Station_32_Equipment_32_Risk_Transmission_32_Station_32__45__32_Design_32_Life_ConsqUnitOutput_B;
if (estimatedDesignLifeMeasure == null)
{
return(null);
}
double estimatedDesignLife = estimatedDesignLifeMeasure[0].Value;
double defaultOutcomeCondition = 10.0;
TimePeriodDTO timePeriod = new TimePeriodDTO();
var endOfSpendMonthOffset = FindEndOfSpendMonth(timeInvariantData.InvestmentSpendByAccountType);
if (!endOfSpendMonthOffset.HasValue)
{
return(null);
}
timePeriod.StartTime = GetCalendarDateTime(startFiscalYear, fiscalPeriod: 1)
.AddMonths(endOfSpendMonthOffset.Value + 1); // + 1 because the benefit starts in the first month after end of spend.
TimeVariantLocalConditionDTO localTimeInvariantData =
new TimeVariantLocalConditionDTO(defaultOutcomeCondition, timePeriod);
List <TimeVariantLocalConditionDTO> localTimeInvariantDataList
= new List <TimeVariantLocalConditionDTO>();
localTimeInvariantDataList.Add(localTimeInvariantData);
// A generic end of life condition decay curve, generated based on the design life entered by user.
XYCurveDTO conditionDecayCurve = HelperFunctions.GenericEndOfLifeModel.constructConditionDecayCurve(estimatedDesignLife);
return(InterpolateCurve <TimeVariantLocalConditionDTO>(localTimeInvariantDataList,
startFiscalYear,
months,
conditionDecayCurve,
x => x.ConditionScoreLocal));
}
public override double?[] GetUnits(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// Cannot calculate cosequence if system parameters are missing or have no values
if (!timeInvariantData.SystemValue_32_per_32_Candidate_32_Attracted.HasValue ||
!timeInvariantData.SystemEmployee_32_Productivity_32_Value.HasValue ||
!timeInvariantData.SystemEmployee_32_Cost_32_to_32_Replace.HasValue)
{
return(null);
}
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData,
startFiscalYear,
months, (x =>
(x.Number_32_of_32_Candidates_32_Attracted * x.Workplace_32_Impact_32_On_32_Attractiveness.Value
* timeInvariantData.SystemValue_32_per_32_Candidate_32_Attracted.Value) +
(x.Number_32_of_32_Employees_32_Affected * x.Workplace_32_Impact_32_On_32_Productivity.Value
* timeInvariantData.SystemEmployee_32_Productivity_32_Value.Value) +
(x.Number_32_of_32_Employees_32_At_32_Risk_32_Of_32_Leaving * x.Workplace_32_Impact_32_On_32_Productivity.Value
* timeInvariantData.SystemEmployee_32_Cost_32_to_32_Replace.Value)
)));
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
// NOTE: Formula presumes that COF & POF values, if entered, are consistently used accross all time-variant answers.
// When COF amount is used, we invalidate entire value measure
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.COF != null)
{
return(null);
}
// Risk probability is the POF if it was entered in the questionnaire.
// Otherwise, risk likelihood is calculated using Condition and Design Life.
if (answers != null && answers.POF != null)
{
return(InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => x.POF / 100d / CommonConstants.MonthsInYear)));
}
else
{
var condition = timeInvariantData.Transmission_32_Line_32_Risk_Transmission_32_Line_32__45__32_Condition_ConsqUnitOutput;
if (condition == null)
{
return(null);
}
var eomConditionToFailureCurve = HelperFunctions.GenericEndOfLifeModel.constructGenericEndOfLifePofCurve();
var monthlyProbabilities = ConvertConditionToMonthlyProbability(
condition, eomConditionToFailureCurve, treatProbabilityAsFrequency: true);
return(monthlyProbabilities);
}
}
public override double?[] GetLikelihoodValues(int startFiscalYear, int months,
TimeInvariantInputDTO timeInvariantData, IReadOnlyList <TimeVariantInputDTO> timeVariantData)
{
double?[] monthlyFailureProbabilities = null;
// Risk probability is the POF if it was entered in the questionnaire;
// otherwise, risk likelihood is calculated using Condition and Design Life
// NOTE: Formula presumes that POF value, if entered, is consistently used accross all time-variant answers.
var answers = timeVariantData.FirstOrDefault();
if (answers != null && answers.POF != null)
{
monthlyFailureProbabilities = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => x.POF / 100d / CommonConstants.MonthsInYear));
}
else
{
var condition = timeInvariantData.Transmission_32_Station_32_Equipment_32_Risk_Transmission_32_Station_32__45__32_Condition_ConsqUnitOutput;
if (condition == null)
{
return(null);
}
var eomConditionToFailureCurve = HelperFunctions.GenericEndOfLifeModel.constructGenericEndOfLifePofCurve();
monthlyFailureProbabilities = ConvertConditionToMonthlyProbability(
condition, eomConditionToFailureCurve, treatProbabilityAsFrequency: true);
}
// Probability of Collateral Damage is mandatory input variable
var collateralDamageProbabilities = InterpolatePropagate <TimeVariantInputDTO>(timeVariantData, startFiscalYear, months,
(x => (x.Probability_32_of_32_Collateral_32_Damage / 100d)));
return(HelperFunctions.MultiplySeries(months, monthlyFailureProbabilities, collateralDamageProbabilities));
}
