public void RemoveStochasticSoilProfileFromInput_CalculationWithOutputWithProfile_ReturnInputWithoutProfileAndCalculation()
{
// Setup
PipingFailureMechanism failureMechanism = PipingTestDataGenerator.GetPipingFailureMechanismWithAllCalculationConfigurations();
IEnumerable <IPipingCalculationScenario <PipingInput> > calculations = failureMechanism.Calculations
.Cast <IPipingCalculationScenario <PipingInput> >();
var expectedAffectedObjects = new List <IObservable>();
PipingStochasticSoilProfile profileToDelete = null;
foreach (IPipingCalculationScenario <PipingInput> calculation in calculations)
{
PipingInput input = calculation.InputParameters;
PipingStochasticSoilProfile currentProfile = input.StochasticSoilProfile;
if (profileToDelete == null)
{
profileToDelete = currentProfile;
}
if (profileToDelete != null && ReferenceEquals(profileToDelete, currentProfile))
{
if (calculation.HasOutput)
{
expectedAffectedObjects.Add(calculation);
}
expectedAffectedObjects.Add(input);
}
}
// Call
IEnumerable <IObservable> affected = PipingDataSynchronizationService.RemoveStochasticSoilProfileFromInput(failureMechanism, profileToDelete);
// Assert
CollectionAssert.AreEquivalent(expectedAffectedObjects, affected);
CollectionAssert.IsEmpty(affected.OfType <PipingInput>().Where(a => a.StochasticSoilProfile != null));
CollectionAssert.IsEmpty(affected.OfType <IPipingCalculationScenario <PipingInput> >().Where(a => a.HasOutput));
}
public void GetDiameterD70_MultipleAquiferLayers_ReturnsWithParametersFromTopmostLayer()
{
// Setup
PipingInput input = PipingInputFactory.CreateInputWithAquiferAndCoverageLayer <TestPipingInput>();
const double diameterD70Mean = 0.5;
const double diameterD70CoefficientOfVariation = 0.2;
input.StochasticSoilProfile = new PipingStochasticSoilProfile(
0.0, new PipingSoilProfile("", -2.0, new[]
{
new PipingSoilLayer(1.0)
{
IsAquifer = true,
DiameterD70 = new VariationCoefficientLogNormalDistribution
{
Mean = (RoundedDouble)diameterD70Mean,
CoefficientOfVariation = (RoundedDouble)diameterD70CoefficientOfVariation
}
},
new PipingSoilLayer(0.0)
{
IsAquifer = true,
DiameterD70 = new VariationCoefficientLogNormalDistribution
{
Mean = (RoundedDouble)12.5,
CoefficientOfVariation = (RoundedDouble)2.3
}
}
}, SoilProfileType.SoilProfile1D));
// Call
VariationCoefficientLogNormalDistribution result = DerivedPipingInput.GetDiameterD70(input);
// Assert
AssertDiameterD70(result, diameterD70Mean, diameterD70CoefficientOfVariation);
}
public static void CalculateEffectiveThicknessCoverageLayer_InvalidPipingCalculationWithOutput_ReturnsNaN()
{
// Setup
var invalidPipingCalculation =
SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>(
new TestHydraulicBoundaryLocation());
// Make invalid by having surface line partially above soil profile:
double highestLevelSurfaceLine = invalidPipingCalculation.InputParameters.SurfaceLine.Points.Max(p => p.Z);
double soilProfileTop = highestLevelSurfaceLine - 0.5;
double soilProfileBottom = soilProfileTop - 0.5;
invalidPipingCalculation.InputParameters.StochasticSoilProfile = new PipingStochasticSoilProfile(
0.0,
new PipingSoilProfile("A", soilProfileBottom, new[]
{
new PipingSoilLayer(soilProfileTop)
{
IsAquifer = true
}
}, SoilProfileType.SoilProfile1D));
var generalInput = new GeneralPipingInput();
// Call
PipingInput input = invalidPipingCalculation.InputParameters;
double result = InputParameterCalculationService.CalculateEffectiveThicknessCoverageLayer(
generalInput.WaterVolumetricWeight,
PipingDesignVariableFactory.GetPhreaticLevelExit(input).GetDesignValue(),
input.ExitPointL,
input.SurfaceLine,
input.StochasticSoilProfile.SoilProfile);
// Assert
Assert.IsNaN(result);
}
public void GetSaturatedVolumicWeightOfCoverageLayer_NoCoverageLayersAboveTopAquiferLayer_ReturnsDistributionWithParametersNaN()
{
// Setup
PipingInput input = PipingInputFactory.CreateInputWithAquiferAndCoverageLayer <TestPipingInput>();
input.StochasticSoilProfile = new PipingStochasticSoilProfile(
0.0, new PipingSoilProfile("", -2.0, new[]
{
new PipingSoilLayer(2.0)
{
IsAquifer = false
},
new PipingSoilLayer(1.0)
{
IsAquifer = true
}
}, SoilProfileType.SoilProfile1D));
// Call
LogNormalDistribution result = DerivedPipingInput.GetSaturatedVolumicWeightOfCoverageLayer(input);
// Assert
AssertSaturatedVolumicWeightOfCoverageLayer(result);
}
private static IEnumerable <string> ValidateAquiferLayers(PipingInput input)
{
double surfaceLevel = input.SurfaceLine.GetZAtL(input.ExitPointL);
PipingSoilProfile pipingSoilProfile = input.StochasticSoilProfile.SoilProfile;
if (!pipingSoilProfile.GetConsecutiveAquiferLayersBelowLevel(surfaceLevel).Any())
{
yield return(Resources.PipingCalculationService_ValidateInput_No_aquifer_layer_at_ExitPointL_under_SurfaceLine);
}
else
{
VariationCoefficientLogNormalDistribution darcyPermeability = DerivedPipingInput.GetDarcyPermeability(input);
if (IsInvalidDistributionValue(darcyPermeability.Mean) || IsInvalidDistributionValue(darcyPermeability.CoefficientOfVariation))
{
yield return(Resources.PipingCalculationService_ValidateInput_Cannot_derive_DarcyPermeability);
}
VariationCoefficientLogNormalDistribution diameter70 = DerivedPipingInput.GetDiameterD70(input);
if (IsInvalidDistributionValue(diameter70.Mean) || IsInvalidDistributionValue(diameter70.CoefficientOfVariation))
{
yield return(Resources.PipingCalculationService_ValidateInput_Cannot_derive_Diameter70);
}
}
}
private static bool IsSurfaceLineProfileDefinitionComplete(PipingInput input)
{
return(input.SurfaceLine != null &&
input.StochasticSoilProfile != null &&
!double.IsNaN(input.ExitPointL));
}
private static IEnumerable <string> ValidateCoreSurfaceLineAndSoilProfileProperties(PipingInput input)
{
if (input.SurfaceLine == null)
{
yield return(Resources.PipingCalculationService_ValidateInput_No_SurfaceLine_selected);
}
if (input.StochasticSoilProfile == null)
{
yield return(Resources.PipingCalculationService_ValidateInput_No_StochasticSoilProfile_selected);
}
if (double.IsNaN(input.ExitPointL))
{
yield return(Resources.PipingCalculationService_ValidateInput_No_value_for_ExitPointL);
}
if (double.IsNaN(input.EntryPointL))
{
yield return(Resources.PipingCalculationService_ValidateInput_No_value_for_EntryPointL);
}
}
/// <summary>
/// Creates the design variable for the volumic weight of the saturated coverage layer.
/// </summary>
/// <param name="pipingInput">The piping input.</param>
/// <returns>The created <see cref="DesignVariable{LogNormalDistribution}"/>.</returns>
/// <exception cref="ArgumentNullException">Thrown when <paramref name="pipingInput"/> is <c>null</c>.</exception>
public static DesignVariable <LogNormalDistribution> GetSaturatedVolumicWeightOfCoverageLayer(PipingInput pipingInput)
{
LogNormalDistribution thicknessCoverageLayer = DerivedPipingInput.GetThicknessCoverageLayer(pipingInput);
LogNormalDistribution saturatedVolumicWeightOfCoverageLayer = DerivedPipingInput.GetSaturatedVolumicWeightOfCoverageLayer(pipingInput);
if (double.IsNaN(thicknessCoverageLayer.Mean))
{
return(new DeterministicDesignVariable <LogNormalDistribution>(saturatedVolumicWeightOfCoverageLayer));
}
return(new LogNormalDistributionDesignVariable(saturatedVolumicWeightOfCoverageLayer)
{
Percentile = 0.05
});
}
/// <summary>
/// Creates the design variable for the total thickness of the aquifer layers at the exit point.
/// </summary>
/// <param name="pipingInput">The piping input.</param>
/// <returns>The created <see cref="DesignVariable{LogNormalDistribution}"/>.</returns>
/// <exception cref="ArgumentNullException">Thrown when <paramref name="pipingInput"/> is <c>null</c>.</exception>
public static DesignVariable <LogNormalDistribution> GetThicknessAquiferLayer(PipingInput pipingInput)
{
return(new LogNormalDistributionDesignVariable(DerivedPipingInput.GetThicknessAquiferLayer(pipingInput))
{
Percentile = 0.95
});
}
/// <summary>
/// Creates the design variable for the Darcy-speed with which water flows through the aquifer layer.
/// </summary>
/// <param name="pipingInput">The piping input.</param>
/// <returns>The created <see cref="VariationCoefficientDesignVariable{VariationCoefficientLogNormalDistribution}"/>.</returns>
/// <exception cref="ArgumentNullException">Thrown when <paramref name="pipingInput"/> is <c>null</c>.</exception>
public static VariationCoefficientDesignVariable <VariationCoefficientLogNormalDistribution> GetDarcyPermeability(PipingInput pipingInput)
{
return(new VariationCoefficientLogNormalDistributionDesignVariable(DerivedPipingInput.GetDarcyPermeability(pipingInput))
{
Percentile = 0.95
});
}
/// <summary>
/// Creates the design variable for the sieve size through which 70% of the grains of the top part of the aquifer pass.
/// </summary>
/// <param name="pipingInput">The piping input.</param>
/// <returns>The created <see cref="VariationCoefficientDesignVariable{VariationCoefficientLogNormalDistribution}"/>.</returns>
/// <exception cref="ArgumentNullException">Thrown when <paramref name="pipingInput"/> is <c>null</c>.</exception>
public static VariationCoefficientDesignVariable <VariationCoefficientLogNormalDistribution> GetDiameter70(PipingInput pipingInput)
{
return(new VariationCoefficientLogNormalDistributionDesignVariable(DerivedPipingInput.GetDiameterD70(pipingInput))
{
Percentile = 0.05
});
}
/// <summary>
/// Creates the design variable for the effective thickness of the coverage layers at the exit point.
/// </summary>
/// <param name="pipingInput">The piping input.</param>
/// <param name="generalInput">The general piping input.</param>
/// <returns>The created <see cref="DesignVariable{LogNormalDistribution}"/>.</returns>
/// <exception cref="ArgumentNullException">Thrown when any input parameter is <c>null</c>.</exception>
public static DesignVariable <LogNormalDistribution> GetEffectiveThicknessCoverageLayer(PipingInput pipingInput, GeneralPipingInput generalInput)
{
LogNormalDistribution thicknessCoverageLayer = DerivedPipingInput.GetThicknessCoverageLayer(pipingInput);
LogNormalDistribution effectiveThicknessCoverageLayer = DerivedPipingInput.GetEffectiveThicknessCoverageLayer(pipingInput, generalInput);
if (double.IsNaN(thicknessCoverageLayer.Mean))
{
return(new DeterministicDesignVariable <LogNormalDistribution>(effectiveThicknessCoverageLayer));
}
return(new LogNormalDistributionDesignVariable(effectiveThicknessCoverageLayer)
{
Percentile = 0.05
});
}
