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Altaxo.Science.Thermodynamics.Fluids
HelmholtzEquationOfState Class
HelmholtzEquationOfState Methods
GetDeltaFromMassDensity Method
GetDeltaFromMoleDensity Method
GetTauFromTemperature Method
IsentropicDerivativeOfMassSpecificVolumeWrtPressure_FromMoleDensityAndTemperature Method
IsentropicDerivativeOfMoleSpecificVolumeWrtPressure_FromMoleDensityAndTemperature Method
IsothermalCompressibility_FromMassDensityAndTemperature Method
IsothermalCompressibility_FromMoleDensityAndTemperature Method
IsothermalCompressionalModulus_FromMassDensityAndTemperature Method
IsothermalCompressionalModulus_FromMoleDensityAndTemperature Method
IsothermalDerivativePressureWrtMassDensity_FromMassDensityAndTemperature Method
IsothermalDerivativePressureWrtMoleDensity_FromMoleDensityAndTemperature Method
MassDensity_FromMoleDensity Method
MassDensity_FromPressureAndTemperature Method
MassSpecificEnthalpy_FromMassDensityAndTemperature Method
MassSpecificEnthalpy_FromMoleDensityAndTemperature Method
MassSpecificEntropy_FromMassDensityAndTemperature Method
MassSpecificEntropy_FromMoleDensityAndTemperature Method
MassSpecificGibbsEnergy_FromMassDensityAndTemperature Method
MassSpecificGibbsEnergy_FromMoleDensityAndTemperature Method
MassSpecificHelmholtzEnergy_FromMassDensityAndTemperature Method
MassSpecificHelmholtzEnergy_FromMoleDensityAndTemperature Method
MassSpecificInternalEnergy_FromMassDensityAndTemperature Method
MassSpecificInternalEnergy_FromMoleDensityAndTemperature Method
MassSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature Method
MassSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature Method
MassSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature Method
MassSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature Method
MoleDensity_FromMassDensity Method
MoleDensity_FromPressureAndTemperature Method
MoleDensityEstimates_FromPressureAndTemperature Method
MoleSpecificEnthalpy_FromMassDensityAndTemperature Method
MoleSpecificEnthalpy_FromMoleDensityAndTemperature Method
MoleSpecificEntropy_FromMassDensityAndTemperature Method
MoleSpecificEntropy_FromMoleDensityAndTemperature Method
MoleSpecificGibbsEnergy_FromMassDensityAndTemperature Method
MoleSpecificGibbsEnergy_FromMoleDensityAndTemperature Method
MoleSpecificHelmholtzEnergy_FromMassDensityAndTemperature Method
MoleSpecificHelmholtzEnergy_FromMoleDensityAndTemperature Method
MoleSpecificInternalEnergy_FromMassDensityAndTemperature Method
MoleSpecificInternalEnergy_FromMoleDensityAndTemperature Method
MoleSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature Method
MoleSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature Method
MoleSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature Method
MoleSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature Method
Phi0_OfReducedVariables Method
Phi0_tau_OfReducedVariables Method
Phi0_tautau_OfReducedVariables Method
PhiR_delta_OfReducedVariables Method
PhiR_deltadelta_OfReducedVariables Method
PhiR_deltatau_OfReducedVariables Method
PhiR_OfReducedVariables Method
PhiR_tau_OfReducedVariables Method
PhiR_tautau_OfReducedVariables Method
Pow2 Method
Pressure_FromMassDensityAndTemperature Method
Pressure_FromMoleDensityAndTemperature Method
SpeedOfSound_FromMassDensityAndTemperature Method
SpeedOfSound_FromMoleDensityAndTemperature Method
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HelmholtzEquationOfState Methods

The HelmholtzEquationOfState type exposes the following members.

Methods
 NameDescription
Public methodEqualsDetermines whether the specified object is equal to the current object.
(Inherited from Object)
Protected methodFinalizeAllows an object to try to free resources and perform other cleanup operations before it is reclaimed by garbage collection.
(Inherited from Object)
Public methodGetDeltaFromMassDensity Gets the reduced density by density / ReducingMassDensity.
Public methodGetDeltaFromMoleDensity Gets the reduced density by density / ReducingMassDensity.
Public methodGetHashCodeServes as the default hash function.
(Inherited from Object)
Public methodGetTauFromTemperature Gets the inverse reduced temperature by ReducingTemperature / temperature.
Public methodGetTypeGets the Type of the current instance.
(Inherited from Object)
Public methodIsentropicDerivativeOfMassSpecificVolumeWrtPressure_FromMoleDensityAndTemperature Gets the isentropic (adiabatic) derivative of the mass specific volume w.r.t. pressure from mole density and temperature.
Public methodIsentropicDerivativeOfMoleSpecificVolumeWrtPressure_FromMoleDensityAndTemperature Gets the isentropic (adiabatic) derivative of the mole specific volume w.r.t. pressure from mole density and temperature.
Public methodIsothermalCompressibility_FromMassDensityAndTemperature Gets the isothermal compressibility in 1/Pa from mass density (kg/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodIsothermalCompressibility_FromMoleDensityAndTemperature Gets the isothermal compressibility in 1/Pa from mole density (mol/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodIsothermalCompressionalModulus_FromMassDensityAndTemperature Gets the isothermal compressional modulus K in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodIsothermalCompressionalModulus_FromMoleDensityAndTemperature Gets the isothermal compressional modulus in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodIsothermalDerivativePressureWrtMassDensity_FromMassDensityAndTemperature Gets the derivative of pressure w.r.t. the mass density at isothermal conditions. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodIsothermalDerivativePressureWrtMoleDensity_FromMoleDensityAndTemperature Gets the derivative of pressure w.r.t. the mole density at isothermal conditions. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassDensity_FromMoleDensity Gets the mass density (in kg/m³) from mole density (in mol/m³).
Public methodMassDensity_FromPressureAndTemperature(Double, Double, Double) Gets the mass density for a given pressure and temperature.
Public methodMassDensity_FromPressureAndTemperature(Double, Double, Double, Double) Gets the mole density from a given pressure and temperature.
Public methodMassSpecificEnthalpy_FromMassDensityAndTemperature Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificEnthalpy_FromMoleDensityAndTemperature Get the enthalpy from a given density and temperature.
Public methodMassSpecificEntropy_FromMassDensityAndTemperature Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificEntropy_FromMoleDensityAndTemperature Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificGibbsEnergy_FromMassDensityAndTemperature Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificGibbsEnergy_FromMoleDensityAndTemperature Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificHelmholtzEnergy_FromMassDensityAndTemperature Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificHelmholtzEnergy_FromMoleDensityAndTemperature Get the mass specific Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificInternalEnergy_FromMassDensityAndTemperature Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificInternalEnergy_FromMoleDensityAndTemperature Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMassSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Protected methodMemberwiseCloneCreates a shallow copy of the current Object.
(Inherited from Object)
Public methodMoleDensity_FromMassDensity Gets the mole density (in mol/m³) from mass density (in kg/m³).
Public methodMoleDensity_FromPressureAndTemperature(Double, Double, Double) Get the mole density for a given pressure and temperature.
Public methodMoleDensity_FromPressureAndTemperature(Double, Double, Double, Double) Gets the mole density from a given pressure and temperature.
Public methodMoleDensityEstimates_FromPressureAndTemperature Gets an estimate of the mole densities at a given pressure and temperature.
Public methodMoleSpecificEnthalpy_FromMassDensityAndTemperature Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificEnthalpy_FromMoleDensityAndTemperature Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificEntropy_FromMassDensityAndTemperature Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificEntropy_FromMoleDensityAndTemperature Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificGibbsEnergy_FromMassDensityAndTemperature Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificGibbsEnergy_FromMoleDensityAndTemperature Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificHelmholtzEnergy_FromMassDensityAndTemperature Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificHelmholtzEnergy_FromMoleDensityAndTemperature Get the Helmholtz energy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificInternalEnergy_FromMassDensityAndTemperature Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificInternalEnergy_FromMoleDensityAndTemperature Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodMoleSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodPhi0_OfReducedVariables Ideal part of the dimensionless Helmholtz energy as function of reduced variables. (Page 1541, Table 28)
Public methodPhi0_tau_OfReducedVariables First derivative of the dimensionless Helmholtz energy as function of reduced variables with respect to the inverse reduced temperature. (Page 1541, Table 28)
Public methodPhi0_tautau_OfReducedVariables Second derivative of Phi0 the of reduced variables with respect to the inverse reduced temperature. (Page 1541, Table 28)
Public methodPhiR_delta_OfReducedVariables Calculates the first derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta.
Public methodPhiR_deltadelta_OfReducedVariables Calculates the second derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta.
Public methodPhiR_deltatau_OfReducedVariables Calculates the derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta and the inverse reduced temperature tau.
Public methodPhiR_OfReducedVariables Calculates the residual part of the dimensionless Helmholtz energy in dependence on reduced density and reduced inverse temperature.
Public methodPhiR_tau_OfReducedVariables Calculates the first derivative of the residual part of the dimensionless Helmholtz energy with respect to the inverse reduced temperature.
Public methodPhiR_tautau_OfReducedVariables Calculates the second derivative of the residual part of the dimensionless Helmholtz energy with respect to the inverse reduced temperature.
Protected methodStatic memberPow2 
Public methodPressure_FromMassDensityAndTemperature Get the pressure from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodPressure_FromMoleDensityAndTemperature Gets the pressure from a given molar density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodSpeedOfSound_FromMassDensityAndTemperature Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodSpeedOfSound_FromMoleDensityAndTemperature Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!.
Public methodToStringReturns a string that represents the current object.
(Inherited from Object)
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