Failed
tests / testsuite-gcc / simulation_libraries_3rdParty_TestMedia.TestFlueGas.mos (from (result.xml))
Stacktrace
Output mismatch (see stdout for details)
Standard Output
+ TestFlueGas.mos [instantiate/check/simulate] ... equation mismatch [time: 12] ==== Log /tmp/omc-rtest-unknown/simulation/libraries/3rdParty/TestMedia/TestFlueGas.mos_temp6253/log-TestFlueGas.mos true "" true "" "function Modelica.Math.asin \"Inverse sine (-1 <= u <= 1)\" input Real u; output Real y(quantity = \"Angle\", unit = \"rad\", displayUnit = \"deg\"); external \"C\" y = asin(u); end Modelica.Math.asin; function Modelica.Math.log \"Natural (base e) logarithm (u shall be > 0)\" input Real u; output Real y; external \"C\" y = log(u); end Modelica.Math.log; function Modelica.Media.IdealGases.Common.DataRecord \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord res; end Modelica.Media.IdealGases.Common.DataRecord; function Modelica.Media.IdealGases.Common.DataRecord$Ar \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$Ar\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$Ar res; end Modelica.Media.IdealGases.Common.DataRecord$Ar; function Modelica.Media.IdealGases.Common.DataRecord$C2H2_vinylidene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C2H2_vinylidene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C2H2_vinylidene res; end Modelica.Media.IdealGases.Common.DataRecord$C2H2_vinylidene; function Modelica.Media.IdealGases.Common.DataRecord$C2H4 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C2H4\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C2H4 res; end Modelica.Media.IdealGases.Common.DataRecord$C2H4; function Modelica.Media.IdealGases.Common.DataRecord$C2H5OH \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C2H5OH\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C2H5OH res; end Modelica.Media.IdealGases.Common.DataRecord$C2H5OH; function Modelica.Media.IdealGases.Common.DataRecord$C2H6 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C2H6\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C2H6 res; end Modelica.Media.IdealGases.Common.DataRecord$C2H6; function Modelica.Media.IdealGases.Common.DataRecord$C3H6_propylene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C3H6_propylene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C3H6_propylene res; end Modelica.Media.IdealGases.Common.DataRecord$C3H6_propylene; function Modelica.Media.IdealGases.Common.DataRecord$C3H8 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C3H8\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C3H8 res; end Modelica.Media.IdealGases.Common.DataRecord$C3H8; function Modelica.Media.IdealGases.Common.DataRecord$C4H10_n_butane \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C4H10_n_butane\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C4H10_n_butane res; end Modelica.Media.IdealGases.Common.DataRecord$C4H10_n_butane; function Modelica.Media.IdealGases.Common.DataRecord$C4H8_1_butene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C4H8_1_butene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C4H8_1_butene res; end Modelica.Media.IdealGases.Common.DataRecord$C4H8_1_butene; function Modelica.Media.IdealGases.Common.DataRecord$C5H10_1_pentene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C5H10_1_pentene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C5H10_1_pentene res; end Modelica.Media.IdealGases.Common.DataRecord$C5H10_1_pentene; function Modelica.Media.IdealGases.Common.DataRecord$C5H12_n_pentane \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C5H12_n_pentane\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C5H12_n_pentane res; end Modelica.Media.IdealGases.Common.DataRecord$C5H12_n_pentane; function Modelica.Media.IdealGases.Common.DataRecord$C6H12_1_hexene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C6H12_1_hexene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C6H12_1_hexene res; end Modelica.Media.IdealGases.Common.DataRecord$C6H12_1_hexene; function Modelica.Media.IdealGases.Common.DataRecord$C6H14_n_hexane \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C6H14_n_hexane\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C6H14_n_hexane res; end Modelica.Media.IdealGases.Common.DataRecord$C6H14_n_hexane; function Modelica.Media.IdealGases.Common.DataRecord$C6H6 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C6H6\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C6H6 res; end Modelica.Media.IdealGases.Common.DataRecord$C6H6; function Modelica.Media.IdealGases.Common.DataRecord$C7H14_1_heptene \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C7H14_1_heptene\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C7H14_1_heptene res; end Modelica.Media.IdealGases.Common.DataRecord$C7H14_1_heptene; function Modelica.Media.IdealGases.Common.DataRecord$C7H16_n_heptane \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C7H16_n_heptane\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C7H16_n_heptane res; end Modelica.Media.IdealGases.Common.DataRecord$C7H16_n_heptane; function Modelica.Media.IdealGases.Common.DataRecord$C8H10_ethylbenz \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C8H10_ethylbenz\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C8H10_ethylbenz res; end Modelica.Media.IdealGases.Common.DataRecord$C8H10_ethylbenz; function Modelica.Media.IdealGases.Common.DataRecord$C8H18_n_octane \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$C8H18_n_octane\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$C8H18_n_octane res; end Modelica.Media.IdealGases.Common.DataRecord$C8H18_n_octane; function Modelica.Media.IdealGases.Common.DataRecord$CH3OH \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$CH3OH\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$CH3OH res; end Modelica.Media.IdealGases.Common.DataRecord$CH3OH; function Modelica.Media.IdealGases.Common.DataRecord$CH4 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$CH4\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$CH4 res; end Modelica.Media.IdealGases.Common.DataRecord$CH4; function Modelica.Media.IdealGases.Common.DataRecord$CL2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$CL2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$CL2 res; end Modelica.Media.IdealGases.Common.DataRecord$CL2; function Modelica.Media.IdealGases.Common.DataRecord$CO \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$CO\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$CO res; end Modelica.Media.IdealGases.Common.DataRecord$CO; function Modelica.Media.IdealGases.Common.DataRecord$CO2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$CO2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$CO2 res; end Modelica.Media.IdealGases.Common.DataRecord$CO2; function Modelica.Media.IdealGases.Common.DataRecord$F2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$F2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$F2 res; end Modelica.Media.IdealGases.Common.DataRecord$F2; function Modelica.Media.IdealGases.Common.DataRecord$H2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$H2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$H2 res; end Modelica.Media.IdealGases.Common.DataRecord$H2; function Modelica.Media.IdealGases.Common.DataRecord$H2O \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$H2O\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$H2O res; end Modelica.Media.IdealGases.Common.DataRecord$H2O; function Modelica.Media.IdealGases.Common.DataRecord$He \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$He\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$He res; end Modelica.Media.IdealGases.Common.DataRecord$He; function Modelica.Media.IdealGases.Common.DataRecord$N2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$N2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$N2 res; end Modelica.Media.IdealGases.Common.DataRecord$N2; function Modelica.Media.IdealGases.Common.DataRecord$N2O \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$N2O\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$N2O res; end Modelica.Media.IdealGases.Common.DataRecord$N2O; function Modelica.Media.IdealGases.Common.DataRecord$NH3 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$NH3\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$NH3 res; end Modelica.Media.IdealGases.Common.DataRecord$NH3; function Modelica.Media.IdealGases.Common.DataRecord$NO \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$NO\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$NO res; end Modelica.Media.IdealGases.Common.DataRecord$NO; function Modelica.Media.IdealGases.Common.DataRecord$NO2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$NO2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$NO2 res; end Modelica.Media.IdealGases.Common.DataRecord$NO2; function Modelica.Media.IdealGases.Common.DataRecord$Ne \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$Ne\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$Ne res; end Modelica.Media.IdealGases.Common.DataRecord$Ne; function Modelica.Media.IdealGases.Common.DataRecord$O2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$O2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$O2 res; end Modelica.Media.IdealGases.Common.DataRecord$O2; function Modelica.Media.IdealGases.Common.DataRecord$SO2 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$SO2\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$SO2 res; end Modelica.Media.IdealGases.Common.DataRecord$SO2; function Modelica.Media.IdealGases.Common.DataRecord$SO3 \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.DataRecord$SO3\" input String name; input Real MM(quantity = \"MolarMass\", unit = \"kg/mol\", min = 0.0); input Real Hf(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real H0(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0); input Real Tlimit(quantity = \"ThermodynamicTemperature\", unit = \"K\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0, displayUnit = \"degC\"); input Real[7] alow; input Real[2] blow; input Real[7] ahigh; input Real[2] bhigh; input Real R(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); output DataRecord$SO3 res; end Modelica.Media.IdealGases.Common.DataRecord$SO3; function Modelica.Media.IdealGases.Common.SingleGasNasa.FluidConstants \"Automatically generated record constructor for Modelica.Media.IdealGases.Common.SingleGasNasa.FluidConstants\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants res; end Modelica.Media.IdealGases.Common.SingleGasNasa.FluidConstants; function Modelica.Media.IdealGases.Common.SingleGasNasa.h_T \"Compute specific enthalpy from temperature and gas data; reference is decided by the refChoice input, or by the referenceChoice package constant by default\" input Modelica.Media.IdealGases.Common.DataRecord data \"Ideal gas data\"; input Real T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0) \"Temperature\"; input Boolean exclEnthForm = true \"If true, enthalpy of formation Hf is not included in specific enthalpy h\"; input enumeration(ZeroAt0K, ZeroAt25C, UserDefined) refChoice = Modelica.Media.IdealGases.Common.SingleGasNasa.Choices.ReferenceEnthalpy.ZeroAt0K \"Choice of reference enthalpy\"; input Real h_off(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0) = 0.0 \"User defined offset for reference enthalpy, if referenceChoice = UserDefined\"; output Real h(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0) \"Specific enthalpy at temperature T\"; algorithm h := smooth(0, (if T < data.Tlimit then data.R * (T * (data.blow[1] + data.alow[2] * log(T) + T * (data.alow[3] + T * (0.5 * data.alow[4] + T * (0.3333333333333333 * data.alow[5] + T * (0.25 * data.alow[6] + 0.2 * data.alow[7] * T))))) - data.alow[1]) / T else data.R * (T * (data.bhigh[1] + data.ahigh[2] * log(T) + T * (data.ahigh[3] + T * (0.5 * data.ahigh[4] + T * (0.3333333333333333 * data.ahigh[5] + T * (0.25 * data.ahigh[6] + 0.2 * data.ahigh[7] * T))))) - data.ahigh[1]) / T) + (if exclEnthForm then -data.Hf else 0.0) + (if refChoice == Modelica.Media.Interfaces.PartialMedium.Choices.ReferenceEnthalpy.ZeroAt0K then data.H0 else 0.0) + (if refChoice == Modelica.Media.Interfaces.PartialMedium.Choices.ReferenceEnthalpy.UserDefined then h_off else 0.0)); end Modelica.Media.IdealGases.Common.SingleGasNasa.h_T; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$CO res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO2 \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO2\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$CO2 res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$CO2; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2 \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$H2 res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2O \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2O\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$H2O res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$H2O; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$N2 \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$N2\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$N2 res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$N2; function Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$O2 \"Automatically generated record constructor for Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$O2\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(min = 0.0, max = 100000000.0, nominal = 100000.0, start = 100000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(min = 1.0, max = 10000.0, nominal = 300.0, start = 300.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(min = -100000000.0, max = 100000000.0, nominal = 1000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants$O2 res; end Modelica.Media.Interfaces.PartialMixtureMedium.FluidConstants$O2; function Modelica.SIunits.Conversions.from_degC \"Convert from Celsius to Kelvin\" input Real Celsius(quantity = \"ThermodynamicTemperature\", unit = \"degC\") \"Celsius value\"; output Real Kelvin(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0) \"Kelvin value\"; algorithm Kelvin := 273.15 + Celsius; end Modelica.SIunits.Conversions.from_degC; function TestMedia.TestModels.TestFlueGas.Medium.FluidConstants \"Automatically generated record constructor for TestMedia.TestModels.TestFlueGas.Medium.FluidConstants\" input String iupacName; input String casRegistryNumber; input String chemicalFormula; input String structureFormula; input Real molarMass(min = 0.001, max = 0.25, nominal = 0.032, quantity = \"MolarMass\", unit = \"kg/mol\"); input Real criticalTemperature(start = 500.0, nominal = 500.0, min = 1.0, max = 10000.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real criticalPressure(start = 1000000.0, nominal = 1000000.0, min = 0.0, max = 100000000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real criticalMolarVolume(min = 1e-06, max = 1000000.0, nominal = 1.0, quantity = \"MolarVolume\", unit = \"m3/mol\"); input Real acentricFactor; input Real meltingPoint(start = 500.0, nominal = 500.0, min = 1.0, max = 10000.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real normalBoilingPoint(start = 500.0, nominal = 500.0, min = 1.0, max = 10000.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real dipoleMoment(min = 0.0, max = 2.0, unit = \"debye\", quantity = \"ElectricDipoleMoment\"); input Boolean hasIdealGasHeatCapacity = false; input Boolean hasCriticalData = false; input Boolean hasDipoleMoment = false; input Boolean hasFundamentalEquation = false; input Boolean hasLiquidHeatCapacity = false; input Boolean hasSolidHeatCapacity = false; input Boolean hasAccurateViscosityData = false; input Boolean hasAccurateConductivityData = false; input Boolean hasVapourPressureCurve = false; input Boolean hasAcentricFactor = false; input Real HCRIT0(start = 300000.0, nominal = 100000.0, min = -100000000.0, max = 100000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real SCRIT0(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; input Real deltah(start = 300000.0, nominal = 100000.0, min = -100000000.0, max = 100000000.0, quantity = \"SpecificEnergy\", unit = \"J/kg\") = 0.0; input Real deltas(min = -1000000.0, max = 1000000.0, nominal = 1000.0, quantity = \"SpecificEntropy\", unit = \"J/(kg.K)\") = 0.0; output FluidConstants res; end TestMedia.TestModels.TestFlueGas.Medium.FluidConstants; function TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState \"Automatically generated record constructor for TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState\" input Real p(start = 1000000.0, nominal = 1000000.0, min = 0.0, max = 100000000.0, quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\"); input Real T(start = 500.0, nominal = 500.0, min = 1.0, max = 10000.0, quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\"); input Real[6] X(quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1); output ThermodynamicState res; end TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState; function TestMedia.TestModels.TestFlueGas.Medium.density \"Return density of ideal gas\" input TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState state \"thermodynamic state record\"; output Real d(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0, max = 100000.0, start = 10.0, nominal = 10.0) \"Density\"; algorithm d := state.p / (state.T * (296.8033869505308 * state.X[1] + 4124.487568704486 * state.X[2] + 296.8383547363272 * state.X[3] + 259.8369938872708 * state.X[4] + 461.5233290850878 * state.X[5] + 188.9244822140674 * state.X[6])); end TestMedia.TestModels.TestFlueGas.Medium.density; function TestMedia.TestModels.TestFlueGas.Medium.h_TX \"Return specific enthalpy\" input Real T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 6000.0, start = 288.15, nominal = 300.0) \"Temperature\"; input Real[:] X(quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) = {0.768, 0.0, 0.0, 0.232, 0.0, 0.0} \"Independent Mass fractions of gas mixture\"; input Boolean exclEnthForm = true \"If true, enthalpy of formation Hf is not included in specific enthalpy h\"; input enumeration(ZeroAt0K, ZeroAt25C, UserDefined) refChoice = Modelica.Media.Interfaces.PartialMedium.Choices.ReferenceEnthalpy.ZeroAt0K \"Choice of reference enthalpy\"; input Real h_off(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0) = 0.0 \"User defined offset for reference enthalpy, if referenceChoice = UserDefined\"; output Real h(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0) \"Specific enthalpy at temperature T\"; algorithm h := X * {Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"N2\", 0.0280134, 0, 309498.4543111511, 1000, {22103.71497, -381.846182, 6.08273836, -0.00853091441, 1.384646189e-05, -9.62579362e-09, 2.519705809e-12}, {710.846086, -10.76003744}, {587712.406, -2239.249073, 6.06694922, -0.00061396855, 1.491806679e-07, -1.923105485e-11, 1.061954386e-15}, {12832.10415, -15.86640027}, 296.8033869505308), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"H2\", 0.00201588, 0, 4200697.462150524, 1000, {40783.2321, -800.918604, 8.21470201, -0.01269714457, 1.753605076e-05, -1.20286027e-08, 3.36809349e-12}, {2682.484665, -30.43788844}, {560812.801, -837.150474, 2.975364532, 0.001252249124, -3.74071619e-07, 5.936625200000001e-11, -3.6069941e-15}, {5339.82441, -2.202774769}, 4124.487568704486), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"CO\", 0.0280101, -3946262.098314536, 309570.6191695138, 1000, {14890.45326, -292.2285939, 5.72452717, -0.008176235030000001, 1.456903469e-05, -1.087746302e-08, 3.027941827e-12}, {-13031.31878, -7.85924135}, {461919.725, -1944.704863, 5.91671418, -0.0005664282830000001, 1.39881454e-07, -1.787680361e-11, 9.62093557e-16}, {-2466.261084, -13.87413108}, 296.8383547363272), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"O2\", 0.0319988, 0, 271263.4223783392, 1000, {-34255.6342, 484.700097, 1.119010961, 0.00429388924, -6.83630052e-07, -2.0233727e-09, 1.039040018e-12}, {-3391.45487, 18.4969947}, {-1037939.022, 2344.830282, 1.819732036, 0.001267847582, -2.188067988e-07, 2.053719572e-11, -8.193467050000001e-16}, {-16890.10929, 17.38716506}, 259.8369938872708), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"H2O\", 0.01801528, -13423382.81725291, 549760.6476280135, 1000, {-39479.6083, 575.5731019999999, 0.931782653, 0.00722271286, -7.34255737e-06, 4.95504349e-09, -1.336933246e-12}, {-33039.7431, 17.24205775}, {1034972.096, -2412.698562, 4.64611078, 0.002291998307, -6.836830479999999e-07, 9.426468930000001e-11, -4.82238053e-15}, {-13842.86509, -7.97814851}, 461.5233290850878), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"CO2\", 0.0440095, -8941478.544405185, 212805.6215135368, 1000, {49436.5054, -626.411601, 5.30172524, 0.002503813816, -2.127308728e-07, -7.68998878e-10, 2.849677801e-13}, {-45281.9846, -7.04827944}, {117696.2419, -1788.791477, 8.291523189999999, -9.22315678e-05, 4.86367688e-09, -1.891053312e-12, 6.330036589999999e-16}, {-39083.5059, -26.52669281}, 188.9244822140674), T, exclEnthForm, refChoice, h_off)}; end TestMedia.TestModels.TestFlueGas.Medium.h_TX; function TestMedia.TestModels.TestFlueGas.Medium.setState_pTX \"Return thermodynamic state as function of p, T and compUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/HARPE5PKGUCTTU7KPWYDQXZC5S:/var/lib/docker/overlay2/l/AKUSGG2DJ2VNFFSFKIZ77OVOVT:/var/lib/docker/overlay2/l/6EAWHLLNQ4VNIHV6JWX763TT3V:/var/lib/docker/overlay2/l/CSHIUSYFZCK4EBRLHZTUP4D54K:/var/lib/docker/overlay2/l/STL54MVTFWD2TABVXYNZ7IPE74:/var/lib/docker/overlay2/l/GGYGSX4UHIVXAQSELYLXSV4LV6:/var/lib/docker/overlay2/l/FGCIUGECWESRTLJ22UYYTVRTIF:/var/lib/docker/overlay2/l/QEFCR6W3IF3JFHZSD6HWLTY5FM:/var/lib/docker/overlay2/l/D6VBA3BXFB2KX' Unexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/HARPE5PKGUCTTU7KPWYDQXZC5S:/var/lib/docker/overlay2/l/AKUSGG2DJ2VNFFSFKIZ77OVOVT:/var/lib/docker/overlay2/l/6EAWHLLNQ4VNIHV6JWX763TT3V:/var/lib/docker/overlay2/l/CSHIUSYFZCK4EBRLHZTUP4D54K:/var/lib/docker/overlay2/l/STL54MVTFWD2TABVXYNZ7IPE74:/var/lib/docker/overlay2/l/GGYGSX4UHIVXAQSELYLXSV4LV6:/var/lib/docker/overlay2/l/FGCIUGECWESRTLJ22UYYTVRTIF:/var/lib/docker/overlay2/l/QEFCR6W3IF3JFHZSD6HWLTY5FM:/var/lib/docker/overlay2/l/D6VBA3BXFB2KX' Unexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/HARPE5PKGUCTTU7KPWYDQXZC5S:/var/lib/docker/overlay2/l/AKUSGG2DJ2VNFFSFKIZ77OVOVT:/var/lib/docker/overlay2/l/6EAWHLLNQ4VNIHV6JWX763TT3V:/var/lib/docker/overlay2/l/CSHIUSYFZCK4EBRLHZTUP4D54K:/var/lib/docker/overlay2/l/STL54MVTFWD2TABVXYNZ7IPE74:/var/lib/docker/overlay2/l/GGYGSX4UHIVXAQSELYLXSV4LV6:/var/lib/docker/overlay2/l/FGCIUGECWESRTLJ22UYYTVRTIF:/var/lib/docker/overlay2/l/QEFCR6W3IF3JFHZSD6HWLTY5FM:/var/lib/docker/overlay2/l/D6VBA3BXFB2KX' osition X\" input Real p(quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\", min = 0.0, max = 100000000.0, start = 1000000.0, nominal = 1000000.0) \"Pressure\"; input Real T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 10000.0, start = 500.0, nominal = 500.0) \"Temperature\"; input Real[:] X(quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) = {0.768, 0.0, 0.0, 0.232, 0.0, 0.0} \"Mass fractions\"; output TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState state; algorithm state := if size(X, 1) == 6 then TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState(p, T, X) else TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState(p, T, cat(1, X, {1.0 - sum(X)})); end TestMedia.TestModels.TestFlueGas.Medium.setState_pTX; function TestMedia.TestModels.TestFlueGas.Medium.specificEnthalpy \"Return specific enthalpy\" input TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState state \"thermodynamic state record\"; output Real h(quantity = \"SpecificEnergy\", unit = \"J/kg\", min = -100000000.0, max = 100000000.0, start = 300000.0, nominal = 100000.0) \"Specific enthalpy\"; algorithm h := TestMedia.TestModels.TestFlueGas.Medium.h_TX(state.T, {state.X[1], state.X[2], state.X[3], state.X[4], state.X[5], state.X[6]}, true, Modelica.Media.Interfaces.PartialMedium.Choices.ReferenceEnthalpy.ZeroAt0K, 0.0); end TestMedia.TestModels.TestFlueGas.Medium.specificEnthalpy; class TestMedia.TestModels.TestFlueGas Real state.p(quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\", min = 0.0, max = 100000000.0, start = 1000000.0, nominal = 1000000.0) \"Absolute pressure of medium\"; Real state.T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 10000.0, start = 500.0, nominal = 500.0) \"Temperature of medium\"; Real state.X[1](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real state.X[2](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real state.X[3](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real state.X[4](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real state.X[5](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real state.X[6](quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) \"Mass fractions (= (component mass)/total mass m_i/m)\"; Real p(quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\", min = 0.0, max = 100000000.0, start = 1000000.0, nominal = 1000000.0); Real h(quantity = \"SpecificEnergy\", unit = \"J/kg\", min = -100000000.0, max = 100000000.0, start = 300000.0, nominal = 100000.0); Real d(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0, max = 100000.0, start = 10.0, nominal = 10.0); Real T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 10000.0, start = 500.0, nominal = 500.0); equation T = 300.0 + 300.0 * time; p = 100000.0; state = TestMedia.TestModels.TestFlueGas.Medium.setState_pTX(p, T, {0.768, 0.0, 0.0, 0.232, 0.0, 0.0}); d = TestMedia.TestModels.TestFlueGas.Medium.density(state); h = TestMedia.TestModels.TestFlueGas.Medium.specificEnthalpy(state); end TestMedia.TestModels.TestFlueGas; " "" "Check of TestMedia.TestModels.TestFlueGas completed successfully. Class TestMedia.TestModels.TestFlueGas has 12 equation(s) and 12 variable(s). 2 of these are trivial equation(s)." "" record SimulationResult resultFile = "TestMedia.TestModels.TestFlueGas_res.mat", simulationOptions = "startTime = 0.0, stopTime = 1.0, numberOfIntervals = 500, tolerance = 1e-06, method = 'dassl', fileNamePrefix = 'TestMedia.TestModels.TestFlueGas', options = '', outputFormat = 'mat', variableFilter = '.*', cflags = '', simflags = ''", messages = "LOG_SUCCESS | info | The initialization finished successfully without homotopy method. LOG_SUCCESS | info | The simulation finished successfully. " end SimulationResult; "" Equation mismatch: diff says: --- /tmp/omc-rtest-unknown/simulation/libraries/3rdParty/TestMedia/TestFlueGas.mos_temp6253/equations-expected2019-10-28 13:24:37.707156693 +0000 +++ /tmp/omc-rtest-unknown/simulation/libraries/3rdParty/TestMedia/TestFlueGas.mos_temp6253/equations-got2019-10-28 13:24:49.575029921 +0000 @@ -846,11 +846,12 @@ output Real h(quantity = \"SpecificEnergy\", unit = \"J/kg\", nominal = 1000000.0) \"Specific enthalpy at temperature T\"; algorithm h := X * {Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"N2\", 0.0280134, 0, 309498.4543111511, 1000, {22103.71497, -381.846182, 6.08273836, -0.00853091441, 1.384646189e-05, -9.62579362e-09, 2.519705809e-12}, {710.846086, -10.76003744}, {587712.406, -2239.249073, 6.06694922, -0.00061396855, 1.491806679e-07, -1.923105485e-11, 1.061954386e-15}, {12832.10415, -15.86640027}, 296.8033869505308), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"H2\", 0.00201588, 0, 4200697.462150524, 1000, {40783.2321, -800.918604, 8.21470201, -0.01269714457, 1.753605076e-05, -1.20286027e-08, 3.36809349e-12}, {2682.484665, -30.43788844}, {560812.801, -837.150474, 2.975364532, 0.001252249124, -3.74071619e-07, 5.936625200000001e-11, -3.6069941e-15}, {5339.82441, -2.202774769}, 4124.487568704486), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"CO\", 0.0280101, -3946262.098314536, 309570.6191695138, 1000, {14890.45326, -292.2285939, 5.72452717, -0.008176235030000001, 1.456903469e-05, -1.087746302e-08, 3.027941827e-12}, {-13031.31878, -7.85924135}, {461919.725, -1944.704863, 5.91671418, -0.0005664282830000001, 1.39881454e-07, -1.787680361e-11, 9.62093557e-16}, {-2466.261084, -13.87413108}, 296.8383547363272), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"O2\", 0.0319988, 0, 271263.4223783392, 1000, {-34255.6342, 484.700097, 1.119010961, 0.00429388924, -6.83630052e-07, -2.0233727e-09, 1.039040018e-12}, {-3391.45487, 18.4969947}, {-1037939.022, 2344.830282, 1.819732036, 0.001267847582, -2.188067988e-07, 2.053719572e-11, -8.193467050000001e-16}, {-16890.10929, 17.38716506}, 259.8369938872708), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"H2O\", 0.01801528, -13423382.81725291, 549760.6476280135, 1000, {-39479.6083, 575.5731019999999, 0.931782653, 0.00722271286, -7.34255737e-06, 4.95504349e-09, -1.336933246e-12}, {-33039.7431, 17.24205775}, {1034972.096, -2412.698562, 4.64611078, 0.002291998307, -6.836830479999999e-07, 9.426468930000001e-11, -4.82238053e-15}, {-13842.86509, -7.97814851}, 461.5233290850878), T, exclEnthForm, refChoice, h_off), Modelica.Media.IdealGases.Common.SingleGasNasa.h_T(Modelica.Media.IdealGases.Common.DataRecord(\"CO2\", 0.0440095, -8941478.544405185, 212805.6215135368, 1000, {49436.5054, -626.411601, 5.30172524, 0.002503813816, -2.127308728e-07, -7.68998878e-10, 2.849677801e-13}, {-45281.9846, -7.04827944}, {117696.2419, -1788.791477, 8.291523189999999, -9.22315678e-05, 4.86367688e-09, -1.891053312e-12, 6.330036589999999e-16}, {-39083.5059, -26.52669281}, 188.9244822140674), T, exclEnthForm, refChoice, h_off)}; end TestMedia.TestModels.TestFlueGas.Medium.h_TX; -function TestMedia.TestModels.TestFlueGas.Medium.setState_pTX \"Return thermodynamic state as function of p, T and composition X\" +function TestMedia.TestModels.TestFlueGas.Medium.setState_pTX \"Return thermodynamic state as function of p, T and compUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/HARPE5PKGUCTTU7KPWYDQXZC5S:/var/lib/docker/overlay2/l/AKUSGG2DJ2VNFFSFKIZ77OVOVT:/var/lib/docker/overlay2/l/6EAWHLLNQ4VNIHV6JWX763TT3V:/var/lib/docker/overlay2/l/CSHIUSYFZCK4EBRLHZTUP4D54K:/var/lib/docker/overlay2/l/STL54MVTFWD2TABVXYNZ7IPE74:/var/lib/docker/overlay2/l/GGYGSX4UHIVXAQSELYLXSV4LV6:/var/lib/docker/overlay2/l/FGCIUGECWESRTLJ22UYYTVRTIF:/var/lib/docker/overlay2/l/QEFCR6W3IF3JFHZSD6HWLTY5FM:/var/lib/docker/overlay2/l/D6VBA3BXFB2KX' +osition X\" input Real p(quantity = \"Pressure\", unit = \"Pa\", displayUnit = \"bar\", min = 0.0, max = 100000000.0, start = 1000000.0, nominal = 1000000.0) \"Pressure\"; input Real T(quantity = \"ThermodynamicTemperature\", unit = \"K\", displayUnit = \"degC\", min = 1.0, max = 10000.0, start = 500.0, nominal = 500.0) \"Temperature\"; input Real[:] X(quantity = \"MassFraction\", unit = \"kg/kg\", min = 0.0, max = 1.0, nominal = 0.1) = {0.768, 0.0, 0.0, 0.232, 0.0, 0.0} \"Mass fractions\"; output TestMedia.TestModels.TestFlueGas.Medium.ThermodynamicState state; algorithm Equation mismatch: omc-diff says: Failed 'o' 'U' Line 851: Text differs: expected: function TestMedia.TestModels.TestFlueGas.Medium.setState_pTX \"Return thermodynamic state as function of p, T and composition X\" got: function TestMedia.TestModels.TestFlueGas.Medium.setState_pTX \"Return thermodynamic state as function of p, T and compUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay == 1 out of 1 tests failed [simulation/libraries/3rdParty/TestMedia/TestFlueGas.mos_temp6253, time: 12]