Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.conf.json loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo", uses=false) [Timeout 180] "Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo): time 0.0006412/0.0006412, allocations: 84.23 kB / 20.06 MB, free: 4.465 MB / 18.57 MB " [Timeout remaining time 180] loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo", uses=false) [Timeout 180] "Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo): time 0.0007323/0.0007323, allocations: 173.9 kB / 23.36 MB, free: 1.16 MB / 18.57 MB " [Timeout remaining time 180] loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo", uses=false) [Timeout 180] "Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo): time 0.8922/0.8922, allocations: 177.1 MB / 203.7 MB, free: 5.727 MB / 186.7 MB " [Timeout remaining time 179] loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo", uses=false) [Timeout 180] "Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo): time 0.6913/0.6913, allocations: 116 MB / 376.2 MB, free: 4.191 MB / 346.7 MB " [Timeout remaining time 179] Using package ThermofluidStream with version 1.3.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo) Using package Modelica with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo) Using package Complex with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo) Using package ModelicaServices with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo) Running command: translateModel(ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2,tolerance=1e-06,outputFormat="mat",numberOfIntervals=100,variableFilter="CPUtime|EventCounter|T_in|Time|_derdummy|_dummy|der.dp.|der.pRatio.|dp|dp1.L|dp1.P|dp1.P_in|dp1.P_nom|dp1.TC|der.dp1.adiabaticModel.w_t_is.|dp1.adiabaticModel.eta_is|dp1.adiabaticModel.h_in|dp1.adiabaticModel.h_out|dp1.adiabaticModel.h_out_is|dp1.adiabaticModel.p_out|dp1.adiabaticModel.s_in|dp1.adiabaticModel.state_in.T|dp1.adiabaticModel.state_in.p|dp1.adiabaticModel.w_t|dp1.adiabaticModel.w_t_is|dp1.assertionLevel|dp1.clip_p_out|der.dp1.P.|der.dp1.h_out.|dp1.dh|dp1.dp|dp1.dp_fixed|dp1.dp_nom|dp1.dp_start|dp1.dr_corr|dp1.etaSpec|dp1.eta_actual|dp1.eta_fixed|dp1.eta_is|dp1.h_in|dp1.h_out|dp1.initM_flow|der.dp1.inlet.m_flow.|dp1.inlet.m_flow|dp1.inlet.r|dp1.inlet.state.T|dp1.inlet.state.p|dp1.m_acceleration_0|dp1.m_flow|dp1.m_flowStateSelect|dp1.m_flow_0|dp1.outlet.m_flow|dp1.outlet.r|dp1.outlet.state.T|dp1.outlet.state.p|dp1.outletSpec|dp1.outletSpec_actual|dp1.outletSpec_prescribed|dp1.outletValueSpec|dp1.pRatio|dp1.pRatio_fixed|dp1.p_in|dp1.p_min|dp1.p_out|dp1.p_out_fixed|dp1.singularityRegime|dropOfCommons.L|dropOfCommons.assertionLevel|dropOfCommons.g|dropOfCommons.instanceNameColor.1.|dropOfCommons.instanceNameColor.2.|dropOfCommons.instanceNameColor.3.|dropOfCommons.k_volume_damping|dropOfCommons.m_flow_reg|dropOfCommons.omega_reg|dropOfCommons.p_min|dropOfCommons.rho_min|energyFlowSource.E_flow|energyFlowSource.E_flow_out|eta_is|outletPressure.y|pOut1.L|pOut1.P|pOut1.P_in|pOut1.P_nom|pOut1.TC|der.pOut1.adiabaticModel.w_t_is.|pOut1.adiabaticModel.eta_is|pOut1.adiabaticModel.h_in|pOut1.adiabaticModel.h_out|pOut1.adiabaticModel.h_out_is|pOut1.adiabaticModel.p_out|pOut1.adiabaticModel.s_in|pOut1.adiabaticModel.state_in.T|pOut1.adiabaticModel.state_in.p|pOut1.adiabaticModel.w_t|pOut1.adiabaticModel.w_t_is|pOut1.assertionLevel|pOut1.clip_p_out|der.pOut1.h_out.|pOut1.dh|pOut1.dp|pOut1.dp_fixed|pOut1.dp_nom|pOut1.dp_start|pOut1.dr_corr|pOut1.etaSpec|pOut1.eta_actual|pOut1.eta_fixed|pOut1.eta_is|pOut1.h_in|pOut1.h_out|pOut1.initM_flow|der.pOut1.inlet.m_flow.|pOut1.inlet.m_flow|pOut1.inlet.r|pOut1.inlet.state.T|pOut1.inlet.state.p|pOut1.m_acceleration_0|pOut1.m_flow|pOut1.m_flowStateSelect|pOut1.m_flow_0|pOut1.outlet.m_flow|pOut1.outlet.r|pOut1.outlet.state.T|pOut1.outlet.state.p|pOut1.outletSpec|pOut1.outletSpec_actual|pOut1.outletSpec_prescribed|pOut1.outletValueSpec|pOut1.pRatio|pOut1.pRatio_fixed|pOut1.p_in|pOut1.p_min|pOut1.p_out|pOut1.p_out_fixed|pOut1.singularityRegime|pRatio|pRatio1.L|pRatio1.P|pRatio1.P_in|pRatio1.P_nom|pRatio1.TC|der.pRatio1.adiabaticModel.w_t_is.|pRatio1.adiabaticModel.eta_is|pRatio1.adiabaticModel.h_in|pRatio1.adiabaticModel.h_out|pRatio1.adiabaticModel.h_out_is|pRatio1.adiabaticModel.p_out|pRatio1.adiabaticModel.s_in|pRatio1.adiabaticModel.state_in.T|pRatio1.adiabaticModel.state_in.p|pRatio1.adiabaticModel.w_t|pRatio1.adiabaticModel.w_t_is|pRatio1.assertionLevel|pRatio1.clip_p_out|der.pRatio1.h_out.|pRatio1.dh|pRatio1.dp|pRatio1.dp_fixed|pRatio1.dp_nom|pRatio1.dp_start|pRatio1.dr_corr|pRatio1.etaSpec|pRatio1.eta_actual|pRatio1.eta_fixed|pRatio1.eta_is|pRatio1.h_in|pRatio1.h_out|pRatio1.initM_flow|der.pRatio1.inlet.m_flow.|pRatio1.inlet.m_flow|pRatio1.inlet.r|pRatio1.inlet.state.T|pRatio1.inlet.state.p|pRatio1.m_acceleration_0|pRatio1.m_flow|pRatio1.m_flowStateSelect|pRatio1.m_flow_0|pRatio1.outlet.m_flow|pRatio1.outlet.r|pRatio1.outlet.state.T|pRatio1.outlet.state.p|pRatio1.outletSpec|pRatio1.outletSpec_actual|pRatio1.outletSpec_prescribed|pRatio1.outletValueSpec|pRatio1.pRatio|pRatio1.pRatio_fixed|pRatio1.p_in|pRatio1.p_min|pRatio1.p_out|pRatio1.p_out_fixed|pRatio1.singularityRegime|p_in|p_out|power.T_falling|power.T_rising|power.T_start|power.T_width|power.amplitude|power.count|power.falling|power.nperiod|power.offset|power.period|power.rising|power.startTime|power.width|power.y|pressureDifference.T_falling|pressureDifference.T_rising|pressureDifference.T_start|pressureDifference.T_width|pressureDifference.amplitude|pressureDifference.count|pressureDifference.falling|pressureDifference.nperiod|pressureDifference.offset|pressureDifference.period|pressureDifference.rising|pressureDifference.startTime|pressureDifference.width|pressureDifference.y|pressureRatio.y|sink.L|der.sink.inlet.m_flow.|sink.inlet.m_flow|sink.inlet.r|sink.inlet.state.T|sink.inlet.state.p|sink1.L|der.sink1.inlet.m_flow.|sink1.inlet.m_flow|sink1.inlet.r|sink1.inlet.state.T|der.sink1.inlet.state.p.|sink1.inlet.state.p|sink2.L|der.sink2.inlet.m_flow.|sink2.inlet.m_flow|sink2.inlet.r|sink2.inlet.state.T|sink2.inlet.state.p|source.L|source.T0|source.T0_par|source.h0|source.h0_par|der.source.outlet.m_flow.|source.outlet.m_flow|source.outlet.r|source.outlet.state.T|source.outlet.state.p|source.p0|source.p0_par|source1.L|source1.T0|source1.T0_par|source1.h0|source1.h0_par|der.source1.outlet.m_flow.|source1.outlet.m_flow|source1.outlet.r|source1.outlet.state.T|source1.outlet.state.p|source1.p0|source1.p0_par|source2.L|source2.T0|source2.T0_par|source2.h0|source2.h0_par|der.source2.outlet.m_flow.|source2.outlet.m_flow|source2.outlet.r|source2.outlet.state.T|source2.outlet.state.p|source2.p0|source2.p0_par",fileNamePrefix="ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2") translateModel(ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2,tolerance=1e-06,outputFormat="mat",numberOfIntervals=100,variableFilter="CPUtime|EventCounter|T_in|Time|_derdummy|_dummy|der.dp.|der.pRatio.|dp|dp1.L|dp1.P|dp1.P_in|dp1.P_nom|dp1.TC|der.dp1.adiabaticModel.w_t_is.|dp1.adiabaticModel.eta_is|dp1.adiabaticModel.h_in|dp1.adiabaticModel.h_out|dp1.adiabaticModel.h_out_is|dp1.adiabaticModel.p_out|dp1.adiabaticModel.s_in|dp1.adiabaticModel.state_in.T|dp1.adiabaticModel.state_in.p|dp1.adiabaticModel.w_t|dp1.adiabaticModel.w_t_is|dp1.assertionLevel|dp1.clip_p_out|der.dp1.P.|der.dp1.h_out.|dp1.dh|dp1.dp|dp1.dp_fixed|dp1.dp_nom|dp1.dp_start|dp1.dr_corr|dp1.etaSpec|dp1.eta_actual|dp1.eta_fixed|dp1.eta_is|dp1.h_in|dp1.h_out|dp1.initM_flow|der.dp1.inlet.m_flow.|dp1.inlet.m_flow|dp1.inlet.r|dp1.inlet.state.T|dp1.inlet.state.p|dp1.m_acceleration_0|dp1.m_flow|dp1.m_flowStateSelect|dp1.m_flow_0|dp1.outlet.m_flow|dp1.outlet.r|dp1.outlet.state.T|dp1.outlet.state.p|dp1.outletSpec|dp1.outletSpec_actual|dp1.outletSpec_prescribed|dp1.outletValueSpec|dp1.pRatio|dp1.pRatio_fixed|dp1.p_in|dp1.p_min|dp1.p_out|dp1.p_out_fixed|dp1.singularityRegime|dropOfCommons.L|dropOfCommons.assertionLevel|dropOfCommons.g|dropOfCommons.instanceNameColor.1.|dropOfCommons.instanceNameColor.2.|dropOfCommons.instanceNameColor.3.|dropOfCommons.k_volume_damping|dropOfCommons.m_flow_reg|dropOfCommons.omega_reg|dropOfCommons.p_min|dropOfCommons.rho_min|energyFlowSource.E_flow|energyFlowSource.E_flow_out|eta_is|outletPressure.y|pOut1.L|pOut1.P|pOut1.P_in|pOut1.P_nom|pOut1.TC|der.pOut1.adiabaticModel.w_t_is.|pOut1.adiabaticModel.eta_is|pOut1.adiabaticModel.h_in|pOut1.adiabaticModel.h_out|pOut1.adiabaticModel.h_out_is|pOut1.adiabaticModel.p_out|pOut1.adiabaticModel.s_in|pOut1.adiabaticModel.state_in.T|pOut1.adiabaticModel.state_in.p|pOut1.adiabaticModel.w_t|pOut1.adiabaticModel.w_t_is|pOut1.assertionLevel|pOut1.clip_p_out|der.pOut1.h_out.|pOut1.dh|pOut1.dp|pOut1.dp_fixed|pOut1.dp_nom|pOut1.dp_start|pOut1.dr_corr|pOut1.etaSpec|pOut1.eta_actual|pOut1.eta_fixed|pOut1.eta_is|pOut1.h_in|pOut1.h_out|pOut1.initM_flow|der.pOut1.inlet.m_flow.|pOut1.inlet.m_flow|pOut1.inlet.r|pOut1.inlet.state.T|pOut1.inlet.state.p|pOut1.m_acceleration_0|pOut1.m_flow|pOut1.m_flowStateSelect|pOut1.m_flow_0|pOut1.outlet.m_flow|pOut1.outlet.r|pOut1.outlet.state.T|pOut1.outlet.state.p|pOut1.outletSpec|pOut1.outletSpec_actual|pOut1.outletSpec_prescribed|pOut1.outletValueSpec|pOut1.pRatio|pOut1.pRatio_fixed|pOut1.p_in|pOut1.p_min|pOut1.p_out|pOut1.p_out_fixed|pOut1.singularityRegime|pRatio|pRatio1.L|pRatio1.P|pRatio1.P_in|pRatio1.P_nom|pRatio1.TC|der.pRatio1.adiabaticModel.w_t_is.|pRatio1.adiabaticModel.eta_is|pRatio1.adiabaticModel.h_in|pRatio1.adiabaticModel.h_out|pRatio1.adiabaticModel.h_out_is|pRatio1.adiabaticModel.p_out|pRatio1.adiabaticModel.s_in|pRatio1.adiabaticModel.state_in.T|pRatio1.adiabaticModel.state_in.p|pRatio1.adiabaticModel.w_t|pRatio1.adiabaticModel.w_t_is|pRatio1.assertionLevel|pRatio1.clip_p_out|der.pRatio1.h_out.|pRatio1.dh|pRatio1.dp|pRatio1.dp_fixed|pRatio1.dp_nom|pRatio1.dp_start|pRatio1.dr_corr|pRatio1.etaSpec|pRatio1.eta_actual|pRatio1.eta_fixed|pRatio1.eta_is|pRatio1.h_in|pRatio1.h_out|pRatio1.initM_flow|der.pRatio1.inlet.m_flow.|pRatio1.inlet.m_flow|pRatio1.inlet.r|pRatio1.inlet.state.T|pRatio1.inlet.state.p|pRatio1.m_acceleration_0|pRatio1.m_flow|pRatio1.m_flowStateSelect|pRatio1.m_flow_0|pRatio1.outlet.m_flow|pRatio1.outlet.r|pRatio1.outlet.state.T|pRatio1.outlet.state.p|pRatio1.outletSpec|pRatio1.outletSpec_actual|pRatio1.outletSpec_prescribed|pRatio1.outletValueSpec|pRatio1.pRatio|pRatio1.pRatio_fixed|pRatio1.p_in|pRatio1.p_min|pRatio1.p_out|pRatio1.p_out_fixed|pRatio1.singularityRegime|p_in|p_out|power.T_falling|power.T_rising|power.T_start|power.T_width|power.amplitude|power.count|power.falling|power.nperiod|power.offset|power.period|power.rising|power.startTime|power.width|power.y|pressureDifference.T_falling|pressureDifference.T_rising|pressureDifference.T_start|pressureDifference.T_width|pressureDifference.amplitude|pressureDifference.count|pressureDifference.falling|pressureDifference.nperiod|pressureDifference.offset|pressureDifference.period|pressureDifference.rising|pressureDifference.startTime|pressureDifference.width|pressureDifference.y|pressureRatio.y|sink.L|der.sink.inlet.m_flow.|sink.inlet.m_flow|sink.inlet.r|sink.inlet.state.T|sink.inlet.state.p|sink1.L|der.sink1.inlet.m_flow.|sink1.inlet.m_flow|sink1.inlet.r|sink1.inlet.state.T|der.sink1.inlet.state.p.|sink1.inlet.state.p|sink2.L|der.sink2.inlet.m_flow.|sink2.inlet.m_flow|sink2.inlet.r|sink2.inlet.state.T|sink2.inlet.state.p|source.L|source.T0|source.T0_par|source.h0|source.h0_par|der.source.outlet.m_flow.|source.outlet.m_flow|source.outlet.r|source.outlet.state.T|source.outlet.state.p|source.p0|source.p0_par|source1.L|source1.T0|source1.T0_par|source1.h0|source1.h0_par|der.source1.outlet.m_flow.|source1.outlet.m_flow|source1.outlet.r|source1.outlet.state.T|source1.outlet.state.p|source1.p0|source1.p0_par|source2.L|source2.T0|source2.T0_par|source2.h0|source2.h0_par|der.source2.outlet.m_flow.|source2.outlet.m_flow|source2.outlet.r|source2.outlet.state.T|source2.outlet.state.p|source2.p0|source2.p0_par",fileNamePrefix="ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2") [Timeout 660] "Notification: Performance of FrontEnd - Absyn->SCode: time 3.873e-05/3.873e-05, allocations: 5.828 kB / 0.5548 GB, free: 12.67 MB / 490.7 MB Notification: Performance of NFInst.instantiate(ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2): time 0.4864/0.4864, allocations: 137.3 MB / 0.6888 GB, free: 6.566 MB / 0.5573 GB Notification: Performance of NFInst.instExpressions: time 0.006529/0.493, allocations: 6.03 MB / 0.6947 GB, free: 6.09 MB / 0.5573 GB Notification: Performance of NFInst.updateImplicitVariability: time 0.001291/0.4943, allocations: 64.41 kB / 0.6948 GB, free: 6.051 MB / 0.5573 GB Notification: Performance of NFTyping.typeComponents: time 0.001382/0.4956, allocations: 445.5 kB / 0.6952 GB, free: 5.914 MB / 0.5573 GB Notification: Performance of NFTyping.typeBindings: time 0.002817/0.4985, allocations: 1.167 MB / 0.6963 GB, free: 5.66 MB / 0.5573 GB Notification: Performance of NFTyping.typeClassSections: time 0.001568/0.5, allocations: 0.6862 MB / 0.697 GB, free: 5.562 MB / 0.5573 GB Notification: Performance of NFFlatten.flatten: time 0.001822/0.5019, allocations: 1.964 MB / 0.6989 GB, free: 4.711 MB / 0.5573 GB Notification: Performance of NFFlatten.resolveConnections: time 0.0003541/0.5022, allocations: 145.2 kB / 0.6991 GB, free: 4.637 MB / 0.5573 GB Notification: Performance of NFEvalConstants.evaluate: time 0.001365/0.5036, allocations: 1.106 MB / 0.7001 GB, free: 4.211 MB / 0.5573 GB Notification: Performance of NFSimplifyModel.simplify: time 0.0005077/0.5041, allocations: 0.5048 MB / 0.7006 GB, free: 4.082 MB / 0.5573 GB Notification: Performance of NFPackage.collectConstants: time 8.464e-05/0.5042, allocations: 64.47 kB / 0.7007 GB, free: 4.082 MB / 0.5573 GB Notification: Performance of NFFlatten.collectFunctions: time 0.001977/0.5061, allocations: 1.105 MB / 0.7018 GB, free: 3.824 MB / 0.5573 GB Notification: Performance of combineBinaries: time 0.0007583/0.5069, allocations: 1.757 MB / 0.7035 GB, free: 2.758 MB / 0.5573 GB Notification: Performance of replaceArrayConstructors: time 0.0004205/0.5073, allocations: 1.192 MB / 0.7047 GB, free: 1.996 MB / 0.5573 GB Notification: Performance of NFVerifyModel.verify: time 0.0001664/0.5075, allocations: 90.59 kB / 0.7047 GB, free: 1.996 MB / 0.5573 GB Notification: Performance of FrontEnd: time 0.000381/0.5079, allocations: 277.9 kB / 0.705 GB, free: 1.906 MB / 0.5573 GB Notification: Model statistics after passing the front-end and creating the data structures used by the back-end: * Number of equations: 157 (148) * Number of variables: 157 (157) Notification: Performance of [SIM] Bindings: time 0.002705/0.5106, allocations: 4.353 MB / 0.7093 GB, free: 15.24 MB / 0.573 GB Notification: Performance of [SIM] FunctionAlias: time 0.0006936/0.5113, allocations: 0.7218 MB / 0.71 GB, free: 14.73 MB / 0.573 GB Notification: Performance of [SIM] Early Inline: time 0.002144/0.5134, allocations: 2.951 MB / 0.7128 GB, free: 12.6 MB / 0.573 GB Notification: Performance of [SIM] Simplify 1: time 0.0004026/0.5138, allocations: 357.5 kB / 0.7132 GB, free: 12.38 MB / 0.573 GB Notification: Performance of [SIM] Alias: time 0.003096/0.5169, allocations: 3.734 MB / 0.7168 GB, free: 9.625 MB / 0.573 GB Notification: Performance of [SIM] Simplify 2: time 0.0002374/0.5171, allocations: 274.1 kB / 0.7171 GB, free: 9.465 MB / 0.573 GB Notification: Performance of [SIM] Remove Stream: time 0.0001449/0.5173, allocations: 221.8 kB / 0.7173 GB, free: 9.285 MB / 0.573 GB Notification: Performance of [SIM] Detect States: time 0.000659/0.5179, allocations: 0.7545 MB / 0.718 GB, free: 8.648 MB / 0.573 GB Notification: Performance of [SIM] Events: time 0.0002128/0.5182, allocations: 179.6 kB / 0.7182 GB, free: 8.539 MB / 0.573 GB Notification: Performance of [SIM] Partitioning: time 0.001051/0.5192, allocations: 0.922 MB / 0.7191 GB, free: 7.992 MB / 0.573 GB Error: Internal error NBSorting.tarjan failed to sort system: System Variables (189/201) **************************** (1|1) [DSTA] (1) Real pRatio1.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.Medium.pressure(pRatio1.inlet.state) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (2|2) [DSTA] (1) final Real pRatio1.adiabaticModel.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.adiabaticModel.Medium.specificEnthalpy(pRatio1.adiabaticModel.state_in) (min = -1e10, max = 1e10, nominal = 1e6) (3|3) [DSTA] (1) output Real source.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (4|4) [DSTA] (1) input Real dp1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (5|5) [DSTA] (1) Real pRatio = (p_in + dp) / p_in (6|6) [ALGB] (1) Real pRatio1.singularityRegime (7|7) [DSTA] (1) Real pRatio1.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.Medium.specificEnthalpy(pRatio1.inlet.state) (min = -1e10, max = 1e10, nominal = 1e6) (8|8) [DSTA] (1) Real pOut1.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.Medium.specificEnthalpy(pOut1.inlet.state) (min = -1e10, max = 1e10, nominal = 1e6) (9|9) [ALGB] (1) output Real pRatio1.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (10|10) [DSTA] (1) Real pRatio1.p_out (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (11|11) [ALGB] (1) output Real dp1.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (12|12) [ALGB] (1) Real $FUN_11 (13|13) [ALGB] (1) Real $FUN_10 (14|14) [DDER] (1) Real $DER.pOut1.m_flow (StateSelect = avoid) (15|15) [DSTA] (1) final input Real pOut1.adiabaticModel.state_in.p = pOut1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (16|16) [DSTA] (1) Real dp = dp (min = max(-p_in, -p_in, -p_in), max = max(1e8 - p_in, 1e8 - p_in, 1e8 - p_in)) (17|17) [DSTA] (1) output Real source2.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (18|18) [DSTA] (1) final Real pRatio1.adiabaticModel.w_t_is (19|19) [DSTA] (1) output Real source1.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (20|20) [DSTA] (1) final Real pOut1.adiabaticModel.w_t_is (21|21) [ALGB] (1) Real pOut1.pRatio = (p_in + dp) / pOut1.p_in (22|22) [ALGB] (1) Real dp1.outlet.r (23|23) [ALGB] (1) Real pOut1.outlet.r (24|24) [DSTA] (1) final Real pRatio1.adiabaticModel.h_out_is = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.adiabaticModel.Medium.specificEnthalpy_psX(pRatio1.p_out, pRatio1.adiabaticModel.s_in, {}) (min = -1e10, max = 1e10, nominal = 1e6) (25|25) [ALGB] (1) Real pOut1.singularityRegime (26|26) [DSTA] (1) final Real dp1.adiabaticModel.w_t_is (27|27) [DSTA] (1) final Real pOut1.adiabaticModel.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.adiabaticModel.Medium.specificEnthalpy(pOut1.adiabaticModel.state_in) (min = -1e10, max = 1e10, nominal = 1e6) (28|28) [ALGB] (1) input Real sink2.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (29|29) [ALGB] (1) input Real sink1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (30|30) [DSTA] (1) Real pOut1.dh (31|31) [DSTA] (1) final input Real dp1.adiabaticModel.state_in.T = dp1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (32|32) [DSTA] (1) Real $FUN_9.T (33|33) [ALGB] (1) Real $FUN_8.T (34|34) [DSTA] (1) Real $FUN_5.T (35|35) [ALGB] (1) output Real pOut1.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (36|36) [ALGB] (1) Real $FUN_4.T (37|37) [DSTA] (1) final input Real pRatio1.adiabaticModel.state_in.p = pRatio1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (38|38) [DSTA] (1) Real dp1.dh (39|39) [DSTA] (1) input Real pRatio1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (40|40) [DSTA] (1) Real $FUN_1.T (41|41) [ALGB] (1) Real $FUN_7 (42|42) [ALGB] (1) Real $FUN_6 (43|43) [ALGB] (1) Real $FUN_3 (44|44) [ALGB] (1) Real $FUN_2 (45|45) [ALGB] (1) final Real pRatio1.adiabaticModel.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.adiabaticModel.Medium.pressure(pRatio1.adiabaticModel.state_in) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (46|46) [DISS] (1) protected Integer pressureDifference.count (47|47) [DSTA] (1) Real pRatio1.h_out (min = -1e10, max = 1e10, nominal = 1e6) (48|48) [DSTA] (1) final input Real dp1.adiabaticModel.state_in.p = dp1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (49|49) [ALGB] (1) Real sink.r (50|50) [DSTA] (1) final Real pRatio1.adiabaticModel.w_t (51|51) [DISS] (1) protected Integer power.count (52|52) [DSTA] (1) input Real pOut1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (53|53) [ALGB] (1) Real pOut1.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.Medium.pressure(pOut1.inlet.state) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (54|54) [DSTA] (1) final Real pRatio1.adiabaticModel.s_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pRatio1.adiabaticModel.Medium.specificEntropy(pRatio1.adiabaticModel.state_in) (min = -1e7, max = 1e7, nominal = 1000.0) (55|55) [ALGB] (1) input Real sink.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (56|56) [DISS] (1) protected Real power.T_start (57|57) [DSTA] (1) Real dp1.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.Medium.pressure(dp1.inlet.state) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (58|58) [DSTA] (1) Real dp1.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.Medium.specificEnthalpy(dp1.inlet.state) (min = -1e10, max = 1e10, nominal = 1e6) (59|59) [DSTA] (1) input Real pRatio1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (60|60) [ALGB] (1) Real $FUN_12.p (61|61) [DISC] (1) Boolean $SEV_12 (62|62) [ALGB] (1) Real sink2.r (63|63) [DISC] (1) Boolean $SEV_11 (64|64) [ALGB] (1) Real sink1.r (65|65) [DISC] (1) Boolean $SEV_10 (66|66) [ALGB] (1) Real pOut1.dp (67|67) [DSTA] (1) Real dp1.p_out (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (68|68) [DSTA] (1) final Real pOut1.adiabaticModel.w_t (69|69) [ALGB] (1) final Real pOut1.adiabaticModel.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.adiabaticModel.Medium.pressure(pOut1.adiabaticModel.state_in) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (70|70) [ALGB] (1) final Real dp1.adiabaticModel.p_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.adiabaticModel.Medium.pressure(dp1.adiabaticModel.state_in) (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (71|71) [ALGB] (1) Real pRatio1.dp (72|72) [DSTA] (1) final Real dp1.adiabaticModel.w_t (73|73) [DSTA] (1) final Real dp1.adiabaticModel.h_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.adiabaticModel.Medium.specificEnthalpy(dp1.adiabaticModel.state_in) (min = -1e10, max = 1e10, nominal = 1e6) (74|74) [DSTA] (1) Real $FUN_9.p (75|75) [DISC] (1) Boolean $SEV_9 (76|76) [DSTA] (1) input Real dp1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (77|77) [ALGB] (1) Real $FUN_8.p (78|78) [DISC] (1) Boolean $SEV_8 (79|79) [DISC] (1) Boolean $SEV_7 (80|80) [ALGB] (1) input Real sink2.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (81|81) [DSTA] (1) output Real source.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (82|82) [DISC] (1) Boolean $SEV_6 (83|83) [ALGB] (1) input Real sink1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (84|84) [DSTA] (1) Real $FUN_5.p (85|85) [DISC] (1) Boolean $SEV_5 (86|86) [ALGB] (1) input Real sink.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (87|87) [ALGB] (1) Real $FUN_4.p (88|88) [DISC] (1) Boolean $SEV_4 (89|89) [DSTA] (1) final Real dp1.adiabaticModel.s_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.adiabaticModel.Medium.specificEntropy(dp1.adiabaticModel.state_in) (min = -1e7, max = 1e7, nominal = 1000.0) (90|90) [DISC] (1) Boolean $SEV_3 (91|91) [DSTA] (1) final input Real pOut1.adiabaticModel.state_in.T = pOut1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (92|92) [DISC] (1) Boolean $SEV_2 (93|93) [DSTA] (1) Real $FUN_1.p (94|94) [DISC] (1) Boolean $SEV_1 (95|95) [DSTA] (1) final Real dp1.adiabaticModel.h_out_is = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.dp1.adiabaticModel.Medium.specificEnthalpy_psX(dp1.p_out, dp1.adiabaticModel.s_in, {}) (min = -1e10, max = 1e10, nominal = 1e6) (96|96) [DISC] (1) Boolean $SEV_0 (97|97) [ALGB] (1) output Real pRatio1.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (98|98) [DSTA] (1) final Real pOut1.adiabaticModel.h_out_is = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.adiabaticModel.Medium.specificEnthalpy_psX(p_in + dp, pOut1.adiabaticModel.s_in, {}) (min = -1e10, max = 1e10, nominal = 1e6) (99|99) [ALGB] (1) Real source1.outlet.r (100|100) [DSTA] (1) final input Real pRatio1.adiabaticModel.state_in.T = pRatio1.inlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (101|101) [ALGB] (1) Real source2.outlet.r (102|102) [ALGB] (1) output Real dp1.outlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (103|103) [DSTA] (1) output Real source2.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (104|104) [ALGB] (1) Real dp1.pRatio = dp1.p_out / dp1.p_in (105|105) [DSTA] (1) output Real source1.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (106|106) [DSTA] (1) final Real pOut1.adiabaticModel.s_in = ThermofluidStream.Idealized.Tests.Processes.Adiabatic.Warnings2.pOut1.adiabaticModel.Medium.specificEntropy(pOut1.adiabaticModel.state_in) (min = -1e7, max = 1e7, nominal = 1000.0) (107|107) [ALGB] (1) Real pRatio1.outlet.r (108|108) [DSTA] (1) Real dp1.h_out (min = -1e10, max = 1e10, nominal = 1e6) (109|109) [ALGB] (1) Real dp1.singularityRegime (110|110) [DSTA] (1) input Real pOut1.inlet.state.p (start = 1e5, min = 0.0, max = 1e8, nominal = 1e5) (111|111) [DSTA] (1) Real pOut1.h_out (min = -1e10, max = 1e10, nominal = 1e6) (112|112) [DSTA] (1) Real pRatio1.dh (113|113) [DDER] (1) Real $DER.dp1.m_flow (StateSelect = avoid) (114|114) [DISS] (1) protected Real pressureDifference.T_start (115|115) [DDER] (1) Real $DER.pRatio1.m_flow (StateSelect = avoid) (116|116) [DSTA] (1) Real dp1.P_in_internal (117|117) [ALGB] (1) output Real pOut1.outlet.state.T (start = 288.15, min = 273.15, max = 373.15, nominal = 300.0) (118|118) [ALGB] (1) Real source.outlet.r (119|119) [ALGB] (1) Real $FUN_12.T (120|120) [DDER] (1) final input Real $DER.pRatio1.adiabaticModel.state_in.p (StateSelect = avoid) (121|121) [DDER] (1) final input Real $DER.pRatio1.adiabaticModel.state_in.T (StateSelect = avoid) (122|122) [DDER] (1) final Real $DER.pRatio1.adiabaticModel.h_in (StateSelect = avoid) (123|123) [DDER] (1) Real $DER.$FUN_1.T (StateSelect = avoid) (124|124) [DDER] (1) Real $DER.pOut1.dh (StateSelect = avoid) (125|125) [DER-] (2) source1.Medium.ThermodynamicState $DER.$FUN_5 (126|127) [DER-] (2) source1.outlet.Medium.ThermodynamicState $DER.source1.outlet.state (127|129) [DDER] (1) final Real $DER.dp1.adiabaticModel.w_t (StateSelect = avoid) (128|130) [DDER] (1) Real $DER.$FUN_5.p (StateSelect = avoid) (129|131) [DDER] (1) final Real $DER.dp1.adiabaticModel.w_t_is (StateSelect = avoid) (130|132) [DDER] (1) Real $DER.$FUN_5.T (StateSelect = avoid) (131|133) [DER-] (2) source.Medium.ThermodynamicState $DER.$FUN_1 (132|135) [DER-] (2) source.outlet.Medium.ThermodynamicState $DER.source.outlet.state (133|137) [DDER] (1) Real $DER.$FUN_9.p (StateSelect = avoid) (134|138) [DDER] (1) Real $DER.$FUN_9.T (StateSelect = avoid) (135|139) [DDER] (1) final Real $DER.pRatio1.adiabaticModel.s_in (StateSelect = avoid) (136|140) [DDER] (1) final Real $DER.pRatio1.adiabaticModel.h_out_is (StateSelect = avoid) (137|141) [DDER] (1) Real $DER.pRatio1.p_out (StateSelect = avoid) (138|142) [DDER] (1) output Real $DER.source2.outlet.state.T (StateSelect = avoid) (139|143) [DDER] (1) input Real $DER.pOut1.inlet.state.T (StateSelect = avoid) (140|144) [DDER] (1) Real $DER.pOut1.h_in (StateSelect = avoid) (141|145) [DDER] (1) input Real $DER.pOut1.inlet.state.p (StateSelect = avoid) (142|146) [DDER] (1) output Real $DER.source2.outlet.state.p (StateSelect = avoid) (143|147) [DDER] (1) Real $DER.pRatio1.h_in (StateSelect = avoid) (144|148) [DDER] (1) Real $DER.pRatio1.h_out (StateSelect = avoid) (145|149) [DDER] (1) Real $DER.pRatio1.dh (StateSelect = avoid) (146|150) [DDER] (1) final input Real $DER.pOut1.adiabaticModel.state_in.p (StateSelect = avoid) (147|151) [DDER] (1) final input Real $DER.pOut1.adiabaticModel.state_in.T (StateSelect = avoid) (148|152) [DDER] (1) input Real $DER.pRatio1.inlet.state.T (StateSelect = avoid) (149|153) [DDER] (1) output Real $DER.source1.outlet.state.T (StateSelect = avoid) (150|154) [DDER] (1) final Real $DER.pOut1.adiabaticModel.s_in (StateSelect = avoid) (151|155) [DDER] (1) output Real $DER.source1.outlet.state.p (StateSelect = avoid) (152|156) [DDER] (1) Real $DER.pOut1.h_out (StateSelect = avoid) (153|157) [DDER] (1) final Real $DER.pOut1.adiabaticModel.w_t (StateSelect = avoid) (154|158) [DDER] (1) final Real $DER.pRatio1.adiabaticModel.w_t_is (StateSelect = avoid) (155|159) [DDER] (1) final Real $DER.pRatio1.adiabaticModel.w_t (StateSelect = avoid) (156|160) [DER-] (2) dp1.inlet.Medium.ThermodynamicState $DER.dp1.inlet.state (157|162) [DER-] (2) final dp1.adiabaticModel.Medium.ThermodynamicState $DER.dp1.adiabaticModel.state_in (158|164) [DDER] (1) final Real $DER.pOut1.adiabaticModel.h_in (StateSelect = avoid) (159|165) [DDER] (1) final Real $DER.pOut1.adiabaticModel.h_out_is (StateSelect = avoid) (160|166) [DDER] (1) final Real $DER.pOut1.adiabaticModel.w_t_is (StateSelect = avoid) (161|167) [DER-] (2) pRatio1.inlet.Medium.ThermodynamicState $DER.pRatio1.inlet.state (162|169) [DER-] (2) final pRatio1.adiabaticModel.Medium.ThermodynamicState $DER.pRatio1.adiabaticModel.state_in (163|171) [DER-] (2) pOut1.inlet.Medium.ThermodynamicState $DER.pOut1.inlet.state (164|173) [DER-] (2) final pOut1.adiabaticModel.Medium.ThermodynamicState $DER.pOut1.adiabaticModel.state_in (165|175) [DDER] (1) Real $DER.dp1.p_in (StateSelect = avoid) (166|176) [DER-] (2) source2.Medium.ThermodynamicState $DER.$FUN_9 (167|178) [DER-] (2) source2.outlet.Medium.ThermodynamicState $DER.source2.outlet.state (168|180) [DDER] (1) Real $DER.dp1.P_in_internal (StateSelect = avoid) (169|181) [DDER] (1) Real $DER.dp1.h_out (StateSelect = avoid) (170|182) [DDER] (1) Real $DER.dp1.dh (StateSelect = avoid) (171|183) [DDER] (1) Real $DER.$FUN_1.p (StateSelect = avoid) (172|184) [DDER] (1) Real $DER.dp (StateSelect = avoid) (173|185) [DDER] (1) Real $DER.pRatio (StateSelect = avoid) (174|186) [DDER] (1) Real $DER.dp1.h_in (StateSelect = avoid) (175|187) [DDER] (1) input Real $DER.dp1.inlet.state.T (StateSelect = avoid) (176|188) [DDER] (1) output Real $DER.source.outlet.state.T (StateSelect = avoid) (177|189) [DDER] (1) input Real $DER.dp1.inlet.state.p (StateSelect = avoid) (178|190) [DDER] (1) output Real $DER.source.outlet.state.p (StateSelect = avoid) (179|191) [DDER] (1) final input Real $DER.dp1.adiabaticModel.state_in.p (StateSelect = avoid) (180|192) [DDER] (1) final input Real $DER.dp1.adiabaticModel.state_in.T (StateSelect = avoid) (181|193) [DDER] (1) final Real $DER.dp1.adiabaticModel.h_in (StateSelect = avoid) (182|194) [DDER] (1) final Real $DER.dp1.adiabaticModel.s_in (StateSelect = avoid) (183|195) [DDER] (1) Real $DER.dp1.p_out (StateSelect = avoid) (184|196) [DDER] (1) final Real $DER.dp1.adiabaticModel.h_out_is (StateSelect = avoid) (185|197) [DDER] (1) input Real $DER.pRatio1.inlet.state.p (StateSelect = avoid) (186|198) [DDER] (1) Real $DER.pRatio1.p_in (StateSelect = avoid) (187|199) [DSTA] (1) Real pOut1.m_flow = pOut1.m_flow (StateSelect = default) (188|200) [DSTA] (1) Real dp1.m_flow = dp1.m_flow (StateSelect = default) (189|201) [DSTA] (1) Real pRatio1.m_flow = pRatio1.m_flow (StateSelect = default) System Equations (162/177) **************************** (1|1) [SCAL] (1) pRatio1.adiabaticModel.w_t = pRatio1.h_out - pRatio1.adiabaticModel.h_in ($RES_SIM_51) (2|2) [SCAL] (1) pOut1.m_flow = (pOut1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + pOut1.dh ^ 2.0) ($RES_SIM_16) (3|3) [SCAL] (1) $FUN_7 = abs(pRatio1.dh) ($RES_AUX_182) (4|4) [SCAL] (1) pOut1.pRatio = (p_in + dp) / pOut1.p_in ($RES_BND_147) (5|5) [SCAL] (1) pRatio1.adiabaticModel.w_t_is = pRatio1.adiabaticModel.h_out_is - pRatio1.adiabaticModel.h_in ($RES_SIM_52) (6|6) [SCAL] (1) $FUN_6 = abs(dp1.P_in_internal) ($RES_AUX_183) (7|7) [SCAL] (1) $DER.pRatio1.m_flow * sink1.L = pRatio1.outlet.r - sink1.r ($RES_SIM_53) (8|8) [SCAL] (1) pOut1.dh = pOut1.h_out - pOut1.h_in ($RES_SIM_18) (9|9) [RECD] (2) source1.outlet.state = $FUN_5 ($RES_SIM_54) (10|11) [SCAL] (1) source1.L * (-$DER.pRatio1.m_flow) = source1.outlet.r ($RES_SIM_55) (11|12) [SCAL] (1) $FUN_3 = abs(dp1.dh) ($RES_AUX_186) (12|13) [SCAL] (1) $FUN_2 = abs(dp1.P_in_internal) ($RES_AUX_187) (13|14) [RECD] (2) dp1.outlet.state = $FUN_4 ($RES_SIM_59) (14|16) [SCAL] (1) pOut1.outlet.state.T = sink2.inlet.state.T ($RES_SIM_97) (15|17) [SCAL] (1) pOut1.outlet.state.p = sink2.inlet.state.p ($RES_SIM_98) (16|18) [SCAL] (1) $SEV_3 = time >= ((CAST(Real, 1 + $PRE.pressureDifference.count)) * pressureDifference.period + pressureDifference.startTime) ($RES_EVT_210) (17|19) [SCAL] (1) $SEV_4 = (time < pressureDifference.startTime or pressureDifference.nperiod == 0) or pressureDifference.nperiod > 0 and pressureDifference.count >= pressureDifference.nperiod ($RES_EVT_211) (18|20) [SCAL] (1) $SEV_5 = time < (pressureDifference.T_start + pressureDifference.T_rising) ($RES_EVT_212) (19|21) [SCAL] (1) $SEV_6 = time < (pressureDifference.T_start + pressureDifference.T_width) ($RES_EVT_213) (20|22) [SCAL] (1) $SEV_7 = time < (pressureDifference.T_start + pressureDifference.T_falling) ($RES_EVT_214) (21|23) [SCAL] (1) $SEV_8 = time >= ((CAST(Real, 1 + $PRE.power.count)) * power.period + power.startTime) ($RES_EVT_215) (22|24) [SCAL] (1) $SEV_9 = (time < power.startTime or power.nperiod == 0) or power.nperiod > 0 and power.count >= power.nperiod ($RES_EVT_216) (23|25) [SCAL] (1) $SEV_10 = time < (power.T_start + power.T_rising) ($RES_EVT_217) (24|26) [SCAL] (1) $SEV_11 = time < (power.T_start + power.T_width) ($RES_EVT_218) (25|27) [SCAL] (1) $SEV_12 = time < (power.T_start + power.T_falling) ($RES_EVT_219) (26|28) [SCAL] (1) source2.outlet.state.T = pOut1.inlet.state.T ($RES_SIM_100) (27|29) [SCAL] (1) source2.outlet.state.p = pOut1.inlet.state.p ($RES_SIM_101) (28|30) [SCAL] (1) pRatio1.outlet.state.T = sink1.inlet.state.T ($RES_SIM_103) (29|31) [SCAL] (1) pRatio1.outlet.state.p = sink1.inlet.state.p ($RES_SIM_104) (30|32) [SCAL] (1) pOut1.adiabaticModel.w_t = if $SEV_2 then pOut1.adiabaticModel.w_t_is / pOut1.eta_fixed else pOut1.adiabaticModel.w_t_is * pOut1.eta_fixed ($RES_SIM_23) (31|33) [SCAL] (1) source1.outlet.state.T = pRatio1.inlet.state.T ($RES_SIM_106) (32|34) [SCAL] (1) source1.outlet.state.p = pRatio1.inlet.state.p ($RES_SIM_107) (33|35) [SCAL] (1) dp1.p_out = dp1.p_in + dp ($RES_SIM_61) (34|36) [SCAL] (1) pOut1.adiabaticModel.w_t = pOut1.h_out - pOut1.adiabaticModel.h_in ($RES_SIM_26) (35|37) [RECD] (2) dp1.adiabaticModel.state_in = dp1.inlet.state ($RES_BND_156) (36|39) [SCAL] (1) dp1.outlet.r = source.outlet.r - $DER.dp1.m_flow * dp1.L ($RES_SIM_62) (37|40) [SCAL] (1) pOut1.adiabaticModel.w_t_is = pOut1.adiabaticModel.h_out_is - pOut1.adiabaticModel.h_in ($RES_SIM_27) (38|41) [SCAL] (1) dp1.outlet.state.T = sink.inlet.state.T ($RES_SIM_109) (39|42) [RECD] (2) pRatio1.adiabaticModel.state_in = pRatio1.inlet.state ($RES_BND_157) (40|44) [SCAL] (1) $DER.pOut1.m_flow * sink2.L = pOut1.outlet.r - sink2.r ($RES_SIM_28) (41|45) [RECD] (2) pOut1.adiabaticModel.state_in = pOut1.inlet.state ($RES_BND_158) (42|47) [SCAL] (1) dp1.p_in = dp1.inlet.state.p ($RES_AUX_159) (43|48) [SCAL] (1) dp1.singularityRegime = if noEvent($FUN_2 > 2.220446049250313e-16 and $FUN_3 < 2.220446049250313e-16) then -1.0 else 0.0 ($RES_SIM_64) (44|49) [RECD] (2) source2.outlet.state = $FUN_9 ($RES_SIM_29) (45|51) [SCAL] (1) dp1.m_flow = (dp1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + dp1.dh ^ 2.0) ($RES_SIM_66) (46|52) [SCAL] (1) dp1.dh = dp1.h_out - dp1.h_in ($RES_SIM_68) (47|53) [SCAL] (1) $FUN_1.p = source.p0_par ($RES_SIM_189) (48|54) [SCAL] (1) pRatio = (p_in + dp) / p_in ($RES_BND_120) (49|55) [SCAL] (1) dp1.outlet.state.p = sink.inlet.state.p ($RES_SIM_110) (50|56) [SCAL] (1) dp1.h_in = 1005.45 * ((-298.15) + dp1.inlet.state.T) ($RES_AUX_160) (51|57) [SCAL] (1) source.outlet.state.T = dp1.inlet.state.T ($RES_SIM_112) (52|58) [SCAL] (1) dp1.pRatio = dp1.p_out / dp1.p_in ($RES_BND_125) (53|59) [SCAL] (1) source2.L * (-$DER.pOut1.m_flow) = source2.outlet.r ($RES_SIM_30) (54|60) [SCAL] (1) dp1.adiabaticModel.p_in = dp1.adiabaticModel.state_in.p ($RES_AUX_161) (55|61) [SCAL] (1) source.outlet.state.p = dp1.inlet.state.p ($RES_SIM_113) (56|62) [SCAL] (1) dp1.adiabaticModel.s_in = 1005.45 * log(0.0033540164346805303 * dp1.adiabaticModel.state_in.T) - 287.0509010514002 * log(9.869232667160129e-6 * dp1.adiabaticModel.state_in.p) ($RES_AUX_162) (57|63) [SCAL] (1) dp1.adiabaticModel.h_in = 1005.45 * ((-298.15) + dp1.adiabaticModel.state_in.T) ($RES_AUX_163) (58|64) [SCAL] (1) dp1.adiabaticModel.h_out_is = 1005.45 * ((-298.15) + 298.15 * exp(9.945795414988312e-4 * (dp1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * dp1.p_out)))) ($RES_AUX_164) (59|65) [RECD] (2) pRatio1.outlet.state = $FUN_8 ($RES_SIM_34) (60|67) [SCAL] (1) pRatio1.p_in = pRatio1.inlet.state.p ($RES_AUX_165) (61|68) [SCAL] (1) pRatio1.h_in = 1005.45 * ((-298.15) + pRatio1.inlet.state.T) ($RES_AUX_166) (62|69) [SCAL] (1) pRatio1.p_out = pRatio1.p_in + pRatio1.dp ($RES_SIM_36) (63|70) [SCAL] (1) pRatio1.adiabaticModel.p_in = pRatio1.adiabaticModel.state_in.p ($RES_AUX_167) (64|71) [SCAL] (1) pRatio1.outlet.r = source1.outlet.r - $DER.pRatio1.m_flow * pRatio1.L ($RES_SIM_37) (65|72) [SCAL] (1) pRatio1.adiabaticModel.s_in = 1005.45 * log(0.0033540164346805303 * pRatio1.adiabaticModel.state_in.T) - 287.0509010514002 * log(9.869232667160129e-6 * pRatio1.adiabaticModel.state_in.p) ($RES_AUX_168) (66|73) [SCAL] (1) dp1.adiabaticModel.w_t = if $SEV_0 then dp1.adiabaticModel.w_t_is / dp1.eta_fixed else dp1.adiabaticModel.w_t_is * dp1.eta_fixed ($RES_SIM_73) (67|74) [SCAL] (1) pRatio1.adiabaticModel.h_in = 1005.45 * ((-298.15) + pRatio1.adiabaticModel.state_in.T) ($RES_AUX_169) (68|75) [SCAL] (1) $FUN_1.T = source.T0_par ($RES_SIM_190) (69|76) [SCAL] (1) pRatio1.singularityRegime = if noEvent($FUN_6 > 2.220446049250313e-16 and $FUN_7 < 2.220446049250313e-16) then -1.0 else 0.0 ($RES_SIM_39) (70|77) [SCAL] (1) $FUN_4.p = dp1.p_out ($RES_SIM_191) (71|78) [SCAL] (1) $FUN_4.T = 298.15 + 9.945795414988312e-4 * dp1.h_out ($RES_SIM_192) (72|79) [SCAL] (1) dp1.adiabaticModel.w_t = dp1.h_out - dp1.adiabaticModel.h_in ($RES_SIM_76) (73|80) [SCAL] (1) $FUN_5.p = source1.p0_par ($RES_SIM_193) (74|81) [SCAL] (1) dp1.adiabaticModel.w_t_is = dp1.adiabaticModel.h_out_is - dp1.adiabaticModel.h_in ($RES_SIM_77) (75|82) [SCAL] (1) $FUN_5.T = source1.T0_par ($RES_SIM_194) (76|83) [SCAL] (1) $DER.dp1.m_flow * sink.L = dp1.outlet.r - sink.r ($RES_SIM_78) (77|84) [SCAL] (1) $FUN_8.p = pRatio1.p_out ($RES_SIM_195) (78|85) [RECD] (2) source.outlet.state = $FUN_1 ($RES_SIM_79) (79|87) [SCAL] (1) $FUN_8.T = 298.15 + 9.945795414988312e-4 * pRatio1.h_out ($RES_SIM_196) (80|88) [SCAL] (1) $FUN_9.p = source2.p0_par ($RES_SIM_197) (81|89) [SCAL] (1) $FUN_9.T = source2.T0_par ($RES_SIM_198) (82|90) [SCAL] (1) $FUN_12.p = p_in + dp ($RES_SIM_199) (83|91) [SCAL] (1) pRatio1.adiabaticModel.h_out_is = 1005.45 * ((-298.15) + 298.15 * exp(9.945795414988312e-4 * (pRatio1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * pRatio1.p_out)))) ($RES_AUX_170) (84|92) [SCAL] (1) pOut1.p_in = pOut1.inlet.state.p ($RES_AUX_171) (85|93) [SCAL] (1) pRatio1.m_flow = (pRatio1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + pRatio1.dh ^ 2.0) ($RES_SIM_41) (86|94) [SCAL] (1) pRatio = pRatio1.p_out / pRatio1.p_in ($RES_BND_136) (87|95) [SCAL] (1) pOut1.h_in = 1005.45 * ((-298.15) + pOut1.inlet.state.T) ($RES_AUX_172) (88|96) [SCAL] (1) pOut1.adiabaticModel.p_in = pOut1.adiabaticModel.state_in.p ($RES_AUX_173) (89|97) [SCAL] (1) pRatio1.dh = pRatio1.h_out - pRatio1.h_in ($RES_SIM_43) (90|98) [SCAL] (1) pOut1.adiabaticModel.s_in = 1005.45 * log(0.0033540164346805303 * pOut1.adiabaticModel.state_in.T) - 287.0509010514002 * log(9.869232667160129e-6 * pOut1.adiabaticModel.state_in.p) ($RES_AUX_174) (91|99) [SCAL] (1) pOut1.adiabaticModel.h_in = 1005.45 * ((-298.15) + pOut1.adiabaticModel.state_in.T) ($RES_AUX_175) (92|100) [SCAL] (1) source.L * (-$DER.dp1.m_flow) = source.outlet.r ($RES_SIM_80) (93|101) [SCAL] (1) pOut1.adiabaticModel.h_out_is = 1005.45 * ((-298.15) + 298.15 * exp(9.945795414988312e-4 * (pOut1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * (p_in + dp))))) ($RES_AUX_176) (94|102) [SCAL] (1) $FUN_12.T = 298.15 + 9.945795414988312e-4 * pOut1.h_out ($RES_SIM_200) (95|103) [SCAL] (1) $FUN_11 = abs(pOut1.dh) ($RES_AUX_178) (96|104) [SCAL] (1) pRatio1.adiabaticModel.w_t = if $SEV_1 then pRatio1.adiabaticModel.w_t_is / pRatio1.eta_fixed else pRatio1.adiabaticModel.w_t_is * pRatio1.eta_fixed ($RES_SIM_48) (97|105) [SCAL] (1) $FUN_10 = abs(dp1.P_in_internal) ($RES_AUX_179) (98|106) [RECD] (2) pOut1.outlet.state = $FUN_12 ($RES_SIM_9) (99|108) [WHEN] (1) ($RES_SIM_7) (99|108) [----] when $SEV_3 then (99|108) [----] pressureDifference.count := 1 + $PRE.pressureDifference.count (99|108) [----] end when; (100|109) [WHEN] (1) ($RES_SIM_6) (100|109) [----] when $SEV_3 then (100|109) [----] pressureDifference.T_start := time (100|109) [----] end when; (101|110) [SCAL] (1) $SEV_0 = dp1.p_out >= dp1.adiabaticModel.p_in ($RES_EVT_207) (102|111) [SCAL] (1) dp = pressureDifference.offset + (if $SEV_4 then 0.0 else if $SEV_5 then ((time - pressureDifference.T_start) * pressureDifference.amplitude) / pressureDifference.rising else if $SEV_6 then pressureDifference.amplitude else if $SEV_7 then (((pressureDifference.T_falling + pressureDifference.T_start) - time) * pressureDifference.amplitude) / pressureDifference.falling else 0.0) ($RES_SIM_5) (103|112) [SCAL] (1) $SEV_1 = pRatio1.p_out >= pRatio1.adiabaticModel.p_in ($RES_EVT_208) (104|113) [WHEN] (1) ($RES_SIM_4) (104|113) [----] when $SEV_8 then (104|113) [----] power.count := 1 + $PRE.power.count (104|113) [----] end when; (105|114) [SCAL] (1) $SEV_2 = p_in + dp >= pOut1.adiabaticModel.p_in ($RES_EVT_209) (106|115) [WHEN] (1) ($RES_SIM_3) (106|115) [----] when $SEV_8 then (106|115) [----] power.T_start := time (106|115) [----] end when; (107|116) [SCAL] (1) dp1.P_in_internal = power.offset + (if $SEV_9 then 0.0 else if $SEV_10 then ((time - power.T_start) * power.amplitude) / power.rising else if $SEV_11 then power.amplitude else if $SEV_12 then (((power.T_falling + power.T_start) - time) * power.amplitude) / power.falling else 0.0) ($RES_SIM_2) (108|117) [SCAL] (1) p_in + dp = pOut1.p_in + pOut1.dp ($RES_SIM_11) (109|118) [SCAL] (1) pOut1.outlet.r = source2.outlet.r - $DER.pOut1.m_flow * pOut1.L ($RES_SIM_12) (110|119) [SCAL] (1) pOut1.singularityRegime = if noEvent($FUN_10 > 2.220446049250313e-16 and $FUN_11 < 2.220446049250313e-16) then -1.0 else 0.0 ($RES_SIM_14) (111|120) [SCAL] (1) $DER.pRatio1.h_in = 1005.45 * $DER.pRatio1.inlet.state.T ($RES_SIM_220) (112|121) [SCAL] (1) $DER.pRatio1.adiabaticModel.w_t = $DER.pRatio1.h_out - $DER.pRatio1.adiabaticModel.h_in ($RES_SIM_221) (113|122) [SCAL] (1) $DER.pOut1.m_flow = (($DER.pOut1.dh * dp1.P_in_internal + pOut1.dh * $DER.dp1.P_in_internal) * (4.930380657631324e-32 + pOut1.dh ^ 2.0) - (2.0 * pOut1.dh * $DER.pOut1.dh) * pOut1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + pOut1.dh ^ 2.0) ^ 2.0 ($RES_SIM_222) (114|123) [SCAL] (1) $DER.pRatio1.adiabaticModel.s_in = 1005.45 * ((1/(0.0033540164346805303 * pRatio1.adiabaticModel.state_in.T)) * (0.0033540164346805303 * $DER.pRatio1.adiabaticModel.state_in.T)) - 287.0509010514002 * ((1/(9.869232667160129e-6 * pRatio1.adiabaticModel.state_in.p)) * (9.869232667160129e-6 * $DER.pRatio1.adiabaticModel.state_in.p)) ($RES_SIM_223) (115|124) [SCAL] (1) $DER.pRatio1.adiabaticModel.w_t_is = $DER.pRatio1.adiabaticModel.h_out_is - $DER.pRatio1.adiabaticModel.h_in ($RES_SIM_224) (116|125) [SCAL] (1) $DER.dp1.adiabaticModel.w_t = if $SEV_0 then ($DER.dp1.adiabaticModel.w_t_is * dp1.eta_fixed) / dp1.eta_fixed ^ 2.0 else $DER.dp1.adiabaticModel.w_t_is * dp1.eta_fixed ($RES_SIM_225) (117|126) [SCAL] (1) $DER.pRatio1.adiabaticModel.h_in = 1005.45 * $DER.pRatio1.adiabaticModel.state_in.T ($RES_SIM_226) (118|127) [SCAL] (1) $DER.$FUN_1.T = 0.0 ($RES_SIM_227) (119|128) [SCAL] (1) $DER.pOut1.dh = $DER.pOut1.h_out - $DER.pOut1.h_in ($RES_SIM_228) (120|129) [RECD] (2) $DER.source1.outlet.state = $DER.$FUN_5 ($RES_SIM_229) (121|131) [SCAL] (1) $DER.dp1.adiabaticModel.w_t = $DER.dp1.h_out - $DER.dp1.adiabaticModel.h_in ($RES_SIM_230) (122|132) [SCAL] (1) $DER.$FUN_5.p = 0.0 ($RES_SIM_231) (123|133) [SCAL] (1) $DER.dp1.adiabaticModel.w_t_is = $DER.dp1.adiabaticModel.h_out_is - $DER.dp1.adiabaticModel.h_in ($RES_SIM_232) (124|134) [SCAL] (1) $DER.$FUN_5.T = 0.0 ($RES_SIM_233) (125|135) [RECD] (2) $DER.source.outlet.state = $DER.$FUN_1 ($RES_SIM_234) (126|137) [SCAL] (1) $DER.$FUN_9.p = 0.0 ($RES_SIM_235) (127|138) [SCAL] (1) $DER.$FUN_9.T = 0.0 ($RES_SIM_236) (128|139) [SCAL] (1) $DER.pRatio1.adiabaticModel.h_out_is = 1005.45 * (298.15 * (exp(9.945795414988312e-4 * (pRatio1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * pRatio1.p_out))) * (9.945795414988312e-4 * ($DER.pRatio1.adiabaticModel.s_in + 287.0509010514002 * ((1/(9.869232667160129e-6 * pRatio1.p_out)) * (9.869232667160129e-6 * $DER.pRatio1.p_out)))))) ($RES_SIM_237) (129|140) [SCAL] (1) $DER.pRatio1.m_flow = (($DER.pRatio1.dh * dp1.P_in_internal + pRatio1.dh * $DER.dp1.P_in_internal) * (4.930380657631324e-32 + pRatio1.dh ^ 2.0) - (2.0 * pRatio1.dh * $DER.pRatio1.dh) * pRatio1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + pRatio1.dh ^ 2.0) ^ 2.0 ($RES_SIM_238) (130|141) [SCAL] (1) $DER.pRatio = ($DER.pRatio1.p_out * pRatio1.p_in - pRatio1.p_out * $DER.pRatio1.p_in) / pRatio1.p_in ^ 2.0 ($RES_SIM_239) (131|142) [SCAL] (1) $DER.source2.outlet.state.T = $DER.pOut1.inlet.state.T ($RES_SIM_240) (132|143) [SCAL] (1) $DER.pOut1.h_in = 1005.45 * $DER.pOut1.inlet.state.T ($RES_SIM_241) (133|144) [SCAL] (1) $DER.source2.outlet.state.p = $DER.pOut1.inlet.state.p ($RES_SIM_242) (134|145) [SCAL] (1) $DER.pRatio1.dh = $DER.pRatio1.h_out - $DER.pRatio1.h_in ($RES_SIM_243) (135|146) [SCAL] (1) $DER.pOut1.adiabaticModel.s_in = 1005.45 * ((1/(0.0033540164346805303 * pOut1.adiabaticModel.state_in.T)) * (0.0033540164346805303 * $DER.pOut1.adiabaticModel.state_in.T)) - 287.0509010514002 * ((1/(9.869232667160129e-6 * pOut1.adiabaticModel.state_in.p)) * (9.869232667160129e-6 * $DER.pOut1.adiabaticModel.state_in.p)) ($RES_SIM_244) (136|147) [SCAL] (1) $DER.pOut1.adiabaticModel.h_in = 1005.45 * $DER.pOut1.adiabaticModel.state_in.T ($RES_SIM_245) (137|148) [SCAL] (1) $DER.pOut1.adiabaticModel.w_t = if $SEV_2 then ($DER.pOut1.adiabaticModel.w_t_is * pOut1.eta_fixed) / pOut1.eta_fixed ^ 2.0 else $DER.pOut1.adiabaticModel.w_t_is * pOut1.eta_fixed ($RES_SIM_246) (138|149) [SCAL] (1) $DER.source1.outlet.state.T = $DER.pRatio1.inlet.state.T ($RES_SIM_247) (139|150) [SCAL] (1) $DER.pOut1.adiabaticModel.h_out_is = 1005.45 * (298.15 * (exp(9.945795414988312e-4 * (pOut1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * (p_in + dp)))) * (9.945795414988312e-4 * ($DER.pOut1.adiabaticModel.s_in + 287.0509010514002 * ((1/(9.869232667160129e-6 * (p_in + dp))) * (9.869232667160129e-6 * $DER.dp)))))) ($RES_SIM_248) (140|151) [SCAL] (1) $DER.source1.outlet.state.p = $DER.pRatio1.inlet.state.p ($RES_SIM_249) (141|152) [SCAL] (1) $DER.dp1.p_out = $DER.dp1.p_in + $DER.dp ($RES_SIM_250) (142|153) [SCAL] (1) $DER.pOut1.adiabaticModel.w_t = $DER.pOut1.h_out - $DER.pOut1.adiabaticModel.h_in ($RES_SIM_251) (143|154) [SCAL] (1) $DER.pRatio1.adiabaticModel.w_t = if $SEV_1 then ($DER.pRatio1.adiabaticModel.w_t_is * pRatio1.eta_fixed) / pRatio1.eta_fixed ^ 2.0 else $DER.pRatio1.adiabaticModel.w_t_is * pRatio1.eta_fixed ($RES_SIM_252) (144|155) [RECD] (2) $DER.dp1.adiabaticModel.state_in = $DER.dp1.inlet.state ($RES_SIM_253) (145|157) [SCAL] (1) $DER.pOut1.adiabaticModel.w_t_is = $DER.pOut1.adiabaticModel.h_out_is - $DER.pOut1.adiabaticModel.h_in ($RES_SIM_254) (146|158) [RECD] (2) $DER.pRatio1.adiabaticModel.state_in = $DER.pRatio1.inlet.state ($RES_SIM_255) (147|160) [SCAL] (1) $DER.dp = if $SEV_4 then 0.0 else if $SEV_5 then (pressureDifference.amplitude * pressureDifference.rising) / pressureDifference.rising ^ 2.0 else if $SEV_6 then 0.0 else if $SEV_7 then -(pressureDifference.amplitude * pressureDifference.falling) / pressureDifference.falling ^ 2.0 else 0.0 ($RES_SIM_256) (148|161) [RECD] (2) $DER.pOut1.adiabaticModel.state_in = $DER.pOut1.inlet.state ($RES_SIM_257) (149|163) [SCAL] (1) $DER.dp1.p_in = $DER.dp1.inlet.state.p ($RES_SIM_258) (150|164) [RECD] (2) $DER.source2.outlet.state = $DER.$FUN_9 ($RES_SIM_259) (151|166) [SCAL] (1) $DER.dp1.m_flow = (($DER.dp1.dh * dp1.P_in_internal + dp1.dh * $DER.dp1.P_in_internal) * (4.930380657631324e-32 + dp1.dh ^ 2.0) - (2.0 * dp1.dh * $DER.dp1.dh) * dp1.dh * dp1.P_in_internal) / (4.930380657631324e-32 + dp1.dh ^ 2.0) ^ 2.0 ($RES_SIM_260) (152|167) [SCAL] (1) $DER.dp1.P_in_internal = if $SEV_9 then 0.0 else if $SEV_10 then (power.amplitude * power.rising) / power.rising ^ 2.0 else if $SEV_11 then 0.0 else if $SEV_12 then -(power.amplitude * power.falling) / power.falling ^ 2.0 else 0.0 ($RES_SIM_261) (153|168) [SCAL] (1) $DER.dp1.dh = $DER.dp1.h_out - $DER.dp1.h_in ($RES_SIM_262) (154|169) [SCAL] (1) $DER.$FUN_1.p = 0.0 ($RES_SIM_263) (155|170) [SCAL] (1) $DER.pRatio = ($DER.dp * p_in) / p_in ^ 2.0 ($RES_SIM_264) (156|171) [SCAL] (1) $DER.dp1.h_in = 1005.45 * $DER.dp1.inlet.state.T ($RES_SIM_265) (157|172) [SCAL] (1) $DER.source.outlet.state.T = $DER.dp1.inlet.state.T ($RES_SIM_266) (158|173) [SCAL] (1) $DER.source.outlet.state.p = $DER.dp1.inlet.state.p ($RES_SIM_267) (159|174) [SCAL] (1) $DER.dp1.adiabaticModel.s_in = 1005.45 * ((1/(0.0033540164346805303 * dp1.adiabaticModel.state_in.T)) * (0.0033540164346805303 * $DER.dp1.adiabaticModel.state_in.T)) - 287.0509010514002 * ((1/(9.869232667160129e-6 * dp1.adiabaticModel.state_in.p)) * (9.869232667160129e-6 * $DER.dp1.adiabaticModel.state_in.p)) ($RES_SIM_268) (160|175) [SCAL] (1) $DER.dp1.adiabaticModel.h_in = 1005.45 * $DER.dp1.adiabaticModel.state_in.T ($RES_SIM_269) (161|176) [SCAL] (1) $DER.dp1.adiabaticModel.h_out_is = 1005.45 * (298.15 * (exp(9.945795414988312e-4 * (dp1.adiabaticModel.s_in + 287.0509010514002 * log(9.869232667160129e-6 * dp1.p_out))) * (9.945795414988312e-4 * ($DER.dp1.adiabaticModel.s_in + 287.0509010514002 * ((1/(9.869232667160129e-6 * dp1.p_out)) * (9.869232667160129e-6 * $DER.dp1.p_out)))))) ($RES_SIM_270) (162|177) [SCAL] (1) $DER.pRatio1.p_in = $DER.pRatio1.inlet.state.p ($RES_SIM_271) =================== Scalar Matching =================== variable to equation ********************** var 1 --> eqn 94 var 2 --> eqn 74 var 3 --> eqn 61 var 4 --> eqn 56 var 5 --> eqn 54 var 6 --> eqn 76 var 7 --> eqn 68 var 8 --> eqn 95 var 9 --> eqn 31 var 10 --> eqn 84 var 11 --> eqn 15 var 12 --> eqn 103 var 13 --> eqn 105 var 14 --> eqn 118 var 15 --> eqn 146 var 16 --> eqn 111 var 17 --> eqn -1 var 18 --> eqn 104 var 19 --> eqn 34 var 20 --> eqn 40 var 21 --> eqn 4 var 22 --> eqn 83 var 23 --> eqn 44 var 24 --> eqn 5 var 25 --> eqn 119 var 26 --> eqn 73 var 27 --> eqn 36 var 28 --> eqn 17 var 29 --> eqn -1 var 30 --> eqn 122 var 31 --> eqn 63 var 32 --> eqn 89 var 33 --> eqn 66 var 34 --> eqn 82 var 35 --> eqn 106 var 36 --> eqn 78 var 37 --> eqn 70 var 38 --> eqn 12 var 39 --> eqn -1 var 40 --> eqn 75 var 41 --> eqn 3 var 42 --> eqn 6 var 43 --> eqn -1 var 44 --> eqn 13 var 45 --> eqn -1 var 46 --> eqn 108 var 47 --> eqn 87 var 48 --> eqn 62 var 49 --> eqn -1 var 50 --> eqn 1 var 51 --> eqn 113 var 52 --> eqn 28 var 53 --> eqn 92 var 54 --> eqn 91 var 55 --> eqn 55 var 56 --> eqn 115 var 57 --> eqn -1 var 58 --> eqn -1 var 59 --> eqn 67 var 60 --> eqn 90 var 61 --> eqn 27 var 62 --> eqn -1 var 63 --> eqn 26 var 64 --> eqn 7 var 65 --> eqn 25 var 66 --> eqn 117 var 67 --> eqn 35 var 68 --> eqn 32 var 69 --> eqn 96 var 70 --> eqn 60 var 71 --> eqn 69 var 72 --> eqn 79 var 73 --> eqn 81 var 74 --> eqn 88 var 75 --> eqn 24 var 76 --> eqn 47 var 77 --> eqn 65 var 78 --> eqn 23 var 79 --> eqn 22 var 80 --> eqn 16 var 81 --> eqn 57 var 82 --> eqn 21 var 83 --> eqn -1 var 84 --> eqn 80 var 85 --> eqn 20 var 86 --> eqn 41 var 87 --> eqn 77 var 88 --> eqn 19 var 89 --> eqn 176 var 90 --> eqn 18 var 91 --> eqn 99 var 92 --> eqn 114 var 93 --> eqn 53 var 94 --> eqn 112 var 95 --> eqn 64 var 96 --> eqn 110 var 97 --> eqn 30 var 98 --> eqn 101 var 99 --> eqn 11 var 100 --> eqn 72 var 101 --> eqn 59 var 102 --> eqn 14 var 103 --> eqn -1 var 104 --> eqn 58 var 105 --> eqn 33 var 106 --> eqn 98 var 107 --> eqn -1 var 108 --> eqn 52 var 109 --> eqn 48 var 110 --> eqn 29 var 111 --> eqn 8 var 112 --> eqn 97 var 113 --> eqn 100 var 114 --> eqn 109 var 115 --> eqn 71 var 116 --> eqn 116 var 117 --> eqn 107 var 118 --> eqn 39 var 119 --> eqn 102 var 120 --> eqn 123 var 121 --> eqn -1 var 122 --> eqn 126 var 123 --> eqn 127 var 124 --> eqn -1 var 125 --> eqn 129 var 126 --> eqn 130 var 127 --> eqn -1 var 128 --> eqn -1 var 129 --> eqn -1 var 130 --> eqn 132 var 131 --> eqn 125 var 132 --> eqn 134 var 133 --> eqn 135 var 134 --> eqn 136 var 135 --> eqn -1 var 136 --> eqn -1 var 137 --> eqn 137 var 138 --> eqn 138 var 139 --> eqn 139 var 140 --> eqn 124 var 141 --> eqn 141 var 142 --> eqn 142 var 143 --> eqn 143 var 144 --> eqn 128 var 145 --> eqn -1 var 146 --> eqn 144 var 147 --> eqn 145 var 148 --> eqn 121 var 149 --> eqn 140 var 150 --> eqn -1 var 151 --> eqn 147 var 152 --> eqn 120 var 153 --> eqn 149 var 154 --> eqn 150 var 155 --> eqn -1 var 156 --> eqn 153 var 157 --> eqn -1 var 158 --> eqn -1 var 159 --> eqn 154 var 160 --> eqn -1 var 161 --> eqn -1 var 162 --> eqn 155 var 163 --> eqn 156 var 164 --> eqn -1 var 165 --> eqn 157 var 166 --> eqn 148 var 167 --> eqn 158 var 168 --> eqn 159 var 169 --> eqn -1 var 170 --> eqn -1 var 171 --> eqn -1 var 172 --> eqn -1 var 173 --> eqn 161 var 174 --> eqn 162 var 175 --> eqn 152 var 176 --> eqn 164 var 177 --> eqn 165 var 178 --> eqn -1 var 179 --> eqn -1 var 180 --> eqn 167 var 181 --> eqn 131 var 182 --> eqn 166 var 183 --> eqn 169 var 184 --> eqn 160 var 185 --> eqn 170 var 186 --> eqn 168 var 187 --> eqn 171 var 188 --> eqn 172 var 189 --> eqn 163 var 190 --> eqn 173 var 191 --> eqn -1 var 192 --> eqn 175 var 193 --> eqn -1 var 194 --> eqn 174 var 195 --> eqn -1 var 196 --> eqn 133 var 197 --> eqn 151 var 198 --> eqn 177 var 199 --> eqn 2 var 200 --> eqn 51 var 201 --> eqn 93 equation to variable ********************** eqn 1 --> var 50 eqn 2 --> var 199 eqn 3 --> var 41 eqn 4 --> var 21 eqn 5 --> var 24 eqn 6 --> var 42 eqn 7 --> var 64 eqn 8 --> var 111 eqn 9 --> var -1 eqn 10 --> var -1 eqn 11 --> var 99 eqn 12 --> var 38 eqn 13 --> var 44 eqn 14 --> var 102 eqn 15 --> var 11 eqn 16 --> var 80 eqn 17 --> var 28 eqn 18 --> var 90 eqn 19 --> var 88 eqn 20 --> var 85 eqn 21 --> var 82 eqn 22 --> var 79 eqn 23 --> var 78 eqn 24 --> var 75 eqn 25 --> var 65 eqn 26 --> var 63 eqn 27 --> var 61 eqn 28 --> var 52 eqn 29 --> var 110 eqn 30 --> var 97 eqn 31 --> var 9 eqn 32 --> var 68 eqn 33 --> var 105 eqn 34 --> var 19 eqn 35 --> var 67 eqn 36 --> var 27 eqn 37 --> var -1 eqn 38 --> var -1 eqn 39 --> var 118 eqn 40 --> var 20 eqn 41 --> var 86 eqn 42 --> var -1 eqn 43 --> var -1 eqn 44 --> var 23 eqn 45 --> var -1 eqn 46 --> var -1 eqn 47 --> var 76 eqn 48 --> var 109 eqn 49 --> var -1 eqn 50 --> var -1 eqn 51 --> var 200 eqn 52 --> var 108 eqn 53 --> var 93 eqn 54 --> var 5 eqn 55 --> var 55 eqn 56 --> var 4 eqn 57 --> var 81 eqn 58 --> var 104 eqn 59 --> var 101 eqn 60 --> var 70 eqn 61 --> var 3 eqn 62 --> var 48 eqn 63 --> var 31 eqn 64 --> var 95 eqn 65 --> var 77 eqn 66 --> var 33 eqn 67 --> var 59 eqn 68 --> var 7 eqn 69 --> var 71 eqn 70 --> var 37 eqn 71 --> var 115 eqn 72 --> var 100 eqn 73 --> var 26 eqn 74 --> var 2 eqn 75 --> var 40 eqn 76 --> var 6 eqn 77 --> var 87 eqn 78 --> var 36 eqn 79 --> var 72 eqn 80 --> var 84 eqn 81 --> var 73 eqn 82 --> var 34 eqn 83 --> var 22 eqn 84 --> var 10 eqn 85 --> var -1 eqn 86 --> var -1 eqn 87 --> var 47 eqn 88 --> var 74 eqn 89 --> var 32 eqn 90 --> var 60 eqn 91 --> var 54 eqn 92 --> var 53 eqn 93 --> var 201 eqn 94 --> var 1 eqn 95 --> var 8 eqn 96 --> var 69 eqn 97 --> var 112 eqn 98 --> var 106 eqn 99 --> var 91 eqn 100 --> var 113 eqn 101 --> var 98 eqn 102 --> var 119 eqn 103 --> var 12 eqn 104 --> var 18 eqn 105 --> var 13 eqn 106 --> var 35 eqn 107 --> var 117 eqn 108 --> var 46 eqn 109 --> var 114 eqn 110 --> var 96 eqn 111 --> var 16 eqn 112 --> var 94 eqn 113 --> var 51 eqn 114 --> var 92 eqn 115 --> var 56 eqn 116 --> var 116 eqn 117 --> var 66 eqn 118 --> var 14 eqn 119 --> var 25 eqn 120 --> var 152 eqn 121 --> var 148 eqn 122 --> var 30 eqn 123 --> var 120 eqn 124 --> var 140 eqn 125 --> var 131 eqn 126 --> var 122 eqn 127 --> var 123 eqn 128 --> var 144 eqn 129 --> var 125 eqn 130 --> var 126 eqn 131 --> var 181 eqn 132 --> var 130 eqn 133 --> var 196 eqn 134 --> var 132 eqn 135 --> var 133 eqn 136 --> var 134 eqn 137 --> var 137 eqn 138 --> var 138 eqn 139 --> var 139 eqn 140 --> var 149 eqn 141 --> var 141 eqn 142 --> var 142 eqn 143 --> var 143 eqn 144 --> var 146 eqn 145 --> var 147 eqn 146 --> var 15 eqn 147 --> var 151 eqn 148 --> var 166 eqn 149 --> var 153 eqn 150 --> var 154 eqn 151 --> var 197 eqn 152 --> var 175 eqn 153 --> var 156 eqn 154 --> var 159 eqn 155 --> var 162 eqn 156 --> var 163 eqn 157 --> var 165 eqn 158 --> var 167 eqn 159 --> var 168 eqn 160 --> var 184 eqn 161 --> var 173 eqn 162 --> var 174 eqn 163 --> var 189 eqn 164 --> var 176 eqn 165 --> var 177 eqn 166 --> var 182 eqn 167 --> var 180 eqn 168 --> var 186 eqn 169 --> var 183 eqn 170 --> var 185 eqn 171 --> var 187 eqn 172 --> var 188 eqn 173 --> var 190 eqn 174 --> var 194 eqn 175 --> var 192 eqn 176 --> var 89 eqn 177 --> var 198 " [Timeout remaining time 659] [Calling sys.exit(0), Time elapsed: 3.056469456292689] Failed to read output from testmodel.py, exit status != 0: 0.5367704201489687 0.545294999 0.035447811 Calling exit ...