startTime=0 stopTime=1800 tolerance=1e-06 numberOfIntervals=2500 stepSize=0.72 Regular simulation: ./Physiolibrary_Physiolibrary.Fluid.Examples.MeanRespiration -abortSlowSimulation -alarm=480 -lv LOG_STATS assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) stdout | warning | Non-Linear Solver try to handle a problem with a called assert. assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) stdout | warning | While solving non-linear system an assertion failed during initialization. | | | | | The non-linear solver tries to solve the problem that could take some time. | | | | | It could help to provide better start-values for the iteration variables. | | | | | For more information simulate with -lv LOG_NLS_V assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) assert | debug | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 100000.0, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) LOG_SUCCESS | info | The initialization finished successfully without homotopy method. LOG_STATS | info | ### STATISTICS ### | | | | | timer | | | | | | 0.00191518s reading init.xml | | | | | | 0.000254928s reading info.xml | | | | | | 6.6074e-05s [ 0.0%] pre-initialization | | | | | | 0.0935876s [ 33.1%] initialization | | | | | | 3.0056e-05s [ 0.0%] steps | | | | | | 6.3695e-05s [ 0.0%] solver (excl. callbacks) | | | | | | 0s [ 0.0%] creating output-file | | | | | | 4.4301e-05s [ 0.0%] event-handling | | | | | | 0.00845943s [ 3.0%] overhead | | | | | | 0.180384s [ 63.8%] simulation | | | | | | 0.282635s [100.0%] total | | | | | events | | | | | | 0 state events | | | | | | 0 time events | | | | | solver: euler | | | | | | 5000 steps taken | | | | | | 5000 calls of functionODE | | | | | | 0 evaluations of jacobian | | | | | | 0 error test failures | | | | | | 0 convergence test failures | | | | | | 0s time of jacobian evaluation LOG_SUCCESS | info | The simulation finished successfully.