Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.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 0.000763/0.000763, allocations: 77.12 kB / 20.69 MB, free: 3.871 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 0.0007556/0.0007556, allocations: 173.2 kB / 23.97 MB, free: 0.5898 MB / 18.57 MB
"
[Timeout remaining time 180]
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo): time 0.7753/0.7753, allocations: 158.6 MB / 185.7 MB, free: 3.074 MB / 170.7 MB
"
[Timeout remaining time 179]
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/package.mo): time 0.4113/0.4113, allocations: 88.35 MB / 326.4 MB, free: 0.9648 MB / 298.7 MB
"
[Timeout remaining time 179]
Using package Dynawo with version 1.8.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/package.mo)
Using package Modelica with version 3.2.3 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+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(Dynawo.Examples.GridCodeSimulations.RunSimulations,tolerance=1e-06,outputFormat="empty",numberOfIntervals=2500,variableFilter="",fileNamePrefix="Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations")
translateModel(Dynawo.Examples.GridCodeSimulations.RunSimulations,tolerance=1e-06,outputFormat="empty",numberOfIntervals=2500,variableFilter="",fileNamePrefix="Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations") [Timeout 660]
"Notification: Modelica requested package Complex of version 3.2.3. Complex 4.1.0 is used instead which states that it is fully compatible without conversion script needed.
Notification: Modelica requested package ModelicaServices of version 3.2.3. ModelicaServices 4.1.0 is used instead which states that it is fully compatible without conversion script needed.
Notification: Performance of FrontEnd - loaded program: time 0.001087/0.001087, allocations: 74.83 kB / 0.4901 GB, free: 22.95 MB / 442.7 MB
Notification: Performance of FrontEnd - Absyn->SCode: time 0.1141/0.1152, allocations: 79.84 MB / 0.568 GB, free: 8.289 MB / 490.7 MB
Notification: Performance of NFInst.instantiate(Dynawo.Examples.GridCodeSimulations.RunSimulations): time 0.06354/0.1788, allocations: 81.48 MB / 0.6476 GB, free: 6.445 MB / 0.5573 GB
Notification: Performance of NFInst.instExpressions: time 0.3331/0.5119, allocations: 43.16 MB / 0.6898 GB, free: 4.602 MB / 0.5886 GB
Notification: Performance of NFInst.updateImplicitVariability: time 0.01948/0.5314, allocations: 0.7584 MB / 0.6905 GB, free: 4.602 MB / 0.5886 GB
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Events/NodeFault.mo:24:3-24:107:writable] Warning: Connector nodeFault is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Loads/BaseClasses/BaseLoad.mo:32:3-32:125:writable] Warning: Connector UPu is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:22:3-22:125:writable] Warning: Connector switchOffSignal3 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:20:3-20:98:writable] Warning: Connector switchOffSignal1 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:21:3-21:125:writable] Warning: Connector switchOffSignal2 is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Controls/Basics/SwitchOff/SwitchOffLogic.mo:24:3-24:105:writable] Warning: Connector running is not balanced: The number of potential variables (1) is not equal to the number of flow variables (0).
Notification: Performance of NFTyping.typeComponents: time 0.01663/0.548, allocations: 7.129 MB / 0.6975 GB, free: 4.602 MB / 0.5886 GB
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/Utilities/Strings.mo:139:3-175:14:writable] Warning: Pure function 'Modelica.Utilities.Strings.isEmpty' contains a call to impure function 'Modelica.Utilities.Strings.Advanced.skipWhiteSpace'.
Notification: Performance of NFTyping.typeBindings: time 0.02726/0.5753, allocations: 10.01 MB / 0.7072 GB, free: 4.523 MB / 0.5886 GB
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI2Xcca.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI2Xccb.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI5.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI6.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI7QMax.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI7QMin.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Buses/Bus.mo:29:3-33:9:writable] Warning: In relation sheetI10.bus.terminal.V.re == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Buses/Bus.mo:29:3-33:9:writable] Warning: In relation sheetI10.bus.terminal.V.im == 0.0, == on Real operands is deprecated in non-function contexts.
[/home/hudson/saved_omc/libraries/.openmodelica/libraries/Dynawo master/Electrical/Wind/WECC/WT4CurrentSource_INIT.mo:82:3-82:98:writable] Warning: In relation Modelica.ComplexMath.'abs'(sheetI10.INIT.sInj0Pu) == 0.0, == on Real operands is deprecated in non-function contexts.
Notification: Performance of NFTyping.typeClassSections: time 0.03523/0.6105, allocations: 24.36 MB / 0.731 GB, free: 13.79 MB / 0.6042 GB
Notification: Performance of NFFlatten.flatten: time 0.05351/0.664, allocations: 48.22 MB / 0.7781 GB, free: 2.148 MB / 0.6198 GB
Notification: Performance of NFFlatten.resolveConnections: time 0.02293/0.6869, allocations: 10.49 MB / 0.7884 GB, free: 10.69 MB / 0.6355 GB
Notification: Performance of NFEvalConstants.evaluate: time 0.02547/0.7124, allocations: 16.95 MB / 0.8049 GB, free: 11.11 MB / 0.6511 GB
Notification: Performance of NFSimplifyModel.simplify: time 0.01862/0.731, allocations: 15.96 MB / 0.8205 GB, free: 11.36 MB / 0.6667 GB
Notification: Performance of NFPackage.collectConstants: time 0.01358/0.7446, allocations: 5.711 MB / 0.8261 GB, free: 5.648 MB / 0.6667 GB
Notification: Performance of NFFlatten.collectFunctions: time 0.01225/0.7568, allocations: 6.273 MB / 0.8322 GB, free: 15.39 MB / 0.6823 GB
Notification: Performance of NFScalarize.scalarize: time 0.0119/0.7687, allocations: 10.76 MB / 0.8427 GB, free: 4.758 MB / 0.6823 GB
Notification: Performance of NFVerifyModel.verify: time 0.02002/0.7888, allocations: 15.2 MB / 0.8576 GB, free: 5.645 MB / 0.698 GB
Notification: Performance of NFConvertDAE.convert: time 0.07423/0.863, allocations: 71.63 MB / 0.9275 GB, free: 15.43 MB / 0.7761 GB
Notification: Performance of FrontEnd - DAE generated: time 7.324e-06/0.863, allocations: 0 / 0.9275 GB, free: 15.43 MB / 0.7761 GB
Notification: Performance of FrontEnd: time 2.485e-06/0.863, allocations: 0 / 0.9275 GB, free: 15.43 MB / 0.7761 GB
Notification: Performance of Transformations before backend: time 0.001851/0.8648, allocations: 0 / 0.9275 GB, free: 15.43 MB / 0.7761 GB
Notification: Model statistics after passing the front-end and creating the data structures used by the back-end:
 * Number of equations: 5452
 * Number of variables: 5452
Notification: Performance of Generate backend data structure: time 0.0969/0.9617, allocations: 44.63 MB / 0.9711 GB, free: 2.566 MB / 0.8073 GB
Notification: Performance of prepare preOptimizeDAE: time 5.554e-05/0.9618, allocations: 12.03 kB / 0.9711 GB, free: 2.555 MB / 0.8073 GB
Notification: Performance of preOpt normalInlineFunction (simulation): time 0.02689/0.9887, allocations: 7.42 MB / 0.9784 GB, free: 11.18 MB / 0.823 GB
Notification: Performance of preOpt evaluateParameters (simulation): time 0.04692/1.036, allocations: 25.62 MB / 1.003 GB, free: 1.996 MB / 0.8386 GB
Notification: Performance of preOpt simplifyIfEquations (simulation): time 0.2754/1.311, allocations: 7.313 MB / 1.011 GB, free: 286.7 MB / 0.8386 GB
Notification: Performance of preOpt expandDerOperator (simulation): time 0.007874/1.319, allocations: 2.181 MB / 1.013 GB, free: 286.7 MB / 0.8386 GB
Notification: Performance of preOpt clockPartitioning (simulation): time 0.06882/1.388, allocations: 33.28 MB / 1.045 GB, free: 268.3 MB / 0.8386 GB
Notification: Performance of preOpt findStateOrder (simulation): time 0.0006651/1.388, allocations: 45.19 kB / 1.045 GB, free: 268.3 MB / 0.8386 GB
Notification: Performance of preOpt replaceEdgeChange (simulation): time 0.00618/1.394, allocations: 0.9126 MB / 1.046 GB, free: 267.6 MB / 0.8386 GB
Notification: Performance of preOpt inlineArrayEqn (simulation): time 0.0006497/1.395, allocations: 0.5168 MB / 1.047 GB, free: 267.6 MB / 0.8386 GB
Notification: Performance of preOpt removeEqualRHS (simulation): time 0.04431/1.439, allocations: 25.7 MB / 1.072 GB, free: 251 MB / 0.8386 GB
Warning: The model contains alias variables with redundant start and/or conflicting nominal values. It is recommended to resolve the conflicts, because otherwise the system could be hard to solve. To print the conflicting alias sets and the chosen candidates please use -d=aliasConflicts.
Notification: Performance of preOpt removeSimpleEquations (simulation): time 0.1365/1.576, allocations: 97.84 MB / 1.167 GB, free: 155.8 MB / 0.8386 GB
Notification: Performance of preOpt comSubExp (simulation): time 0.03946/1.615, allocations: 24.68 MB / 1.191 GB, free: 131 MB / 0.8386 GB
Notification: Performance of preOpt resolveLoops (simulation): time 0.01933/1.635, allocations: 11.5 MB / 1.203 GB, free: 119.4 MB / 0.8386 GB
Notification: Performance of preOpt evalFunc (simulation): time 0.001842/1.637, allocations: 265.9 kB / 1.203 GB, free: 119.2 MB / 0.8386 GB
Notification: Performance of preOpt encapsulateWhenConditions (simulation): time 0.0295/1.666, allocations: 15.77 MB / 1.218 GB, free: 103.3 MB / 0.8386 GB
Notification: Performance of pre-optimization done (n=1841): time 3.395e-05/1.666, allocations: 0 / 1.218 GB, free: 103.3 MB / 0.8386 GB
Notification: Performance of matching and sorting (n=1841): time 0.07522/1.741, allocations: 39.48 MB / 1.257 GB, free: 63.71 MB / 0.8386 GB
Notification: Performance of inlineWhenForInitialization (initialization): time 0.0005739/1.742, allocations: 3.953 MB / 1.261 GB, free: 58.87 MB / 0.8386 GB
Notification: Performance of selectInitializationVariablesDAE (initialization): time 0.05415/1.796, allocations: 27.71 MB / 1.288 GB, free: 31.42 MB / 0.8386 GB
Notification: Performance of collectPreVariables (initialization): time 0.005617/1.802, allocations: 0.4938 MB / 1.288 GB, free: 30.92 MB / 0.8386 GB
Notification: Performance of collectInitialEqns (initialization): time 0.0152/1.817, allocations: 14.34 MB / 1.302 GB, free: 16.66 MB / 0.8386 GB
Notification: Performance of collectInitialBindings (initialization): time 0.009816/1.827, allocations: 6.562 MB / 1.309 GB, free: 10.21 MB / 0.8386 GB
Notification: Performance of simplifyInitialFunctions (initialization): time 0.01875/1.845, allocations: 5.11 MB / 1.314 GB, free: 5.09 MB / 0.8386 GB
Notification: Performance of setup shared object (initialization): time 2.559e-05/1.845, allocations: 305.1 kB / 1.314 GB, free: 4.789 MB / 0.8386 GB
Notification: Performance of preBalanceInitialSystem (initialization): time 0.02476/1.87, allocations: 13.61 MB / 1.327 GB, free: 7.121 MB / 0.8542 GB
Notification: Performance of partitionIndependentBlocks (initialization): time 0.3612/2.231, allocations: 21.83 MB / 1.348 GB, free: 262.8 MB / 0.8542 GB
Notification: Performance of analyzeInitialSystem (initialization): time 0.1126/2.344, allocations: 65.32 MB / 1.412 GB, free: 240.5 MB / 0.8542 GB
Notification: Performance of solveInitialSystemEqSystem (initialization): time 0.0001594/2.344, allocations: 24 kB / 1.412 GB, free: 240.4 MB / 0.8542 GB
Notification: Performance of matching and sorting (n=3549) (initialization): time 0.07566/2.42, allocations: 38.52 MB / 1.45 GB, free: 206.9 MB / 0.8542 GB
Notification: Performance of prepare postOptimizeDAE: time 0.0004006/2.42, allocations: 417.3 kB / 1.45 GB, free: 206.5 MB / 0.8542 GB
Notification: Performance of postOpt simplifyComplexFunction (initialization): time 0.000126/2.42, allocations: 88 kB / 1.45 GB, free: 206.4 MB / 0.8542 GB
Notification: Performance of postOpt tearingSystem (initialization): time 0.002576/2.423, allocations: 2.754 MB / 1.453 GB, free: 203.7 MB / 0.8542 GB
Notification: Performance of postOpt solveSimpleEquations (initialization): time 0.02789/2.451, allocations: 9.309 MB / 1.462 GB, free: 194.4 MB / 0.8542 GB
Notification: Performance of postOpt calculateStrongComponentJacobians (initialization): time 0.009523/2.46, allocations: 9.541 MB / 1.471 GB, free: 184.8 MB / 0.8542 GB
Notification: Performance of postOpt simplifyAllExpressions (initialization): time 0.0216/2.482, allocations: 3.272 MB / 1.475 GB, free: 182.5 MB / 0.8542 GB
Notification: Performance of postOpt collapseArrayExpressions (initialization): time 0.005999/2.488, allocations: 0.9491 MB / 1.476 GB, free: 181.5 MB / 0.8542 GB
Warning: Assuming fixed start value for the following 252 variables:
         sheetI2Xcca.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xcca.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xcca.Xcc_a.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Xcc_a.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Xcc_a.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Xcc_a.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line22.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line22.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line21.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line21.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI6.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI6.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI6.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI6.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMax.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMax.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMax.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMax.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMin.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMin.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMin.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMin.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.loadAlphaBeta.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.loadAlphaBeta.State0 fixed = true )  \"Load connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.inertialGrid1.injectorURI.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.inertialGrid1.injectorURI.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.inertialGrid1.injectorURI.running.value:DISCRETE(flow=false start = sheetI10.inertialGrid1.injectorURI.Running0 fixed = true )  type: Boolean
         sheetI10.loadAlphaBeta.running.value:DISCRETE(flow=false start = sheetI10.loadAlphaBeta.Running0 fixed = true )  type: Boolean
         sheetI10.loadAlphaBeta.deltaP:VARIABLE(flow=false start = 0.0 fixed = true )  \"Delta to apply on PRef in %\" type: Real
         sheetI10.loadAlphaBeta.deltaQ:VARIABLE(flow=false start = 0.0 fixed = true )  \"Delta to apply on QRef in %\" type: Real
         sheetI10.inertialGrid1.reducedOrderSFR.PspPu:VARIABLE(flow=false start = sheetI10.inertialGrid1.reducedOrderSFR.Psp0Pu fixed = true )  \"Incremental power set point in pu (base SNom)\" type: Real
         sheetI10.inertialGrid1.reducedOrderSFR.firstOrder.y:VARIABLE(flow=false start = sheetI10.inertialGrid1.reducedOrderSFR.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.line.running.value:DISCRETE(flow=false start = sheetI10.line.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI10.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI10.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI10.Unit.wecc_repc.leadLag.X0[1] * sheetI10.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI10.Unit.injector.running.value:DISCRETE(flow=false start = sheetI10.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.line.running.value:DISCRETE(flow=false start = sheetI10.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI10.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI10.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI10.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI7QMin.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI7QMin.Unit.wecc_repc.leadLag.X0[1] * sheetI7QMin.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI7QMin.Unit.injector.running.value:DISCRETE(flow=false start = sheetI7QMin.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI7QMin.Unit.line.running.value:DISCRETE(flow=false start = sheetI7QMin.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI7QMin.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI7QMin.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMin.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI7QMax.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI7QMax.Unit.wecc_repc.leadLag.X0[1] * sheetI7QMax.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI7QMax.Unit.injector.running.value:DISCRETE(flow=false start = sheetI7QMax.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI7QMax.Unit.line.running.value:DISCRETE(flow=false start = sheetI7QMax.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI7QMax.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI7QMax.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMax.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI6.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI6.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI6.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI6.Unit.wecc_repc.leadLag.X0[1] * sheetI6.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI6.Unit.injector.running.value:DISCRETE(flow=false start = sheetI6.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI6.Unit.line.running.value:DISCRETE(flow=false start = sheetI6.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI6.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI6.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI6.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI6.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI5.line.running.value:DISCRETE(flow=false start = sheetI5.line.Running0 fixed = true )  type: Boolean
         sheetI5.line21.running.value:DISCRETE(flow=false start = sheetI5.line21.Running0 fixed = true )  type: Boolean
         sheetI5.line22.running.value:DISCRETE(flow=false start = sheetI5.line22.Running0 fixed = true )  type: Boolean
         sheetI5.nodeFault.nodeFault.value:DISCRETE(flow=false start = false fixed = true )  type: Boolean
         sheetI5.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI5.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI5.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI5.Unit.wecc_repc.leadLag.X0[1] * sheetI5.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI5.Unit.injector.running.value:DISCRETE(flow=false start = sheetI5.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI5.Unit.line.running.value:DISCRETE(flow=false start = sheetI5.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI5.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI5.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI5.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI5.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI2Xccb.Xcc_a.running.value:DISCRETE(flow=false start = sheetI2Xccb.Xcc_a.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI2Xccb.Unit.wecc_repc.leadLag.X0[1] * sheetI2Xccb.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI2Xccb.Unit.injector.running.value:DISCRETE(flow=false start = sheetI2Xccb.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.line.running.value:DISCRETE(flow=false start = sheetI2Xccb.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI2Xccb.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xccb.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI2Xcca.Xcc_a.running.value:DISCRETE(flow=false start = sheetI2Xcca.Xcc_a.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI2Xcca.Unit.wecc_repc.leadLag.X0[1] * sheetI2Xcca.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI2Xcca.Unit.injector.running.value:DISCRETE(flow=false start = sheetI2Xcca.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.line.running.value:DISCRETE(flow=false start = sheetI2Xcca.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI2Xcca.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xcca.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
Notification: Performance of preBalanceInitialSystem (initialization_lambda0): time 0.04339/2.531, allocations: 20.17 MB / 1.495 GB, free: 161.5 MB / 0.8542 GB
Notification: Performance of partitionIndependentBlocks (initialization_lambda0): time 0.02918/2.561, allocations: 21.39 MB / 1.516 GB, free: 137.7 MB / 0.8542 GB
Notification: Performance of analyzeInitialSystem (initialization_lambda0): time 0.106/2.666, allocations: 64.26 MB / 1.579 GB, free: 71.98 MB / 0.8542 GB
Notification: Performance of solveInitialSystemEqSystem (initialization_lambda0): time 0.000123/2.667, allocations: 28 kB / 1.579 GB, free: 71.95 MB / 0.8542 GB
Notification: Performance of matching and sorting (n=3549) (initialization_lambda0): time 0.06869/2.735, allocations: 37.76 MB / 1.616 GB, free: 34.96 MB / 0.8542 GB
Notification: Performance of prepare postOptimizeDAE: time 0.0003302/2.736, allocations: 415.7 kB / 1.616 GB, free: 34.51 MB / 0.8542 GB
Notification: Performance of postOpt simplifyComplexFunction (initialization): time 0.000102/2.736, allocations: 88.16 kB / 1.616 GB, free: 34.43 MB / 0.8542 GB
Notification: Performance of postOpt tearingSystem (initialization): time 0.002452/2.738, allocations: 2.746 MB / 1.619 GB, free: 31.66 MB / 0.8542 GB
Notification: Performance of postOpt solveSimpleEquations (initialization): time 0.02596/2.764, allocations: 9.188 MB / 1.628 GB, free: 22.46 MB / 0.8542 GB
Notification: Performance of postOpt calculateStrongComponentJacobians (initialization): time 0.008951/2.773, allocations: 9.541 MB / 1.637 GB, free: 12.73 MB / 0.8542 GB
Notification: Performance of postOpt simplifyAllExpressions (initialization): time 0.01993/2.793, allocations: 3.115 MB / 1.64 GB, free: 9.98 MB / 0.8542 GB
Notification: Performance of postOpt collapseArrayExpressions (initialization): time 0.005637/2.799, allocations: 0.9452 MB / 1.641 GB, free: 9.035 MB / 0.8542 GB
Warning: Assuming fixed start value for the following 252 variables:
         sheetI2Xcca.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xcca.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xcca.Xcc_a.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xcca.Xcc_a.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI2Xccb.Xcc_a.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI2Xccb.Xcc_a.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line22.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line22.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line21.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line21.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI5.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI5.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI6.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI6.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI6.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI6.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMax.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMax.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMax.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMax.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMin.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMin.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI7QMin.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI7QMin.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.Unit.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.Unit.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.Unit.injector.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.Unit.injector.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.line.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.line.State0 fixed = true )  \"Line connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.loadAlphaBeta.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.loadAlphaBeta.State0 fixed = true )  \"Load connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.inertialGrid1.injectorURI.state:DISCRETE(min = Dynawo.Electrical.Constants.state.Open max = Dynawo.Electrical.Constants.state.Undefined start = sheetI10.inertialGrid1.injectorURI.State0 fixed = true )  \"Injector connection state\" type: enumeration(Open, Closed, Closed1, Closed2, Closed3, Undefined)
         sheetI10.inertialGrid1.injectorURI.running.value:DISCRETE(flow=false start = sheetI10.inertialGrid1.injectorURI.Running0 fixed = true )  type: Boolean
         sheetI10.loadAlphaBeta.running.value:DISCRETE(flow=false start = sheetI10.loadAlphaBeta.Running0 fixed = true )  type: Boolean
         sheetI10.loadAlphaBeta.deltaP:VARIABLE(flow=false start = 0.0 fixed = true )  \"Delta to apply on PRef in %\" type: Real
         sheetI10.loadAlphaBeta.deltaQ:VARIABLE(flow=false start = 0.0 fixed = true )  \"Delta to apply on QRef in %\" type: Real
         sheetI10.inertialGrid1.reducedOrderSFR.PspPu:VARIABLE(flow=false start = sheetI10.inertialGrid1.reducedOrderSFR.Psp0Pu fixed = true )  \"Incremental power set point in pu (base SNom)\" type: Real
         sheetI10.inertialGrid1.reducedOrderSFR.firstOrder.y:VARIABLE(flow=false start = sheetI10.inertialGrid1.reducedOrderSFR.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.line.running.value:DISCRETE(flow=false start = sheetI10.line.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI10.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI10.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI10.Unit.wecc_repc.leadLag.X0[1] * sheetI10.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI10.Unit.injector.running.value:DISCRETE(flow=false start = sheetI10.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.line.running.value:DISCRETE(flow=false start = sheetI10.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI10.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI10.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI10.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI10.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI10.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI10.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI7QMin.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI7QMin.Unit.wecc_repc.leadLag.X0[1] * sheetI7QMin.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI7QMin.Unit.injector.running.value:DISCRETE(flow=false start = sheetI7QMin.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI7QMin.Unit.line.running.value:DISCRETE(flow=false start = sheetI7QMin.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI7QMin.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI7QMin.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI7QMin.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMin.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI7QMax.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI7QMax.Unit.wecc_repc.leadLag.X0[1] * sheetI7QMax.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI7QMax.Unit.injector.running.value:DISCRETE(flow=false start = sheetI7QMax.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI7QMax.Unit.line.running.value:DISCRETE(flow=false start = sheetI7QMax.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI7QMax.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI7QMax.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI7QMax.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI7QMax.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI6.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI6.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI6.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI6.Unit.wecc_repc.leadLag.X0[1] * sheetI6.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI6.Unit.injector.running.value:DISCRETE(flow=false start = sheetI6.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI6.Unit.line.running.value:DISCRETE(flow=false start = sheetI6.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI6.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI6.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI6.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI6.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI6.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI6.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI5.line.running.value:DISCRETE(flow=false start = sheetI5.line.Running0 fixed = true )  type: Boolean
         sheetI5.line21.running.value:DISCRETE(flow=false start = sheetI5.line21.Running0 fixed = true )  type: Boolean
         sheetI5.line22.running.value:DISCRETE(flow=false start = sheetI5.line22.Running0 fixed = true )  type: Boolean
         sheetI5.nodeFault.nodeFault.value:DISCRETE(flow=false start = false fixed = true )  type: Boolean
         sheetI5.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI5.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI5.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI5.Unit.wecc_repc.leadLag.X0[1] * sheetI5.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI5.Unit.injector.running.value:DISCRETE(flow=false start = sheetI5.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI5.Unit.line.running.value:DISCRETE(flow=false start = sheetI5.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI5.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI5.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI5.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI5.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI5.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI5.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI2Xccb.Xcc_a.running.value:DISCRETE(flow=false start = sheetI2Xccb.Xcc_a.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI2Xccb.Unit.wecc_repc.leadLag.X0[1] * sheetI2Xccb.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI2Xccb.Unit.injector.running.value:DISCRETE(flow=false start = sheetI2Xccb.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.line.running.value:DISCRETE(flow=false start = sheetI2Xccb.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI2Xccb.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI2Xccb.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI2Xccb.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xccb.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
         sheetI2Xcca.Xcc_a.running.value:DISCRETE(flow=false start = sheetI2Xcca.Xcc_a.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.limitedIntegrator1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgq.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.omegaRefWTGQPu0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_wtgq.limitedIntegratorFreeze.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgq.limitedIntegratorFreeze.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze2.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze2.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_regc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_regc.offDelay.delaySignal:DISCRETE(start = false fixed = true protected = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_regc.offDelay.tNext:DISCRETE(start = -1.0 unit = \"s\" fixed = true protected = true )  type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder2.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder2.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.firstOrder3.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.firstOrder3.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_repc.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_repc.leadLag.x_scaled[1]:VARIABLE(start = sheetI2Xcca.Unit.wecc_repc.leadLag.X0[1] * sheetI2Xcca.Unit.wecc_repc.leadLag.a_end fixed = true protected = true )  \"Scaled vector x\" type: Real [1]
         sheetI2Xcca.Unit.injector.running.value:DISCRETE(flow=false start = sheetI2Xcca.Unit.injector.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.line.running.value:DISCRETE(flow=false start = sheetI2Xcca.Unit.line.Running0 fixed = true )  type: Boolean
         sheetI2Xcca.Unit.wecc_reec.firstOrder.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.UInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.firstOrder1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.firstOrder1.y_start fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.limPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.limPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.varLimPIDFreeze.I.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.varLimPIDFreeze.I.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze1.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze1.Y0 fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.rateLimFirstOrderFreeze.y:VARIABLE(flow=false start = sheetI2Xcca.Unit.wecc_wtgp.PInj0Pu fixed = true )  \"Connector of Real output signal\" type: Real
         sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDip:DISCRETE(flow=false start = false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  \"ending time of the voltage dip start (in seconds)\" type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu:DISCRETE(start = 0.0 unit = \"1\" fixed = true )  type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime:DISCRETE(start = -1.0 unit = \"s\" fixed = true )  type: Real
         sheetI2Xcca.Unit.Pm0Pu:VARIABLE(unit = \"1\" fixed = true )  \"Initial mechanical power in pu (base SNom)\" type: Real
         sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDip:DISCRETE(flow=false fixed = true )  \"Ongoing voltage dip\" type: Boolean
         sheetI2Xcca.Unit.wecc_regc.offDelay.u:DISCRETE(flow=false fixed = true )  \"Boolean input signal\" type: Boolean
Notification: Model statistics after passing the back-end for initialization:
 * Number of independent subsystems: 395
 * Number of states: 0 ()
 * Number of discrete variables: 539 ($PRE.sheetI2Xcca.Unit.line.state,sheetI2Xcca.Unit.line.state,$PRE.sheetI2Xcca.Unit.injector.state,sheetI2Xcca.Unit.injector.state,$PRE.sheetI2Xcca.Xcc_a.state,sheetI2Xcca.Xcc_a.state,$PRE.sheetI2Xccb.Unit.line.state,sheetI2Xccb.Unit.line.state,$PRE.sheetI2Xccb.Unit.injector.state,sheetI2Xccb.Unit.injector.state,$PRE.sheetI2Xccb.Xcc_a.state,sheetI2Xccb.Xcc_a.state,$PRE.sheetI5.Unit.line.state,sheetI5.Unit.line.state,$PRE.sheetI5.Unit.injector.state,sheetI5.Unit.injector.state,$PRE.sheetI5.line22.state,sheetI5.line22.state,$PRE.sheetI5.line21.state,sheetI5.line21.state,$PRE.sheetI5.line.state,sheetI5.line.state,$whenCondition86,$whenCondition87,$PRE.sheetI6.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$whenCondition74,sheetI6.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,$PRE.sheetI6.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,sheetI6.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$PRE.sheetI6.Unit.line.state,sheetI6.Unit.line.state,$PRE.sheetI6.Unit.injector.state,sheetI6.Unit.injector.state,$PRE.sheetI6.infiniteBusFromTable.tableUPhase.nextTimeEvent,$whenCondition59,$PRE.sheetI6.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition58,$PRE.sheetI7QMax.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$whenCondition57,sheetI7QMax.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,$PRE.sheetI7QMax.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,sheetI7QMax.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$PRE.sheetI7QMax.Unit.line.state,sheetI7QMax.Unit.line.state,$PRE.sheetI7QMax.Unit.injector.state,sheetI7QMax.Unit.injector.state,$PRE.sheetI7QMax.infiniteBusFromTable.tableUPhase.nextTimeEvent,$whenCondition42,$PRE.sheetI7QMax.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition41,$PRE.sheetI7QMin.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$whenCondition40,sheetI7QMin.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,$PRE.sheetI7QMin.infiniteBusFromTable.tableOmegaRefPu.nextTimeEventScaled,sheetI7QMin.infiniteBusFromTable.tableOmegaRefPu.nextTimeEvent,$PRE.sheetI7QMin.Unit.line.state,sheetI7QMin.Unit.line.state,$PRE.sheetI7QMin.Unit.injector.state,sheetI7QMin.Unit.injector.state,$PRE.sheetI7QMin.infiniteBusFromTable.tableUPhase.nextTimeEvent,$whenCondition25,$PRE.sheetI7QMin.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition24,$PRE.sheetI10.Unit.line.state,sheetI10.Unit.line.state,$PRE.sheetI10.Unit.injector.state,sheetI10.Unit.injector.state,$PRE.sheetI10.line.state,sheetI10.line.state,$PRE.sheetI10.loadAlphaBeta.state,sheetI10.loadAlphaBeta.state,$PRE.sheetI10.inertialGrid1.injectorURI.state,sheetI10.inertialGrid1.injectorURI.state,$PRE.sheetI10.inertialGrid1.injectorURI.running.value,sheetI10.inertialGrid1.injectorURI.running.value,$whenCondition2,$whenCondition1,$whenCondition3,sheetI2Xcca.Xcc_a.switchOffSignal2.value,sheetI2Xcca.Xcc_a.switchOffSignal1.value,sheetI2Xcca.Unit.injector.switchOffSignal3.value,sheetI2Xcca.Unit.injector.switchOffSignal2.value,sheetI2Xcca.Unit.injector.switchOffSignal1.value,sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI2Xcca.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI2Xccb.Xcc_a.switchOffSignal2.value,sheetI2Xccb.Xcc_a.switchOffSignal1.value,sheetI2Xccb.Unit.injector.switchOffSignal3.value,sheetI2Xccb.Unit.injector.switchOffSignal2.value,sheetI2Xccb.Unit.injector.switchOffSignal1.value,sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI2Xccb.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI5.line.switchOffSignal2.value,sheetI5.line.switchOffSignal1.value,sheetI5.Unit.injector.switchOffSignal3.value,sheetI5.Unit.injector.switchOffSignal2.value,sheetI5.Unit.injector.switchOffSignal1.value,sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI5.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI6.Unit.injector.switchOffSignal3.value,sheetI6.Unit.injector.switchOffSignal2.value,sheetI6.Unit.injector.switchOffSignal1.value,sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI6.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI7QMax.Unit.injector.switchOffSignal3.value,sheetI7QMax.Unit.injector.switchOffSignal2.value,sheetI7QMax.Unit.injector.switchOffSignal1.value,sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI7QMax.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI7QMin.Unit.injector.switchOffSignal3.value,sheetI7QMin.Unit.injector.switchOffSignal2.value,sheetI7QMin.Unit.injector.switchOffSignal1.value,sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI7QMin.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI10.loadAlphaBeta.switchOffSignal2.value,sheetI10.loadAlphaBeta.switchOffSignal1.value,sheetI10.line.switchOffSignal2.value,sheetI10.line.switchOffSignal1.value,sheetI10.Unit.injector.switchOffSignal3.value,sheetI10.Unit.injector.switchOffSignal2.value,sheetI10.Unit.injector.switchOffSignal1.value,sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze1.local_freeze,sheetI10.Unit.wecc_regc.rateLimFirstOrderFreeze2.local_freeze,sheetI10.inertialGrid1.injectorURI.switchOffSignal3.value,sheetI10.inertialGrid1.injectorURI.switchOffSignal2.value,sheetI10.inertialGrid1.injectorURI.switchOffSignal1.value,$PRE.sheetI10.loadAlphaBeta.running.value,$PRE.sheetI10.line.running.value,$PRE.sheetI10.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI10.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI10.Unit.injector.running.value,$PRE.sheetI10.Unit.line.running.value,$PRE.sheetI10.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI10.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI10.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI10.Unit.wecc_regc.Qinj0PuNeg.k,sheetI10.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI10.Unit.wecc_regc.offDelay.u,sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI10.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI10.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI10.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI10.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI10.Unit.line.running.value,sheetI10.Unit.injector.running.value,sheetI10.Unit.wecc_repc.freeze,sheetI10.Unit.wecc_regc.and2.y,sheetI10.Unit.wecc_regc.and1.y,sheetI10.Unit.wecc_regc.and1.u[2],sheetI10.Unit.wecc_regc.offDelay.tNext,sheetI10.Unit.wecc_regc.offDelay.delaySignal,sheetI10.Unit.wecc_regc.offDelay.u,sheetI10.line.running.value,sheetI10.loadAlphaBeta.running.value,$whenCondition5,$whenCondition4,$whenCondition6,$whenCondition8,$whenCondition7,$whenCondition9,$whenCondition11,$whenCondition10,$whenCondition13,$whenCondition12,$whenCondition14,$whenCondition16,$whenCondition15,$whenCondition17,$whenCondition19,$whenCondition18,$whenCondition21,$whenCondition20,$whenCondition23,$whenCondition22,$PRE.sheetI7QMin.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI7QMin.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI7QMin.Unit.injector.running.value,$PRE.sheetI7QMin.Unit.line.running.value,$PRE.sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI7QMin.Unit.wecc_regc.Qinj0PuNeg.k,sheetI7QMin.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI7QMin.Unit.wecc_regc.offDelay.u,sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI7QMin.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI7QMin.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI7QMin.Unit.line.running.value,sheetI7QMin.Unit.injector.running.value,sheetI7QMin.Unit.wecc_repc.freeze,sheetI7QMin.Unit.wecc_regc.and2.y,sheetI7QMin.Unit.wecc_regc.and1.y,sheetI7QMin.Unit.wecc_regc.and1.u[2],sheetI7QMin.Unit.wecc_regc.offDelay.tNext,sheetI7QMin.Unit.wecc_regc.offDelay.delaySignal,sheetI7QMin.Unit.wecc_regc.offDelay.u,sheetI7QMin.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,$PRE.sheetI7QMin.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,sheetI7QMin.infiniteBusFromTable.tableUPhase.nextTimeEvent,sheetI7QMin.infiniteBusFromTable.tableUPu.nextTimeEventScaled,$PRE.sheetI7QMin.infiniteBusFromTable.tableUPu.nextTimeEventScaled,sheetI7QMin.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition27,$whenCondition26,$whenCondition29,$whenCondition28,$whenCondition30,$whenCondition32,$whenCondition31,$whenCondition33,$whenCondition35,$whenCondition34,$whenCondition37,$whenCondition36,$whenCondition39,$whenCondition38,$PRE.sheetI7QMax.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI7QMax.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI7QMax.Unit.injector.running.value,$PRE.sheetI7QMax.Unit.line.running.value,$PRE.sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI7QMax.Unit.wecc_regc.Qinj0PuNeg.k,sheetI7QMax.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI7QMax.Unit.wecc_regc.offDelay.u,sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI7QMax.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI7QMax.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI7QMax.Unit.line.running.value,sheetI7QMax.Unit.injector.running.value,sheetI7QMax.Unit.wecc_repc.freeze,sheetI7QMax.Unit.wecc_regc.and2.y,sheetI7QMax.Unit.wecc_regc.and1.y,sheetI7QMax.Unit.wecc_regc.and1.u[2],sheetI7QMax.Unit.wecc_regc.offDelay.tNext,sheetI7QMax.Unit.wecc_regc.offDelay.delaySignal,sheetI7QMax.Unit.wecc_regc.offDelay.u,sheetI7QMax.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,$PRE.sheetI7QMax.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,sheetI7QMax.infiniteBusFromTable.tableUPhase.nextTimeEvent,sheetI7QMax.infiniteBusFromTable.tableUPu.nextTimeEventScaled,$PRE.sheetI7QMax.infiniteBusFromTable.tableUPu.nextTimeEventScaled,sheetI7QMax.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition44,$whenCondition43,$whenCondition46,$whenCondition45,$whenCondition47,$whenCondition49,$whenCondition48,$whenCondition50,$whenCondition52,$whenCondition51,$whenCondition54,$whenCondition53,$whenCondition56,$whenCondition55,$PRE.sheetI6.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI6.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI6.Unit.injector.running.value,$PRE.sheetI6.Unit.line.running.value,$PRE.sheetI6.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI6.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI6.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI6.Unit.wecc_regc.Qinj0PuNeg.k,sheetI6.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI6.Unit.wecc_regc.offDelay.u,sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI6.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI6.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI6.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI6.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI6.Unit.line.running.value,sheetI6.Unit.injector.running.value,sheetI6.Unit.wecc_repc.freeze,sheetI6.Unit.wecc_regc.and2.y,sheetI6.Unit.wecc_regc.and1.y,sheetI6.Unit.wecc_regc.and1.u[2],sheetI6.Unit.wecc_regc.offDelay.tNext,sheetI6.Unit.wecc_regc.offDelay.delaySignal,sheetI6.Unit.wecc_regc.offDelay.u,sheetI6.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,$PRE.sheetI6.infiniteBusFromTable.tableUPhase.nextTimeEventScaled,sheetI6.infiniteBusFromTable.tableUPhase.nextTimeEvent,sheetI6.infiniteBusFromTable.tableUPu.nextTimeEventScaled,$PRE.sheetI6.infiniteBusFromTable.tableUPu.nextTimeEventScaled,sheetI6.infiniteBusFromTable.tableUPu.nextTimeEvent,$whenCondition61,$whenCondition60,$whenCondition63,$whenCondition62,$whenCondition64,$whenCondition66,$whenCondition65,$whenCondition67,$whenCondition69,$whenCondition68,$whenCondition71,$whenCondition70,$whenCondition73,$whenCondition72,$PRE.sheetI5.line.running.value,$PRE.sheetI5.line21.running.value,$PRE.sheetI5.line22.running.value,$PRE.sheetI5.nodeFault.nodeFault.value,$PRE.sheetI5.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI5.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI5.Unit.injector.running.value,$PRE.sheetI5.Unit.line.running.value,$PRE.sheetI5.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI5.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI5.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI5.Unit.wecc_regc.Qinj0PuNeg.k,sheetI5.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI5.Unit.wecc_regc.offDelay.u,sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI5.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI5.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI5.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI5.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI5.Unit.line.running.value,sheetI5.Unit.injector.running.value,sheetI5.Unit.wecc_repc.freeze,sheetI5.Unit.wecc_regc.and2.y,sheetI5.Unit.wecc_regc.and1.y,sheetI5.Unit.wecc_regc.and1.u[2],sheetI5.Unit.wecc_regc.offDelay.tNext,sheetI5.Unit.wecc_regc.offDelay.delaySignal,sheetI5.Unit.wecc_regc.offDelay.u,sheetI5.nodeFault.nodeFault.value,sheetI5.line22.running.value,sheetI5.line22.switchOffSignal2.value,sheetI5.line22.switchOffSignal1.value,sheetI5.line21.running.value,sheetI5.line21.switchOffSignal2.value,sheetI5.line21.switchOffSignal1.value,sheetI5.line.running.value,$whenCondition76,$whenCondition75,$whenCondition77,$whenCondition79,$whenCondition78,$whenCondition81,$whenCondition80,$whenCondition83,$whenCondition82,$whenCondition85,$whenCondition84,$whenCondition89,$whenCondition88,$whenCondition91,$whenCondition90,$whenCondition92,$whenCondition94,$whenCondition93,$whenCondition95,$whenCondition97,$whenCondition96,$whenCondition99,$whenCondition98,$whenCondition101,$whenCondition100,$PRE.sheetI2Xccb.Xcc_a.running.value,$PRE.sheetI2Xccb.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI2Xccb.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI2Xccb.Unit.injector.running.value,$PRE.sheetI2Xccb.Unit.line.running.value,$PRE.sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI2Xccb.Unit.wecc_regc.Qinj0PuNeg.k,sheetI2Xccb.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI2Xccb.Unit.wecc_regc.offDelay.u,sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI2Xccb.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI2Xccb.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI2Xccb.Unit.line.running.value,sheetI2Xccb.Unit.injector.running.value,sheetI2Xccb.Unit.wecc_repc.freeze,sheetI2Xccb.Unit.wecc_regc.and2.y,sheetI2Xccb.Unit.wecc_regc.and1.y,sheetI2Xccb.Unit.wecc_regc.and1.u[2],sheetI2Xccb.Unit.wecc_regc.offDelay.tNext,sheetI2Xccb.Unit.wecc_regc.offDelay.delaySignal,sheetI2Xccb.Unit.wecc_regc.offDelay.u,sheetI2Xccb.Xcc_a.running.value,$whenCondition103,$whenCondition102,$whenCondition104,$whenCondition106,$whenCondition105,$whenCondition108,$whenCondition107,$whenCondition109,$whenCondition111,$whenCondition110,$whenCondition112,$whenCondition114,$whenCondition113,$whenCondition116,$whenCondition115,$whenCondition118,$whenCondition117,$PRE.sheetI2Xcca.Xcc_a.running.value,$PRE.sheetI2Xcca.Unit.wecc_regc.offDelay.delaySignal,$PRE.sheetI2Xcca.Unit.wecc_regc.offDelay.tNext,$PRE.sheetI2Xcca.Unit.injector.running.value,$PRE.sheetI2Xcca.Unit.line.running.value,$PRE.sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDip,$PRE.sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,$PRE.sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,$PRE.sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI2Xcca.Unit.wecc_regc.Qinj0PuNeg.k,sheetI2Xcca.Unit.wecc_regc.QInj0PuPos.k,$PRE.sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDip,$PRE.sheetI2Xcca.Unit.wecc_regc.offDelay.u,sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDipFrzEndTime,sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.ipMaxFrzPu,sheetI2Xcca.Unit.wecc_reec.currentLimitsCalculation1.vDip,sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDipInjEndTime,sheetI2Xcca.Unit.wecc_reec.iqInjectionLogic.vDip,sheetI2Xcca.Unit.line.running.value,sheetI2Xcca.Unit.injector.running.value,sheetI2Xcca.Unit.wecc_repc.freeze,sheetI2Xcca.Unit.wecc_regc.and2.y,sheetI2Xcca.Unit.wecc_regc.and1.y,sheetI2Xcca.Unit.wecc_regc.and1.u[2],sheetI2Xcca.Unit.wecc_regc.offDelay.tNext,sheetI2Xcca.Unit.wecc_regc.offDelay.delaySignal,sheetI2Xcca.Unit.wecc_regc.offDelay.u,sheetI2Xcca.Xcc_a.running.value,$whenCondition120,$whenCondition119,$whenCondition121,$whenCondition123,$whenCondition122,$whenCondition125,$whenCondition124,$whenCondition126,$whenCondition128,$whenCondition127,$whenCondition129,$whenCondition131,$whenCondition130,$whenCondition133,$whenCondition132,$whenCondition135,$whenCondition134,sheetI10.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI10.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI10.Unit.pll.limIntegrator.local_reset,sheetI10.Unit.pll.integrator.local_reset,sheetI10.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI10.Unit.wecc_repc.limPID.I.local_reset,sheetI10.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI10.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI10.Unit.wecc_wtgt.dPhi.local_reset,sheetI10.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI10.inertialGrid1.integrator.local_reset,sheetI10.inertialGrid1.reducedOrderSFR.integrator.local_reset,sheetI7QMin.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI7QMin.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI7QMin.Unit.pll.limIntegrator.local_reset,sheetI7QMin.Unit.pll.integrator.local_reset,sheetI7QMin.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI7QMin.Unit.wecc_repc.limPID.I.local_reset,sheetI7QMin.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI7QMin.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI7QMin.Unit.wecc_wtgt.dPhi.local_reset,sheetI7QMin.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI7QMax.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI7QMax.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI7QMax.Unit.pll.limIntegrator.local_reset,sheetI7QMax.Unit.pll.integrator.local_reset,sheetI7QMax.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI7QMax.Unit.wecc_repc.limPID.I.local_reset,sheetI7QMax.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI7QMax.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI7QMax.Unit.wecc_wtgt.dPhi.local_reset,sheetI7QMax.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI6.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI6.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI6.Unit.pll.limIntegrator.local_reset,sheetI6.Unit.pll.integrator.local_reset,sheetI6.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI6.Unit.wecc_repc.limPID.I.local_reset,sheetI6.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI6.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI6.Unit.wecc_wtgt.dPhi.local_reset,sheetI6.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI5.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI5.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI5.Unit.pll.limIntegrator.local_reset,sheetI5.Unit.pll.integrator.local_reset,sheetI5.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI5.Unit.wecc_repc.limPID.I.local_reset,sheetI5.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI5.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI5.Unit.wecc_wtgt.dPhi.local_reset,sheetI5.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI2Xccb.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI2Xccb.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI2Xccb.Unit.pll.limIntegrator.local_reset,sheetI2Xccb.Unit.pll.integrator.local_reset,sheetI2Xccb.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI2Xccb.Unit.wecc_repc.limPID.I.local_reset,sheetI2Xccb.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI2Xccb.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI2Xccb.Unit.wecc_wtgt.dPhi.local_reset,sheetI2Xccb.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset,sheetI2Xcca.Unit.wecc_reec.varLimPIDFreeze.I.resetLocal,sheetI2Xcca.Unit.wecc_reec.limPIDFreeze.I.resetLocal,sheetI2Xcca.Unit.pll.limIntegrator.local_reset,sheetI2Xcca.Unit.pll.integrator.local_reset,sheetI2Xcca.Unit.wecc_repc.limPIDFreeze.I.resetLocal,sheetI2Xcca.Unit.wecc_repc.limPID.I.local_reset,sheetI2Xcca.Unit.wecc_wtgt.dOmegaGenerator.local_reset,sheetI2Xcca.Unit.wecc_wtgt.dOmegaTurbine.local_reset,sheetI2Xcca.Unit.wecc_wtgt.dPhi.local_reset,sheetI2Xcca.Unit.wecc_wtgp.absLimRateLimFirstOrderFreeze.integrator.local_reset)
 * Number of discrete states: 0 ()
 * Number of clocked states: 0 ()
 * Top-level inputs: 0
Notification: Strong component statistics for initialization (3373):
 * Single equations (assignments): 3359
 * Array equations: 0
 * Algorithm blocks: 7
 * Record equations: 0
 * When equations: 0
 * If-equations: 0
 * Equation systems (not torn): 5
 * Torn equation systems: 2
 * Mixed (continuous/discrete) equation systems: 0
Notification: Equation system details (not torn):
 * Constant Jacobian (size): 0 systems
 * Linear Jacobian (size,density): 5 systems
   {(4,75.0%), (4,75.0%), (4,75.0%), (8,56.2%), (8,56.2%)}
 * Non-linear Jacobian (size): 0 systems
 * Without analytic Jacobian (size): 0 systems
Notification: Torn system details for strict tearing set:
 * Linear torn systems (#iteration vars, #inner vars, density): 1 system
   {(18,4,29.0%)}
 * Non-linear torn systems (#iteration vars, #inner vars): 1 system
   {(10,4)}
Notification: Performance of prepare postOptimizeDAE: time 0.01332/2.812, allocations: 3.153 MB / 1.644 GB, free: 6.016 MB / 0.8542 GB
Notification: Performance of postOpt lateInlineFunction (simulation): time 0.01137/2.823, allocations: 2.93 MB / 1.647 GB, free: 3.066 MB / 0.8542 GB
Notification: Performance of postOpt wrapFunctionCalls (simulation): time 0.3869/3.21, allocations: 29.26 MB / 1.676 GB, free: 277.5 MB / 0.8698 GB
Notification: Performance of postOpt simplifysemiLinear (simulation): time 0.0004351/3.211, allocations: 97.92 kB / 1.676 GB, free: 277.5 MB / 0.8698 GB
Notification: Performance of postOpt simplifyComplexFunction (simulation): time 2.395e-05/3.211, allocations: 4.406 kB / 1.676 GB, free: 277.5 MB / 0.8698 GB
Notification: Performance of postOpt removeConstants (simulation): time 0.01734/3.228, allocations: 6.672 MB / 1.682 GB, free: 274.4 MB / 0.8698 GB
Notification: Performance of postOpt simplifyTimeIndepFuncCalls (simulation): time 0.00969/3.238, allocations: 0.5895 MB / 1.683 GB, free: 274.1 MB / 0.8698 GB
Notification: Performance of postOpt simplifyAllExpressions (simulation): time 0.01699/3.255, allocations: 1.759 MB / 1.685 GB, free: 273.8 MB / 0.8698 GB
Notification: Performance of postOpt findZeroCrossings (simulation): time 0.007463/3.262, allocations: 2.005 MB / 1.687 GB, free: 273.3 MB / 0.8698 GB
Notification: Performance of postOpt createDAEmodeBDAE (simulation): time 0.05931/3.321, allocations: 31.24 MB / 1.717 GB, free: 261 MB / 0.8698 GB
Notification: Performance of postOpt symbolicJacobianDAE (simulation): time 0.08191/3.403, allocations: 46.15 MB / 1.762 GB, free: 228.9 MB / 0.8698 GB
Notification: Performance of postOpt setEvaluationStage (simulation): time 0.02283/3.426, allocations: 16.88 MB / 1.779 GB, free: 213.8 MB / 0.8698 GB
Notification: Performance of sorting global known variables: time 0.02584/3.452, allocations: 18.27 MB / 1.797 GB, free: 195.9 MB / 0.8698 GB
Notification: Performance of Backend: time 7.51e-07/3.452, allocations: 0 / 1.797 GB, free: 195.9 MB / 0.8698 GB
Notification: Performance of simCode: created initialization part: time 0.07541/3.527, allocations: 41.16 MB / 1.837 GB, free: 155.1 MB / 0.8698 GB
Notification: Performance of SimCode: time 0.07769/3.605, allocations: 54.71 MB / 1.89 GB, free: 100.5 MB / 0.8698 GB
Notification: Performance of Templates: time 1.864/5.469, allocations: 0.8167 GB / 2.707 GB, free: 258 MB / 0.9168 GB
"
[Timeout remaining time 655]
make -j1 -f Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.makefile [Timeout 660]
(rm -f Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.pipe ; mkfifo Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.pipe ; head -c 1048576 < Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.pipe >> ../files/Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.sim & ./Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations  -abortSlowSimulation -alarm=480 -lv LOG_STATS > Dynawo_dev_Dynawo.Examples.GridCodeSimulations.RunSimulations.pipe 2>&1) [Timeout 480]
[Calling os._exit(0), Time elapsed: 23.148886807030067]
Failed to read output from testmodel.py, exit status != 0:
5.4764398040715605 5.48407166 4.619242165
Calling exit ...
<OMPython.OMCSessionZMQ object at 0x7da5455b03e0>