Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries/ --ompython_omhome=/usr Modelica_3.2.3_Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses.conf.json loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo", uses=false) 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 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo) Using package ModelicaServices with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo) Running command: translateModel(Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses,tolerance=1e-06,outputFormat="mat",numberOfIntervals=8000,variableFilter="time|converter_e.singlePhaseElectroMagneticConverter.1..Phi.re|converter_e.singlePhaseElectroMagneticConverter.2..Phi.im|loss_m.Phi.im|loss_m.Phi.re",fileNamePrefix="Modelica_3.2.3_Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses") translateModel(Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses,tolerance=1e-06,outputFormat="mat",numberOfIntervals=8000,variableFilter="time|converter_e.singlePhaseElectroMagneticConverter.1..Phi.re|converter_e.singlePhaseElectroMagneticConverter.2..Phi.im|loss_m.Phi.im|loss_m.Phi.re",fileNamePrefix="Modelica_3.2.3_Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses") Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo): time 0.001207/0.001207, allocations: 109.1 kB / 18.36 MB, free: 4.703 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo): time 0.001692/0.001693, allocations: 196.7 kB / 19.29 MB, free: 3.777 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo): time 1.302/1.302, allocations: 205.1 MB / 225.2 MB, free: 12.25 MB / 190.1 MB Notification: Performance of FrontEnd - Absyn->SCode: time 2.537e-05/2.541e-05, allocations: 2.281 kB / 282.1 MB, free: 2.5 MB / 222.1 MB Notification: Performance of NFInst.instantiate(Modelica.Magnetic.FundamentalWave.Examples.Components.EddyCurrentLosses): time 0.008043/0.008084, allocations: 7.198 MB / 289.3 MB, free: 11.25 MB / 238.1 MB Notification: Performance of NFInst.instExpressions: time 0.003745/0.01186, allocations: 2.227 MB / 291.5 MB, free: 9.016 MB / 238.1 MB Notification: Performance of NFInst.updateImplicitVariability: time 0.0003856/0.01226, allocations: 47.75 kB / 291.5 MB, free: 8.969 MB / 238.1 MB Notification: Performance of NFTyping.typeComponents: time 0.0007425/0.01304, allocations: 449 kB / 292 MB, free: 8.527 MB / 238.1 MB Notification: Performance of NFTyping.typeBindings: time 0.001702/0.01478, allocations: 0.878 MB / 292.8 MB, free: 7.645 MB / 238.1 MB Notification: Performance of NFTyping.typeClassSections: time 0.0006702/0.01546, allocations: 386 kB / 293.2 MB, free: 7.27 MB / 238.1 MB Notification: Performance of NFFlatten.flatten: time 0.002943/0.01842, allocations: 3.336 MB / 296.6 MB, free: 3.926 MB / 238.1 MB Notification: Performance of NFFlatten.resolveConnections: time 0.001563/0.01999, allocations: 1.646 MB / 298.2 MB, free: 2.234 MB / 238.1 MB Notification: Performance of NFEvalConstants.evaluate: time 0.001199/0.0212, allocations: 1.18 MB / 299.4 MB, free: 1.051 MB / 238.1 MB Notification: Performance of NFSimplifyModel.simplify: time 0.001118/0.02233, allocations: 1.238 MB / 300.6 MB, free: 15.81 MB / 254.1 MB Notification: Performance of NFPackage.collectConstants: time 0.0002189/0.02256, allocations: 192 kB / 300.8 MB, free: 15.62 MB / 254.1 MB Notification: Performance of NFFlatten.collectFunctions: time 0.0005511/0.02312, allocations: 343.8 kB / 301.1 MB, free: 15.29 MB / 254.1 MB Notification: Performance of combineBinaries: time 0.00196/0.02509, allocations: 2.844 MB / 304 MB, free: 12.41 MB / 254.1 MB Notification: Performance of replaceArrayConstructors: time 0.001118/0.02621, allocations: 1.888 MB / 305.9 MB, free: 10.5 MB / 254.1 MB Notification: Performance of NFVerifyModel.verify: time 0.0002385/0.02646, allocations: 231.3 kB / 306.1 MB, free: 10.27 MB / 254.1 MB Notification: Performance of FrontEnd: time 0.0001146/0.02658, allocations: 35.88 kB / 306.1 MB, free: 10.24 MB / 254.1 MB Notification: Model statistics after passing the front-end and creating the data structures used by the back-end: * Number of equations: 689 (328) * Number of variables: 689 (299) Notification: Performance of Bindings: time 0.008736/0.03532, allocations: 10.5 MB / 316.6 MB, free: 15.48 MB / 270.1 MB Notification: Performance of FunctionAlias: time 0.0005408/0.03587, allocations: 0.5713 MB / 317.2 MB, free: 14.89 MB / 270.1 MB Notification: Performance of Early Inline: time 0.005663/0.04154, allocations: 6.237 MB / 323.4 MB, free: 8.598 MB / 270.1 MB Notification: Performance of simplify1: time 0.0002396/0.0418, allocations: 247.7 kB / 323.7 MB, free: 8.355 MB / 270.1 MB Notification: Performance of Alias: time 0.003867/0.04567, allocations: 3.856 MB / 327.5 MB, free: 4.312 MB / 270.1 MB Notification: Performance of simplify2: time 0.0001967/0.04588, allocations: 239.7 kB / 327.8 MB, free: 4.078 MB / 270.1 MB Notification: Performance of Events: time 0.000843/0.04673, allocations: 1.018 MB / 328.8 MB, free: 3.047 MB / 270.1 MB Notification: Performance of Detect States: time 0.001212/0.04795, allocations: 1.425 MB / 330.2 MB, free: 1.582 MB / 270.1 MB Notification: Performance of Partitioning: time 0.00237/0.05033, allocations: 2.238 MB / 332.5 MB, free: 15.29 MB / 286.1 MB Error: Internal error NBSlice.fillDependencyArray failed because number of flattened indices 3 for dependency converter_e.singlePhaseElectroMagneticConverter.port_p.Phi.im could not be devided by the body size 2 without rest. Error: Internal error NBAdjacency.Matrix.createPseudo failed for: [FOR-] (6) ($RES_SIM_99) [----] for $i1 in 1:3 loop [----] [RECD] (2) converter_e.singlePhaseElectroMagneticConverter[$i1].port_p.Phi = converter_e.singlePhaseElectroMagneticConverter[$i1].Phi ($RES_SIM_100) [----] end for; Error: Internal error NBAdjacency.Matrix.create failed to create adjacency matrix for system: System Variables (148/366) **************************** (1) [ALGB] (1) Real converter_e.port_p.V_m.im (2) [ALGB] (1) redeclare Real converter_e.Phi.im = converter_e.port_p.Phi.im (3) [ALGB] (3) flow Real[3] powerb_e.pc.pin.i (4) [ALGB] (3) Real[3] powerb_e.currentSensor.i (5) [ALGB] (3) Real[3] sineVoltage_e.plug_p.pin.v (6) [ALGB] (1) redeclare Real reluctance_e.V_m.im (7) [ALGB] (1) flow Real reluctance_e.port_n.Phi.re (8) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.port_p.V_m.re (9) [ALGB] (3) Real[3] powerb_e.voltageSensor.voltageSensor.v (10) [ALGB] (3) flow Real[3] resistor_e.resistor.p.i (11) [DER-] (3) redeclare Real[3] $DER.converter_e.singlePhaseElectroMagneticConverter.Phi.re (12) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.abs_V_m = {Modelica.ComplexMath.'abs'(converter_e.singlePhaseElectroMagneticConverter[$singlePhaseElectroMagneticConverter1].V_m) for $singlePhaseElectroMagneticConverter1 in 1:3} (13) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.pin_p.v (14) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.port_n.V_m.im (15) [ALGB] (3) Real[3] powerb_e.product.y (16) [ALGB] (3) Real[3] powerb_e.nv.pin.v (17) [ALGB] (3) Real[3] resistor_e.resistor.R_actual (18) [ALGB] (3) Real[3] powerb_e.voltageSensor.plug_n.pin.v (19) [ALGB] (3) flow Real[3] powerb_e.currentSensor.plug_n.pin.i (20) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.arg_V_m = {Modelica.ComplexMath.arg(converter_e.singlePhaseElectroMagneticConverter[$singlePhaseElectroMagneticConverter1].V_m, 0.0) for $singlePhaseElectroMagneticConverter1 in 1:3} (21) [ALGB] (1) Real converter_e.port_p.V_m.re (22) [ALGB] (1) redeclare Real converter_e.Phi.re = converter_e.port_p.Phi.re (23) [ALGB] (3) Real[3] resistor_e.resistor.p.v (24) [ALGB] (3) flow Real[3] converter_e.plug_n.pin.i (25) [ALGB] (3) Real[3] loss_e.v (26) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.pin_p.i (27) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.port_p.Phi.im (28) [ALGB] (3) flow Real[3] powerb_e.nv.pin.i (29) [ALGB] (3) Real[3] converter_e.i = converter_e.plug_p.pin.i (30) [ALGB] (1) Real converter_e.port_n.V_m.im (31) [ALGB] (3) flow Real[3] powerb_e.voltageSensor.plug_n.pin.i (32) [ALGB] (3) Real[3] sineVoltage_e.i (33) [ALGB] (3) Real[3] powerb_e.currentSensor.plug_n.pin.v (34) [ALGB] (1) redeclare Real reluctance_e.V_m.re (35) [ALGB] (3) Real[3] converter_e.plug_n.pin.v (36) [ALGB] (3) Real[3] loss_e.i (37) [ALGB] (1) flow Real reluctance_e.port_n.Phi.im (38) [DER-] (3) redeclare Real[3] $DER.converter_e.singlePhaseElectroMagneticConverter.Phi.im (39) [ALGB] (3) Real[3] converter_e.v = converter_e.plug_p.pin.v - converter_e.plug_n.pin.v (40) [ALGB] (1) Real reluctance_e.arg_V_m = Modelica.ComplexMath.arg(reluctance_e.V_m, 0.0) (41) [ALGB] (1) flow Real converter_e.port_p.Phi.im (42) [ALGB] (3) Real[3] loss_e.plug_p.pin.v (43) [ALGB] (3) Real[3] powerb_e.currentSensor.currentSensor.p.v (44) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.port_n.V_m.re (45) [ALGB] (3) redeclare Real[3] converter_e.singlePhaseElectroMagneticConverter.V_m.re (46) [ALGB] (3) Real[3] sineVoltage_e.v (47) [ALGB] (1) flow Real reluctance_e.port_p.Phi.re (48) [DISC] (3) Boolean[3] $SEV_0[$i1] (49) [ALGB] (1) output Real lossPower_e = sum(loss_e.conductor.LossPower) (50) [ALGB] (1) Real reluctance_e.abs_V_m = Modelica.ComplexMath.'abs'(reluctance_e.V_m) (51) [ALGB] (3) Real[3] powerb_e.pv.pin.v (52) [ALGB] (3) flow Real[3] loss_e.plug_p.pin.i (53) [ALGB] (3) flow Real[3] powerb_e.currentSensor.currentSensor.p.i (54) [ALGB] (1) redeclare Real reluctance_e.Phi.im (55) [ALGB] (3) Real[3] resistor_e.resistor.i (56) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.port_p.Phi.re (57) [ALGB] (3) flow Real[3] resistor_e.plug_n.pin.i (58) [ALGB] (1) Real reluctance_e.port_n.V_m.re (59) [ALGB] (3) Real[3] sineVoltage_e.sineVoltage.p.v (60) [ALGB] (1) Real converter_e.port_n.V_m.re (61) [ALGB] (3) Real[3] loss_e.conductor.T_heatPort (start = {288.15 for $i1 in 1:3}, min = {0.0 for $i1 in 1:3}, nominal = {300.0 for $i1 in 1:3}) (62) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.port_n.Phi.im (63) [ALGB] (3) flow Real[3] loss_e.conductor.n.i (64) [ALGB] (3) flow Real[3] powerb_e.pv.pin.i (65) [ALGB] (3) Real[3] resistor_e.resistor.v (66) [ALGB] (3) Real[3] resistor_e.plug_n.pin.v (67) [ALGB] (3) Real[3] loss_e.conductor.i (68) [ALGB] (3) flow Real[3] sineVoltage_e.sineVoltage.p.i (69) [ALGB] (3) Real[3] powerb_e.voltageSensor.voltageSensor.n.v (70) [ALGB] (1) flow Real converter_e.port_p.Phi.re (71) [ALGB] (3) redeclare Real[3] converter_e.singlePhaseElectroMagneticConverter.V_m.im (72) [ALGB] (1) flow Real reluctance_e.port_p.Phi.im (73) [ALGB] (3) Real[3] sineVoltage_e.sineVoltage.i (74) [ALGB] (3) Real[3] $FUN_3 (75) [ALGB] (3) Real[3] loss_e.conductor.n.v (76) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.abs_Phi = {Modelica.ComplexMath.'abs'(converter_e.singlePhaseElectroMagneticConverter[$singlePhaseElectroMagneticConverter1].Phi) for $singlePhaseElectroMagneticConverter1 in 1:3} (77) [ALGB] (1) flow Real converter_e.port_n.Phi.im (78) [ALGB] (3) Real[3] loss_e.conductor.v (79) [ALGB] (3) flow Real[3] powerb_e.voltageSensor.voltageSensor.n.i (80) [ALGB] (3) Real[3] powerb_e.voltageSensor.v (81) [ALGB] (1) flow Real mground_e.port_p.Phi.re (82) [ALGB] (3) Real[3] sineVoltage_e.sineVoltage.v (83) [ALGB] (1) redeclare Real reluctance_e.Phi.re (84) [ALGB] (1) Real reluctance_e.port_n.V_m.im (85) [ALGB] (3) Real[3] resistor_e.resistor.LossPower (86) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.arg_Phi = {Modelica.ComplexMath.arg(converter_e.singlePhaseElectroMagneticConverter[$singlePhaseElectroMagneticConverter1].Phi, 0.0) for $singlePhaseElectroMagneticConverter1 in 1:3} (87) [DISC] (3) Boolean[3] $SEV_4[$i1] (88) [ALGB] (3) Real[3] resistor_e.resistor.T_heatPort (start = {288.15 for $i1 in 1:3}, min = {0.0 for $i1 in 1:3}, nominal = {300.0 for $i1 in 1:3}) (89) [ALGB] (1) Real reluctance_e.port_p.V_m.re (90) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.port_n.Phi.re (91) [ALGB] (1) flow Real converter_e.port_n.Phi.re (92) [ALGB] (3) flow Real[3] powerb_e.currentSensor.plug_p.pin.i (93) [ALGB] (1) flow Real mground_e.port_p.Phi.im (94) [ALGB] (3) flow Real[3] converter_e.plug_p.pin.i (95) [ALGB] (3) Real[3] loss_e.conductor.LossPower (96) [ALGB] (3) Real[3] sineVoltage_e.sineVoltage.signalSource.y (97) [ALGB] (1) Real reluctance_e.port_p.V_m.im (98) [ALGB] (3) Real[3] powerb_e.currentSensor.plug_p.pin.v (99) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.pin_n.v (100) [ALGB] (3) Real[3] converter_e.plug_p.pin.v (101) [ALGB] (3) flow Real[3] sineVoltage_e.plug_n.pin.i (102) [ALGB] (3) flow Real[3] resistor_e.resistor.n.i (103) [ALGB] (1) Real mground_e.port_p.V_m.re (104) [ALGB] (3) Real[3] loss_e.plug_n.pin.v (105) [ALGB] (3) flow Real[3] converter_e.singlePhaseElectroMagneticConverter.pin_n.i (106) [ALGB] (3) Real[3] powerb_e.currentSensor.currentSensor.i (107) [ALGB] (1) Real converter_e.abs_V_m = Modelica.ComplexMath.'abs'(converter_e.V_m) (108) [ALGB] (3) Real[3] sineVoltage_e.plug_n.pin.v (109) [ALGB] (3) flow Real[3] loss_e.plug_n.pin.i (110) [ALGB] (3) Real[3] resistor_e.resistor.n.v (111) [ALGB] (3) flow Real[3] resistor_e.plug_p.pin.i (112) [ALGB] (1) Real converter_e.arg_V_m = Modelica.ComplexMath.arg(converter_e.V_m, 0.0) (113) [ALGB] (3) Real[3] powerb_e.currentSensor.currentSensor.n.v (114) [ALGB] (3) Real[3] loss_e.conductor.G_actual (115) [ALGB] (3) Real[3] resistor_e.plug_p.pin.v (116) [ALGB] (1) Real mground_e.port_p.V_m.im (117) [ALGB] (3) Real[3] powerb_e.voltageSensor.plug_p.pin.v (118) [ALGB] (3) flow Real[3] powerb_e.currentSensor.currentSensor.n.i (119) [ALGB] (3) Real[3] sineVoltage_e.sineVoltage.n.v (120) [ALGB] (3) flow Real[3] star_e.plug_p.pin.i (121) [ALGB] (3) flow Real[3] powerb_e.voltageSensor.plug_p.pin.i (122) [ALGB] (1) redeclare Real converter_e.V_m.im (123) [ALGB] (3) flow Real[3] loss_e.conductor.p.i (124) [ALGB] (3) Real[3] powerb_e.nc.pin.v (125) [ALGB] (3) flow Real[3] sineVoltage_e.sineVoltage.n.i (126) [ALGB] (3) Real[3] star_e.plug_p.pin.v (127) [DISC] (3) Boolean[3] $SEV_2[$i1] (128) [ALGB] (3) Real[3] loss_e.conductor.p.v (129) [ALGB] (3) flow Real[3] powerb_e.nc.pin.i (130) [ALGB] (3) Real[3] powerb_e.voltageSensor.voltageSensor.p.v (131) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.i (132) [ALGB] (3) flow Real[3] powerb_e.voltageSensor.voltageSensor.p.i (133) [ALGB] (3) Real[3] resistor_e.i (134) [ALGB] (1) redeclare Real converter_e.V_m.re (135) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.v (136) [ALGB] (1) Real reluctance_e.arg_Phi = Modelica.ComplexMath.arg(reluctance_e.Phi, 0.0) (137) [ALGB] (1) Real converter_e.abs_Phi = Modelica.ComplexMath.'abs'(converter_e.Phi) (138) [ALGB] (3) Real[3] converter_e.singlePhaseElectroMagneticConverter.port_p.V_m.im (139) [ALGB] (3) Real[3] powerb_e.product.u2 (140) [ALGB] (3) Real[3] resistor_e.v (141) [ALGB] (3) Real[3] powerb_e.product.u1 (142) [ALGB] (3) Real[3] powerb_e.pc.pin.v (143) [ALGB] (1) flow Real ground_e.p.i (144) [ALGB] (3) Real[3] powerb_e.sum.u (145) [ALGB] (1) Real reluctance_e.abs_Phi = Modelica.ComplexMath.'abs'(reluctance_e.Phi) (146) [ALGB] (1) Real converter_e.arg_Phi = Modelica.ComplexMath.arg(converter_e.Phi, 0.0) (147) [ALGB] (1) Real powerb_e.sum.y (148) [ALGB] (3) flow Real[3] sineVoltage_e.plug_p.pin.i System Equations (175/366) **************************** (1) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_p.V_m.im = converter_e.port_p.V_m.im ($RES_SIM_362) (2) [FOR-] (3) ($RES_SIM_447) (2) [----] for $i1 in 1:3 loop (2) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter.port_p.Phi.re + converter_e.singlePhaseElectroMagneticConverter.port_n.Phi.re = 0.0 ($RES_SIM_448) (2) [----] end for; (3) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_p.V_m.re = converter_e.port_p.V_m.re ($RES_SIM_363) (4) [ARRY] (3) resistor_e.v = resistor_e.plug_p.pin.v - resistor_e.plug_n.pin.v ($RES_SIM_120) (5) [FOR-] (3) ($RES_SIM_364) (5) [----] for $i1 in 1:3 loop (5) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].pin_n.i - converter_e.plug_n.pin[$i1].i = 0.0 ($RES_SIM_365) (5) [----] end for; (6) [FOR-] (3) ($RES_SIM_121) (6) [----] for $i1 in 1:3 loop (6) [----] [SCAL] (1) resistor_e.resistor[$i1].i = resistor_e.resistor[$i1].p.i ($RES_SIM_122) (6) [----] end for; (7) [FOR-] (3) ($RES_SIM_449) (7) [----] for $i1 in 1:3 loop (7) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter.port_p.Phi.im + converter_e.singlePhaseElectroMagneticConverter.port_n.Phi.im = 0.0 ($RES_SIM_450) (7) [----] end for; (8) [ARRY] (3) converter_e.singlePhaseElectroMagneticConverter.pin_n.v = converter_e.plug_n.pin.v ($RES_SIM_366) (9) [FOR-] (3) ($RES_SIM_123) (9) [----] for $i1 in 1:3 loop (9) [----] [SCAL] (1) 0.0 = resistor_e.resistor[$i1].p.i + resistor_e.resistor[$i1].n.i ($RES_SIM_124) (9) [----] end for; (10) [FOR-] (3) ($RES_SIM_367) (10) [----] for $i1 in 1:3 loop (10) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].pin_p.i - converter_e.plug_p.pin[$i1].i = 0.0 ($RES_SIM_368) (10) [----] end for; (11) [SCAL] (1) converter_e.plug_p.pin[3].i + loss_e.plug_p.pin[3].i + powerb_e.nc.pin[3].i = 0.0 ($RES_SIM_209) (12) [FOR-] (3) ($RES_SIM_85) (12) [----] for $i1 in 1:3 loop (12) [----] [SCAL] (1) -converter_e.singlePhaseElectroMagneticConverter[$i1].v = $DER.converter_e.singlePhaseElectroMagneticConverter[$i1].Phi.re * converter_e.singlePhaseElectroMagneticConverter.N.re + $DER.converter_e.singlePhaseElectroMagneticConverter[$i1].Phi.im * converter_e.singlePhaseElectroMagneticConverter.N.im ($RES_SIM_86) (12) [----] end for; (13) [FOR-] (3) ($RES_SIM_125) (13) [----] for $i1 in 1:3 loop (13) [----] [SCAL] (1) resistor_e.resistor[$i1].v = resistor_e.resistor[$i1].p.v - resistor_e.resistor[$i1].n.v ($RES_SIM_126) (13) [----] end for; (14) [ARRY] (3) converter_e.plug_p.pin.v = converter_e.singlePhaseElectroMagneticConverter.pin_p.v ($RES_SIM_369) (15) [FOR-] (3) ($RES_SIM_127) (15) [----] for $i1 in 1:3 loop (15) [----] [SCAL] (1) resistor_e.resistor[$i1].T_heatPort = resistor_e.resistor[$i1].T ($RES_SIM_128) (15) [----] end for; (16) [FOR-] (3) ($RES_SIM_89) (16) [----] for $i1 in 1:3 loop (16) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].pin_p.i + converter_e.singlePhaseElectroMagneticConverter[$i1].pin_n.i = 0.0 ($RES_SIM_90) (16) [----] end for; (17) [FOR-] (3) ($RES_SIM_129) (17) [----] for $i1 in 1:3 loop (17) [----] [SCAL] (1) resistor_e.resistor[$i1].LossPower = resistor_e.resistor[$i1].v * resistor_e.resistor[$i1].i ($RES_SIM_130) (17) [----] end for; (18) [SCAL] (1) ground_e.p.i = sum(star_e.plug_p.pin.i) ($RES_$AUX_446) (19) [FOR-] (3) ($RES_$AUX_443) (19) [----] for $i1 in 1:3 loop (19) [----] [SCAL] (1) $FUN_3[$i1] = sin(sineVoltage_e.sineVoltage[$i1].signalSource.freqHz * 6.283185307179586 * (time - sineVoltage_e.sineVoltage[$i1].signalSource.startTime) + sineVoltage_e.sineVoltage[$i1].signalSource.phase) ($RES_$AUX_444) (19) [----] end for; (20) [SCAL] (1) reluctance_e.abs_V_m = (reluctance_e.V_m.re ^ 2.0 + reluctance_e.V_m.im ^ 2.0) ^ 0.5 ($RES_BND_424) (21) [SCAL] (1) lossPower_e = sum(loss_e.conductor.LossPower) ($RES_$AUX_440) (22) [SCAL] (1) reluctance_e.arg_V_m = Modelica.Math.atan3(reluctance_e.V_m.im, reluctance_e.V_m.re, 0.0) ($RES_BND_425) (23) [SCAL] (1) reluctance_e.abs_Phi = (reluctance_e.Phi.re ^ 2.0 + reluctance_e.Phi.im ^ 2.0) ^ 0.5 ($RES_BND_426) (24) [SCAL] (1) reluctance_e.arg_Phi = Modelica.Math.atan3(reluctance_e.Phi.im, reluctance_e.Phi.re, 0.0) ($RES_BND_427) (25) [FOR-] (3) ($RES_SIM_451) (25) [----] for $i1 in 1:3 loop (25) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter.port_p.V_m.re - converter_e.singlePhaseElectroMagneticConverter.port_n.V_m.re = converter_e.singlePhaseElectroMagneticConverter[$i1].V_m.re ($RES_SIM_452) (25) [----] end for; (26) [SCAL] (1) converter_e.plug_p.pin[2].i + loss_e.plug_p.pin[2].i + powerb_e.nc.pin[2].i = 0.0 ($RES_SIM_210) (27) [FOR-] (3) ($RES_SIM_453) (27) [----] for $i1 in 1:3 loop (27) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter.port_p.V_m.im - converter_e.singlePhaseElectroMagneticConverter.port_n.V_m.im = converter_e.singlePhaseElectroMagneticConverter[$i1].V_m.im ($RES_SIM_454) (27) [----] end for; (28) [SCAL] (1) converter_e.plug_p.pin[1].i + loss_e.plug_p.pin[1].i + powerb_e.nc.pin[1].i = 0.0 ($RES_SIM_211) (29) [SCAL] (1) loss_e.plug_p.pin[3].v = powerb_e.nc.pin[3].v ($RES_SIM_212) (30) [FOR-] (3) ($RES_SIM_455) (30) [----] for $i1 in 1:3 loop (30) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].V_m.re = 0.6366197723675814 * converter_e.singlePhaseElectroMagneticConverter.N.re * converter_e.singlePhaseElectroMagneticConverter[$i1].i ($RES_SIM_456) (30) [----] end for; (31) [SCAL] (1) loss_e.plug_p.pin[3].v = converter_e.plug_p.pin[3].v ($RES_SIM_213) (32) [SCAL] (1) loss_e.plug_p.pin[2].v = powerb_e.nc.pin[2].v ($RES_SIM_214) (33) [FOR-] (3) ($RES_SIM_457) (33) [----] for $i1 in 1:3 loop (33) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].V_m.im = 0.6366197723675814 * converter_e.singlePhaseElectroMagneticConverter.N.im * converter_e.singlePhaseElectroMagneticConverter[$i1].i ($RES_SIM_458) (33) [----] end for; (34) [SCAL] (1) loss_e.plug_p.pin[2].v = converter_e.plug_p.pin[2].v ($RES_SIM_215) (35) [SCAL] (1) powerb_e.sum.y = powerb_e.sum.k * powerb_e.sum.u ($RES_SIM_17) (36) [FOR-] (3) ($RES_SIM_131) (36) [----] for $i1 in 1:3 loop (36) [----] [SCAL] (1) resistor_e.resistor[$i1].v = resistor_e.resistor[$i1].R_actual * resistor_e.resistor[$i1].i ($RES_SIM_132) (36) [----] end for; (37) [SCAL] (1) loss_e.plug_p.pin[1].v = powerb_e.nc.pin[1].v ($RES_SIM_216) (38) [FOR-] (3) ($RES_SIM_91) (38) [----] for $i1 in 1:3 loop (38) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].i = converter_e.singlePhaseElectroMagneticConverter[$i1].pin_p.i ($RES_SIM_92) (38) [----] end for; (39) [FOR-] (3) ($RES_SIM_18) (39) [----] for $i1 in 1:3 loop (39) [----] [SCAL] (1) powerb_e.product[$i1].y = powerb_e.product[$i1].u1 * powerb_e.product[$i1].u2 ($RES_SIM_19) (39) [----] end for; (40) [SCAL] (1) loss_e.plug_p.pin[1].v = converter_e.plug_p.pin[1].v ($RES_SIM_217) (41) [FOR-] (3) ($RES_SIM_376) (41) [----] for $i1 in 1:3 loop (41) [----] [SCAL] (1) resistor_e.resistor[$i1].n.i - resistor_e.plug_n.pin[$i1].i = 0.0 ($RES_SIM_377) (41) [----] end for; (42) [SCAL] (1) powerb_e.pv.pin[3].i + powerb_e.pc.pin[3].i + resistor_e.plug_n.pin[3].i = 0.0 ($RES_SIM_218) (43) [FOR-] (3) ($RES_SIM_93) (43) [----] for $i1 in 1:3 loop (43) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].v = converter_e.singlePhaseElectroMagneticConverter[$i1].pin_p.v - converter_e.singlePhaseElectroMagneticConverter[$i1].pin_n.v ($RES_SIM_94) (43) [----] end for; (44) [FOR-] (3) ($RES_SIM_133) (44) [----] for $i1 in 1:3 loop (44) [----] [SCAL] (1) resistor_e.resistor[$i1].R_actual = resistor_e.resistor[$i1].R * (1.0 + resistor_e.resistor[$i1].alpha * (resistor_e.resistor[$i1].T_heatPort - resistor_e.resistor[$i1].T_ref)) ($RES_SIM_134) (44) [----] end for; (45) [SCAL] (1) powerb_e.pv.pin[2].i + powerb_e.pc.pin[2].i + resistor_e.plug_n.pin[2].i = 0.0 ($RES_SIM_219) (46) [ARRY] (3) resistor_e.resistor.n.v = resistor_e.plug_n.pin.v ($RES_SIM_378) (47) [FOR-] (3) ($RES_SIM_379) (47) [----] for $i1 in 1:3 loop (47) [----] [SCAL] (1) resistor_e.resistor[$i1].p.i - resistor_e.plug_p.pin[$i1].i = 0.0 ($RES_SIM_380) (47) [----] end for; (48) [FOR-] (6) ($RES_SIM_99) (48) [----] for $i1 in 1:3 loop (48) [----] [RECD] (2) converter_e.singlePhaseElectroMagneticConverter[$i1].port_p.Phi = converter_e.singlePhaseElectroMagneticConverter[$i1].Phi ($RES_SIM_100) (48) [----] end for; (49) [RECD] (2) converter_e.Phi = converter_e.port_p.Phi ($RES_BND_437) (50) [FOR-] (3) ($RES_SIM_20) (50) [----] for $i1 in 1:3 loop (50) [----] [SCAL] (1) powerb_e.currentSensor.currentSensor[$i1].n.i = -powerb_e.currentSensor.currentSensor[$i1].i ($RES_SIM_21) (50) [----] end for; (51) [SCAL] (1) powerb_e.pv.pin[1].i + powerb_e.pc.pin[1].i + resistor_e.plug_n.pin[1].i = 0.0 ($RES_SIM_220) (52) [FOR-] (3) ($RES_SIM_22) (52) [----] for $i1 in 1:3 loop (52) [----] [SCAL] (1) powerb_e.currentSensor.currentSensor[$i1].p.i = powerb_e.currentSensor.currentSensor[$i1].i ($RES_SIM_23) (52) [----] end for; (53) [SCAL] (1) powerb_e.pv.pin[3].v = resistor_e.plug_n.pin[3].v ($RES_SIM_221) (54) [ARRY] (3) powerb_e.product.y = powerb_e.sum.u ($RES_SIM_307) (55) [SCAL] (1) powerb_e.pv.pin[3].v = powerb_e.pc.pin[3].v ($RES_SIM_222) (56) [FOR-] (3) ($RES_SIM_24) (56) [----] for $i1 in 1:3 loop (56) [----] [SCAL] (1) powerb_e.currentSensor.currentSensor[$i1].p.v = powerb_e.currentSensor.currentSensor[$i1].n.v ($RES_SIM_25) (56) [----] end for; (57) [ARRY] (3) resistor_e.resistor.p.v = resistor_e.plug_p.pin.v ($RES_SIM_381) (58) [ARRY] (3) powerb_e.currentSensor.i = powerb_e.product.u2 ($RES_SIM_308) (59) [SCAL] (1) powerb_e.pv.pin[2].v = resistor_e.plug_n.pin[2].v ($RES_SIM_223) (60) [ARRY] (3) powerb_e.voltageSensor.v = powerb_e.product.u1 ($RES_SIM_309) (61) [SCAL] (1) powerb_e.pv.pin[2].v = powerb_e.pc.pin[2].v ($RES_SIM_224) (62) [FOR-] (3) ($RES_SIM_26) (62) [----] for $i1 in 1:3 loop (62) [----] [SCAL] (1) powerb_e.voltageSensor.voltageSensor[$i1].v = powerb_e.voltageSensor.voltageSensor[$i1].p.v - powerb_e.voltageSensor.voltageSensor[$i1].n.v ($RES_SIM_27) (62) [----] end for; (63) [SCAL] (1) powerb_e.pv.pin[1].v = resistor_e.plug_n.pin[1].v ($RES_SIM_225) (64) [SCAL] (1) powerb_e.pv.pin[1].v = powerb_e.pc.pin[1].v ($RES_SIM_226) (65) [FOR-] (3) ($RES_SIM_28) (65) [----] for $i1 in 1:3 loop (65) [----] [SCAL] (1) powerb_e.voltageSensor.voltageSensor[$i1].n.i = 0.0 ($RES_SIM_29) (65) [----] end for; (66) [FOR-] (3) ($RES_SIM_388) (66) [----] for $i1 in 1:3 loop (66) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].n.i - sineVoltage_e.plug_n.pin[$i1].i = 0.0 ($RES_SIM_389) (66) [----] end for; (67) [ARRY] (3) sineVoltage_e.i = sineVoltage_e.plug_p.pin.i ($RES_SIM_149) (68) [FOR-] (3) ($RES_SIM_310) (68) [----] for $i1 in 1:3 loop (68) [----] [SCAL] (1) powerb_e.voltageSensor.plug_n.pin[$i1].i - powerb_e.nv.pin[$i1].i = 0.0 ($RES_SIM_311) (68) [----] end for; (69) [ARRY] (3) powerb_e.voltageSensor.plug_n.pin.v = powerb_e.nv.pin.v ($RES_SIM_312) (70) [FOR-] (3) ($RES_SIM_313) (70) [----] for $i1 in 1:3 loop (70) [----] [SCAL] (1) powerb_e.voltageSensor.plug_p.pin[$i1].i - powerb_e.pv.pin[$i1].i = 0.0 ($RES_SIM_314) (70) [----] end for; (71) [FOR-] (3) ($RES_SIM_30) (71) [----] for $i1 in 1:3 loop (71) [----] [SCAL] (1) powerb_e.voltageSensor.voltageSensor[$i1].p.i = 0.0 ($RES_SIM_31) (71) [----] end for; (72) [SCAL] (1) reluctance_e.V_m.re = reluctance_e.port_p.V_m.re - reluctance_e.port_n.V_m.re ($RES_SIM_471) (73) [SCAL] (1) reluctance_e.V_m.im = reluctance_e.port_p.V_m.im - reluctance_e.port_n.V_m.im ($RES_SIM_472) (74) [ARRY] (3) powerb_e.voltageSensor.plug_p.pin.v = powerb_e.pv.pin.v ($RES_SIM_315) (75) [FOR-] (3) ($RES_SIM_230) (75) [----] for $i1 in 1:3 loop (75) [----] [SCAL] (1) resistor_e.plug_p.pin[$i1].i + sineVoltage_e.plug_p.pin[$i1].i = 0.0 ($RES_SIM_231) (75) [----] end for; (76) [SCAL] (1) reluctance_e.port_p.Phi.re + reluctance_e.port_n.Phi.re = 0.0 ($RES_SIM_473) (77) [FOR-] (3) ($RES_SIM_316) (77) [----] for $i1 in 1:3 loop (77) [----] [SCAL] (1) powerb_e.currentSensor.plug_n.pin[$i1].i - powerb_e.nc.pin[$i1].i = 0.0 ($RES_SIM_317) (77) [----] end for; (78) [SCAL] (1) reluctance_e.port_p.Phi.im + reluctance_e.port_n.Phi.im = 0.0 ($RES_SIM_474) (79) [ARRY] (3) sineVoltage_e.sineVoltage.n.v = sineVoltage_e.plug_n.pin.v ($RES_SIM_390) (80) [ARRY] (3) resistor_e.plug_p.pin.v = sineVoltage_e.plug_p.pin.v ($RES_SIM_232) (81) [FOR-] (3) ($RES_SIM_391) (81) [----] for $i1 in 1:3 loop (81) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].p.i - sineVoltage_e.plug_p.pin[$i1].i = 0.0 ($RES_SIM_392) (81) [----] end for; (82) [ARRY] (3) powerb_e.currentSensor.plug_n.pin.v = powerb_e.nc.pin.v ($RES_SIM_318) (83) [FOR-] (3) ($RES_SIM_319) (83) [----] for $i1 in 1:3 loop (83) [----] [SCAL] (1) powerb_e.currentSensor.plug_p.pin[$i1].i - powerb_e.pc.pin[$i1].i = 0.0 ($RES_SIM_320) (83) [----] end for; (84) [ARRY] (3) sineVoltage_e.sineVoltage.p.v = sineVoltage_e.plug_p.pin.v ($RES_SIM_393) (85) [ARRY] (3) sineVoltage_e.v = sineVoltage_e.plug_p.pin.v - sineVoltage_e.plug_n.pin.v ($RES_SIM_150) (86) [FOR-] (3) ($RES_SIM_151) (86) [----] for $i1 in 1:3 loop (86) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].i = sineVoltage_e.sineVoltage[$i1].p.i ($RES_SIM_152) (86) [----] end for; (87) [SCAL] (1) mground_e.port_p.V_m.re = 0.0 ($RES_SIM_479) (88) [ARRY] (3) loss_e.i = loss_e.plug_p.pin.i ($RES_SIM_39) (89) [FOR-] (3) ($RES_SIM_153) (89) [----] for $i1 in 1:3 loop (89) [----] [SCAL] (1) 0.0 = sineVoltage_e.sineVoltage[$i1].p.i + sineVoltage_e.sineVoltage[$i1].n.i ($RES_SIM_154) (89) [----] end for; (90) [FOR-] (3) ($RES_SIM_155) (90) [----] for $i1 in 1:3 loop (90) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].v = sineVoltage_e.sineVoltage[$i1].p.v - sineVoltage_e.sineVoltage[$i1].n.v ($RES_SIM_156) (90) [----] end for; (91) [FOR-] (3) ($RES_SIM_157) (91) [----] for $i1 in 1:3 loop (91) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].v = sineVoltage_e.sineVoltage[$i1].signalSource.y ($RES_SIM_158) (91) [----] end for; (92) [FOR-] (3) ($RES_SIM_159) (92) [----] for $i1 in 1:3 loop (92) [----] [SCAL] (1) sineVoltage_e.sineVoltage[$i1].signalSource.y = sineVoltage_e.sineVoltage[$i1].signalSource.offset + (if $SEV_4[$i1] then 0.0 else sineVoltage_e.sineVoltage[$i1].signalSource.amplitude * $FUN_3[$i1]) ($RES_SIM_160) (92) [----] end for; (93) [ARRY] (3) powerb_e.pc.pin.v = powerb_e.currentSensor.plug_p.pin.v ($RES_SIM_321) (94) [ARRY] (3) powerb_e.currentSensor.currentSensor.i = powerb_e.currentSensor.i ($RES_SIM_322) (95) [SCAL] (1) mground_e.port_p.V_m.im = 0.0 ($RES_SIM_480) (96) [FOR-] (3) ($RES_SIM_323) (96) [----] for $i1 in 1:3 loop (96) [----] [SCAL] (1) powerb_e.currentSensor.currentSensor[$i1].n.i - powerb_e.currentSensor.plug_n.pin[$i1].i = 0.0 ($RES_SIM_324) (96) [----] end for; (97) [ARRY] (3) loss_e.v = loss_e.plug_p.pin.v - loss_e.plug_n.pin.v ($RES_SIM_40) (98) [FOR-] (3) ($RES_SIM_41) (98) [----] for $i1 in 1:3 loop (98) [----] [SCAL] (1) loss_e.conductor[$i1].i = loss_e.conductor[$i1].p.i ($RES_SIM_42) (98) [----] end for; (99) [ARRY] (3) powerb_e.currentSensor.currentSensor.n.v = powerb_e.currentSensor.plug_n.pin.v ($RES_SIM_325) (100) [FOR-] (3) ($RES_SIM_326) (100) [----] for $i1 in 1:3 loop (100) [----] [SCAL] (1) powerb_e.currentSensor.currentSensor[$i1].p.i - powerb_e.currentSensor.plug_p.pin[$i1].i = 0.0 ($RES_SIM_327) (100) [----] end for; (101) [SCAL] (1) converter_e.port_n.V_m.im = reluctance_e.port_n.V_m.im ($RES_SIM_241) (102) [FOR-] (3) ($RES_SIM_43) (102) [----] for $i1 in 1:3 loop (102) [----] [SCAL] (1) 0.0 = loss_e.conductor[$i1].p.i + loss_e.conductor[$i1].n.i ($RES_SIM_44) (102) [----] end for; (103) [SCAL] (1) converter_e.port_n.V_m.im = mground_e.port_p.V_m.im ($RES_SIM_242) (104) [ARRY] (3) powerb_e.currentSensor.plug_p.pin.v = powerb_e.currentSensor.currentSensor.p.v ($RES_SIM_328) (105) [SCAL] (1) converter_e.port_n.V_m.re = reluctance_e.port_n.V_m.re ($RES_SIM_243) (106) [FOR-] (3) ($RES_SIM_45) (106) [----] for $i1 in 1:3 loop (106) [----] [SCAL] (1) loss_e.conductor[$i1].v = loss_e.conductor[$i1].p.v - loss_e.conductor[$i1].n.v ($RES_SIM_46) (106) [----] end for; (107) [ARRY] (3) powerb_e.voltageSensor.voltageSensor.v = powerb_e.voltageSensor.v ($RES_SIM_329) (108) [SCAL] (1) converter_e.port_n.V_m.re = mground_e.port_p.V_m.re ($RES_SIM_244) (109) [SCAL] (1) converter_e.port_p.V_m.im = reluctance_e.port_p.V_m.im ($RES_SIM_245) (110) [FOR-] (3) ($RES_SIM_47) (110) [----] for $i1 in 1:3 loop (110) [----] [SCAL] (1) loss_e.conductor[$i1].T_heatPort = loss_e.conductor[$i1].T ($RES_SIM_48) (110) [----] end for; (111) [SCAL] (1) converter_e.port_p.V_m.re = reluctance_e.port_p.V_m.re ($RES_SIM_246) (112) [SCAL] (1) converter_e.V_m.re = converter_e.port_p.V_m.re - converter_e.port_n.V_m.re ($RES_SIM_489) (113) [FOR-] (3) ($RES_SIM_49) (113) [----] for $i1 in 1:3 loop (113) [----] [SCAL] (1) loss_e.conductor[$i1].LossPower = loss_e.conductor[$i1].v * loss_e.conductor[$i1].i ($RES_SIM_50) (113) [----] end for; (114) [FOR-] (3) ($RES_SIM_165) (114) [----] for $i1 in 1:3 loop (114) [----] [SCAL] (1) star_e.plug_p.pin[$i1].v = 0.0 ($RES_SIM_166) (114) [----] end for; (115) [FOR-] (3) ($RES_EVT_495) (115) [----] for $i1 in 1:3 loop (115) [----] [SCAL] (1) $SEV_0[$i1] = 1.0 + loss_e.conductor[$i1].alpha * (loss_e.conductor[$i1].T_heatPort - loss_e.conductor[$i1].T_ref) >= 1e-15 ($RES_EVT_496) (115) [----] end for; (116) [FOR-] (3) ($RES_EVT_499) (116) [----] for $i1 in 1:3 loop (116) [----] [SCAL] (1) $SEV_2[$i1] = 1.0 + resistor_e.resistor[$i1].alpha * (resistor_e.resistor[$i1].T_heatPort - resistor_e.resistor[$i1].T_ref) >= 1e-15 ($RES_EVT_500) (116) [----] end for; (117) [FOR-] (3) ($RES_SIM_330) (117) [----] for $i1 in 1:3 loop (117) [----] [SCAL] (1) powerb_e.voltageSensor.voltageSensor[$i1].p.i - powerb_e.voltageSensor.plug_p.pin[$i1].i = 0.0 ($RES_SIM_331) (117) [----] end for; (118) [ARRY] (3) powerb_e.voltageSensor.voltageSensor.p.v = powerb_e.voltageSensor.plug_p.pin.v ($RES_SIM_332) (119) [SCAL] (1) converter_e.V_m.im = converter_e.port_p.V_m.im - converter_e.port_n.V_m.im ($RES_SIM_490) (120) [FOR-] (3) ($RES_SIM_333) (120) [----] for $i1 in 1:3 loop (120) [----] [SCAL] (1) powerb_e.voltageSensor.voltageSensor[$i1].n.i - powerb_e.voltageSensor.plug_n.pin[$i1].i = 0.0 ($RES_SIM_334) (120) [----] end for; (121) [FOR-] (3) ($RES_SIM_51) (121) [----] for $i1 in 1:3 loop (121) [----] [SCAL] (1) loss_e.conductor[$i1].i = loss_e.conductor[$i1].G_actual * loss_e.conductor[$i1].v ($RES_SIM_52) (121) [----] end for; (122) [ARRY] (3) powerb_e.voltageSensor.voltageSensor.n.v = powerb_e.voltageSensor.plug_n.pin.v ($RES_SIM_335) (123) [FOR-] (3) ($RES_SIM_336) (123) [----] for $i1 in 1:3 loop (123) [----] [SCAL] (1) loss_e.conductor[$i1].n.i - loss_e.plug_n.pin[$i1].i = 0.0 ($RES_SIM_337) (123) [----] end for; (124) [FOR-] (3) ($RES_SIM_53) (124) [----] for $i1 in 1:3 loop (124) [----] [SCAL] (1) loss_e.conductor[$i1].G_actual = loss_e.conductor[$i1].G / (1.0 + loss_e.conductor[$i1].alpha * (loss_e.conductor[$i1].T_heatPort - loss_e.conductor[$i1].T_ref)) ($RES_SIM_54) (124) [----] end for; (125) [ARRY] (3) loss_e.plug_n.pin.v = loss_e.conductor.n.v ($RES_SIM_338) (126) [FOR-] (3) ($RES_SIM_339) (126) [----] for $i1 in 1:3 loop (126) [----] [SCAL] (1) loss_e.conductor[$i1].p.i - loss_e.plug_p.pin[$i1].i = 0.0 ($RES_SIM_340) (126) [----] end for; (127) [FOR-] (3) ($RES_EVT_503) (127) [----] for $i1 in 1:3 loop (127) [----] [SCAL] (1) $SEV_4[$i1] = time < sineVoltage_e.sineVoltage[$i1].signalSource.startTime ($RES_EVT_504) (127) [----] end for; (128) [SCAL] (1) reluctance_e.port_n.Phi.im + mground_e.port_p.Phi.im + converter_e.port_n.Phi.im = 0.0 ($RES_SIM_173) (129) [SCAL] (1) reluctance_e.port_n.Phi.re + mground_e.port_p.Phi.re + converter_e.port_n.Phi.re = 0.0 ($RES_SIM_174) (130) [ARRY] (3) loss_e.plug_p.pin.v = loss_e.conductor.p.v ($RES_SIM_341) (131) [ARRY] (3) converter_e.v = converter_e.plug_p.pin.v - converter_e.plug_n.pin.v ($RES_BND_396) (132) [SCAL] (1) star_e.plug_p.pin[3].i + powerb_e.nv.pin[3].i + loss_e.plug_n.pin[3].i + sineVoltage_e.plug_n.pin[3].i + converter_e.plug_n.pin[3].i = 0.0 ($RES_SIM_261) (133) [ARRY] (3) converter_e.i = converter_e.plug_p.pin.i ($RES_BND_397) (134) [SCAL] (1) star_e.plug_p.pin[2].i + powerb_e.nv.pin[2].i + loss_e.plug_n.pin[2].i + sineVoltage_e.plug_n.pin[2].i + converter_e.plug_n.pin[2].i = 0.0 ($RES_SIM_262) (135) [SCAL] (1) converter_e.abs_V_m = (converter_e.V_m.re ^ 2.0 + converter_e.V_m.im ^ 2.0) ^ 0.5 ($RES_BND_398) (136) [SCAL] (1) star_e.plug_p.pin[1].i + powerb_e.nv.pin[1].i + loss_e.plug_n.pin[1].i + sineVoltage_e.plug_n.pin[1].i + converter_e.plug_n.pin[1].i = 0.0 ($RES_SIM_263) (137) [RECD] (2) reluctance_e.port_p.Phi = reluctance_e.Phi ($RES_SIM_65) (138) [SCAL] (1) converter_e.arg_V_m = Modelica.Math.atan3(converter_e.V_m.im, converter_e.V_m.re, 0.0) ($RES_BND_399) (139) [SCAL] (1) loss_e.plug_n.pin[3].v = converter_e.plug_n.pin[3].v ($RES_SIM_264) (140) [SCAL] (1) loss_e.plug_n.pin[3].v = star_e.plug_p.pin[3].v ($RES_SIM_265) (141) [SCAL] (1) 1.5707963267948966 * reluctance_e.V_m.im = reluctance_e.R_m.q * reluctance_e.Phi.im ($RES_SIM_67) (142) [SCAL] (1) loss_e.plug_n.pin[3].v = powerb_e.nv.pin[3].v ($RES_SIM_266) (143) [SCAL] (1) 1.5707963267948966 * reluctance_e.V_m.re = reluctance_e.R_m.d * reluctance_e.Phi.re ($RES_SIM_68) (144) [SCAL] (1) loss_e.plug_n.pin[3].v = sineVoltage_e.plug_n.pin[3].v ($RES_SIM_267) (145) [SCAL] (1) loss_e.plug_n.pin[2].v = converter_e.plug_n.pin[2].v ($RES_SIM_268) (146) [SCAL] (1) loss_e.plug_n.pin[2].v = star_e.plug_p.pin[2].v ($RES_SIM_269) (147) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_p.Phi.im - converter_e.port_p.Phi.im = 0.0 ($RES_SIM_185) (148) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_p.Phi.re - converter_e.port_p.Phi.re = 0.0 ($RES_SIM_186) (149) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_n.Phi.im - converter_e.port_n.Phi.im = 0.0 ($RES_SIM_187) (150) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_p.Phi.im + converter_e.singlePhaseElectroMagneticConverter[2].port_n.Phi.im = 0.0 ($RES_SIM_188) (151) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[2].port_p.Phi.im + converter_e.singlePhaseElectroMagneticConverter[1].port_n.Phi.im = 0.0 ($RES_SIM_189) (152) [SCAL] (1) converter_e.abs_Phi = (converter_e.Phi.re ^ 2.0 + converter_e.Phi.im ^ 2.0) ^ 0.5 ($RES_BND_400) (153) [SCAL] (1) converter_e.arg_Phi = Modelica.Math.atan3(converter_e.Phi.im, converter_e.Phi.re, 0.0) ($RES_BND_401) (154) [FOR-] (3) ($RES_BND_402) (154) [----] for $i1 in 1:3 loop (154) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].arg_Phi = Modelica.Math.atan3(converter_e.singlePhaseElectroMagneticConverter.Phi.im, converter_e.singlePhaseElectroMagneticConverter.Phi.re, 0.0) ($RES_BND_403) (154) [----] end for; (155) [FOR-] (3) ($RES_BND_404) (155) [----] for $i1 in 1:3 loop (155) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].abs_Phi = (converter_e.singlePhaseElectroMagneticConverter.Phi.re ^ 2.0 + converter_e.singlePhaseElectroMagneticConverter.Phi.im ^ 2.0) ^ 0.5 ($RES_BND_405) (155) [----] end for; (156) [FOR-] (3) ($RES_BND_406) (156) [----] for $i1 in 1:3 loop (156) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].arg_V_m = Modelica.Math.atan3(converter_e.singlePhaseElectroMagneticConverter.V_m.im, converter_e.singlePhaseElectroMagneticConverter.V_m.re, 0.0) ($RES_BND_407) (156) [----] end for; (157) [FOR-] (3) ($RES_BND_408) (157) [----] for $i1 in 1:3 loop (157) [----] [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[$i1].abs_V_m = (converter_e.singlePhaseElectroMagneticConverter.V_m.re ^ 2.0 + converter_e.singlePhaseElectroMagneticConverter.V_m.im ^ 2.0) ^ 0.5 ($RES_BND_409) (157) [----] end for; (158) [SCAL] (1) loss_e.plug_n.pin[2].v = powerb_e.nv.pin[2].v ($RES_SIM_270) (159) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_n.V_m.im = converter_e.port_n.V_m.im ($RES_SIM_356) (160) [SCAL] (1) loss_e.plug_n.pin[2].v = sineVoltage_e.plug_n.pin[2].v ($RES_SIM_271) (161) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_n.V_m.re = converter_e.port_n.V_m.re ($RES_SIM_357) (162) [SCAL] (1) loss_e.plug_n.pin[1].v = converter_e.plug_n.pin[1].v ($RES_SIM_272) (163) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[2].port_n.V_m.im = converter_e.singlePhaseElectroMagneticConverter[3].port_p.V_m.im ($RES_SIM_358) (164) [SCAL] (1) loss_e.plug_n.pin[1].v = star_e.plug_p.pin[1].v ($RES_SIM_273) (165) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[2].port_n.V_m.re = converter_e.singlePhaseElectroMagneticConverter[3].port_p.V_m.re ($RES_SIM_359) (166) [SCAL] (1) loss_e.plug_n.pin[1].v = powerb_e.nv.pin[1].v ($RES_SIM_274) (167) [SCAL] (1) loss_e.plug_n.pin[1].v = sineVoltage_e.plug_n.pin[1].v ($RES_SIM_275) (168) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_n.Phi.re - converter_e.port_n.Phi.re = 0.0 ($RES_SIM_190) (169) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[3].port_p.Phi.re + converter_e.singlePhaseElectroMagneticConverter[2].port_n.Phi.re = 0.0 ($RES_SIM_191) (170) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[2].port_p.Phi.re + converter_e.singlePhaseElectroMagneticConverter[1].port_n.Phi.re = 0.0 ($RES_SIM_192) (171) [ARRY] (3) resistor_e.i = resistor_e.plug_p.pin.i ($RES_SIM_119) (172) [SCAL] (1) reluctance_e.port_p.Phi.im + converter_e.port_p.Phi.im = 0.0 ($RES_SIM_193) (173) [SCAL] (1) reluctance_e.port_p.Phi.re + converter_e.port_p.Phi.re = 0.0 ($RES_SIM_194) (174) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_n.V_m.im = converter_e.singlePhaseElectroMagneticConverter[2].port_p.V_m.im ($RES_SIM_360) (175) [SCAL] (1) converter_e.singlePhaseElectroMagneticConverter[1].port_n.V_m.re = converter_e.singlePhaseElectroMagneticConverter[2].port_p.V_m.re ($RES_SIM_361)