Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr Buildings_3.0.0_Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.conf.json loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica_StateGraph2 2.0.2/package.mo", uses=false) 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) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Buildings 3.0.0/package.mo", uses=false) Using package Buildings with version 3.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Buildings 3.0.0/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 4.0.0 (/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) Using package Modelica_StateGraph2 with version 2.0.2 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica_StateGraph2 2.0.2/package.mo) Running command: translateModel(Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull,tolerance=1e-05,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="Buildings_3.0.0_Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull") translateModel(Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull,tolerance=1e-05,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="Buildings_3.0.0_Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull") [/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica_StateGraph2 2.0.2/package.mo:257:38-257:110:writable] Warning: The file was not encoded in UTF-8: "

An important practical aspect of state machines is the abilit...". Defaulting to 7-bit ASCII with unknown characters replaced by '?'. To change encoding when loading a file: loadFile(encoding="ISO-XXXX-YY"). To change it in a package: add a file package.encoding at the top-level. Note: The Modelica Language Specification only allows files encoded in UTF-8. [/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica_StateGraph2 2.0.2/package.mo:761:36-761:108:writable] Warning: The file was not encoded in UTF-8: "

The Modelica_StateGraph2 library is described in detail in (O...". Defaulting to 7-bit ASCII with unknown characters replaced by '?'. To change encoding when loading a file: loadFile(encoding="ISO-XXXX-YY"). To change it in a package: add a file package.encoding at the top-level. Note: The Modelica Language Specification only allows files encoded in UTF-8. [/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica_StateGraph2 2.0.2/package.mo:1435:36-1435:108:writable] Warning: The file was not encoded in UTF-8: "

Main Authors:

SCode: time 2.432e-05/2.433e-05, allocations: 5.094 kB / 0.5923 GB, free: 18.32 MB / 446.1 MB Notification: Performance of NFInst.instantiate(Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull): time 0.005186/0.005219, allocations: 5.372 MB / 0.5975 GB, free: 13.52 MB / 446.1 MB Notification: Performance of NFInst.instExpressions: time 0.004855/0.01009, allocations: 4.194 MB / 0.6016 GB, free: 9.309 MB / 446.1 MB Notification: Performance of NFInst.updateImplicitVariability: time 0.0003023/0.0104, allocations: 19.88 kB / 0.6016 GB, free: 9.289 MB / 446.1 MB Notification: Performance of NFTyping.typeComponents: time 0.001388/0.01179, allocations: 0.5863 MB / 0.6022 GB, free: 8.703 MB / 446.1 MB Notification: Performance of NFTyping.typeBindings: time 0.001149/0.01295, allocations: 0.6689 MB / 0.6028 GB, free: 8.031 MB / 446.1 MB Notification: Performance of NFTyping.typeClassSections: time 0.001263/0.01422, allocations: 0.5533 MB / 0.6034 GB, free: 7.477 MB / 446.1 MB Notification: Performance of NFFlatten.flatten: time 0.0009143/0.01515, allocations: 1.224 MB / 0.6046 GB, free: 6.246 MB / 446.1 MB Notification: Performance of NFFlatten.resolveConnections: time 0.0005206/0.01568, allocations: 367.9 kB / 0.6049 GB, free: 5.891 MB / 446.1 MB Notification: Performance of NFEvalConstants.evaluate: time 0.0003842/0.01607, allocations: 450.3 kB / 0.6054 GB, free: 5.449 MB / 446.1 MB Notification: Performance of NFSimplifyModel.simplify: time 0.0005208/0.0166, allocations: 466.1 kB / 0.6058 GB, free: 4.992 MB / 446.1 MB Notification: Performance of NFPackage.collectConstants: time 8.363e-05/0.01669, allocations: 52 kB / 0.6059 GB, free: 4.941 MB / 446.1 MB Notification: Performance of NFFlatten.collectFunctions: time 0.00109/0.01779, allocations: 0.7016 MB / 0.6065 GB, free: 4.238 MB / 446.1 MB Notification: Performance of combineBinaries: time 0.0008184/0.01862, allocations: 1.245 MB / 0.6078 GB, free: 2.98 MB / 446.1 MB Notification: Performance of replaceArrayConstructors: time 0.0004276/0.01905, allocations: 0.7746 MB / 0.6085 GB, free: 2.199 MB / 446.1 MB Notification: Performance of NFVerifyModel.verify: time 0.0001099/0.01917, allocations: 107.6 kB / 0.6086 GB, free: 2.094 MB / 446.1 MB Notification: Performance of FrontEnd: time 6.224e-05/0.01924, allocations: 15.94 kB / 0.6086 GB, free: 2.078 MB / 446.1 MB Notification: Model statistics after passing the front-end and creating the data structures used by the back-end: * Number of equations: 179 (126) * Number of variables: 179 (119) Notification: Performance of Bindings: time 0.002785/0.02203, allocations: 3.193 MB / 0.6118 GB, free: 14.75 MB / 462.1 MB Notification: Performance of FunctionAlias: time 0.000221/0.02226, allocations: 167.6 kB / 0.6119 GB, free: 14.59 MB / 462.1 MB Notification: Performance of Early Inline: time 0.005563/0.02783, allocations: 5.363 MB / 0.6171 GB, free: 9.188 MB / 462.1 MB Notification: Performance of simplify1: time 0.000593/0.02844, allocations: 0.5266 MB / 0.6177 GB, free: 8.66 MB / 462.1 MB Notification: Performance of Alias: time 0.002957/0.03141, allocations: 2.794 MB / 0.6204 GB, free: 5.703 MB / 462.1 MB Notification: Performance of simplify2: time 0.0005554/0.03198, allocations: 0.5228 MB / 0.6209 GB, free: 5.18 MB / 462.1 MB Notification: Performance of Events: time 0.001243/0.03323, allocations: 1.04 MB / 0.6219 GB, free: 4.223 MB / 462.1 MB Notification: Performance of Detect States: time 0.001178/0.03442, allocations: 1.118 MB / 0.623 GB, free: 3.09 MB / 462.1 MB Notification: Performance of Partitioning: time 0.001235/0.03567, allocations: 1.198 MB / 0.6242 GB, free: 1.824 MB / 462.1 MB Error: Internal error NBSlice.fillDependencyArray failed because number of flattened indices 1 for dependency load.v[1] could not be divided by the body size 2 without rest. Error: Internal error NBAdjacency.Matrix.createPseudo failed for: [ARRY] (2) load.S = {load.v[1] * (-load.i)[1] + load.v[2] * (-load.i)[2], load.v[2] * (-load.i)[1] - load.v[1] * (-load.i)[2]} ($RES_BND_113) Error: Internal error NBAdjacency.Matrix.create failed to create adjacency matrix for system: System Variables (45/67) ************************** (1) [ALGB] (1) Real[1] tra_load.terminal_n.theta (2) [ALGB] (2) flow Real[2] tra_load.terminal_n.i (3) [ALGB] (1) Real $FUN_2 (4) [ALGB] (1) Real $FUN_1 (5) [ALGB] (2) Real[2] sou.S = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.sou.PhaseSystem.phasePowers_vi(sou.terminal.v, sou.terminal.i) (6) [ALGB] (2) Real[2] tra_load.terminal_p.v (7) [ALGB] (2) protected Real[2] tra_load.P_n = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.tra_load.PhaseSystem_n.phasePowers_vi(tra_load.terminal_n.v, tra_load.terminal_n.i) (8) [ALGB] (2) protected Real[2] tra_load.Z1 = {tra_load.R1 * tra_load.RBaseHigh, (tra_load.L1 * tra_load.omega * tra_load.RBaseHigh) / tra_load.omega_n} (9) [ALGB] (2) protected Real[2] tra_load.Z2 = {tra_load.R2 * tra_load.RBaseLow, (tra_load.L2 * tra_load.omega * tra_load.RBaseLow) / tra_load.omega_n} (10) [ALGB] (2) protected Real[2] tra_load.P_p = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.tra_load.PhaseSystem_p.phasePowers_vi(tra_load.terminal_p.v, tra_load.terminal_p.i) (11) [ALGB] (1) Real tra_load.eta (min = 0.0) (12) [DER-] (1) Real[1] $DER.tra_load.terminal_p.theta (13) [ALGB] (2) flow Real[2] load.terminal.i (14) [ALGB] (2) Real[2] load.S = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.load.PhaseSystem.phasePowers_vi(load.v, -load.i) (15) [ALGB] (1) protected Real load.Q = load.P * tan(acos(load.pf)) (16) [ALGB] (1) Real load.P (17) [ALGB] (2) flow Real[2] tra_load.terminal_p.i (18) [ALGB] (1) Real sou.phi = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.sou.PhaseSystem.phase(sou.terminal.v) - Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.sou.PhaseSystem.phase(-sou.terminal.i) (19) [ALGB] (1) Real[1] sou.terminal.theta (20) [ALGB] (1) Real tra_load.i_n (21) [ALGB] (1) Real tra_load.i_p (22) [ALGB] (1) Real tra_load.v_n (23) [ALGB] (1) Real tra_load.v_p (24) [ALGB] (2) flow Real[2] sou.terminal.i (25) [ALGB] (2) Real[2] load.v = load.terminal.v (start = {120.0, 0.0}) (26) [ALGB] (2) protected Real[2] tra_load.Zlm = {0.0, (10.0 * tra_load.omega * tra_load.RBaseHigh) / tra_load.omega_n} (27) [ALGB] (2) Real[2] tra_load.PLoss (28) [ALGB] (1) protected Real tra_load.S_n = Modelica.Fluid.Utilities.regRoot(tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0, 0.1) (29) [ALGB] (1) protected Real tra_load.S_p = Modelica.Fluid.Utilities.regRoot(tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0, 0.1) (30) [DISC] (1) Boolean $TEV_1 (31) [DISC] (1) Boolean $TEV_0 (32) [ALGB] (2) Real[2] tra_load.terminal_n.v (33) [ALGB] (1) protected Real load.omega (34) [ALGB] (1) protected Real tra_load.omega (35) [ALGB] (2) Real[2] sou.terminal.v (36) [ALGB] (2) Real[2] load.i = load.terminal.i (start = {0.0, 0.0}) (37) [DER-] (1) Real[1] $DER.load.terminal.theta (38) [DISC] (1) Boolean $SEV_11 (39) [ALGB] (2) protected Real[2] tra_load.Zrm = {10.0 * tra_load.RBaseHigh, 0.0} (40) [DISC] (1) Boolean $SEV_10 (41) [ALGB] (2) protected Real[2] tra_load.Im (42) [DISC] (1) Boolean $SEV_9 (43) [ALGB] (2) protected Real[2] tra_load.V1 (start = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.tra_load.PhaseSystem_n.phaseVoltages(tra_load.VHigh, 0.0)) (44) [ALGB] (2) Real[2] load.terminal.v (45) [ALGB] (2) protected Real[2] tra_load.V2 (start = Buildings.Electrical.AC.ThreePhasesBalanced.Conversion.Examples.ACACTransformerFull.tra_load.PhaseSystem_n.phaseVoltages(tra_load.VLow, 0.0)) System Equations (47/67) ************************** (1) [SCAL] (1) sou.phi = atan2(sou.terminal.v[2], sou.terminal.v[1]) - atan2((-sou.terminal.i)[2], (-sou.terminal.i)[1]) ($RES_BND_110) (2) [ARRY] (2) load.v = load.terminal.v ($RES_BND_111) (3) [ARRY] (2) load.i = load.terminal.i ($RES_BND_112) (4) [ARRY] (2) load.S = {load.v[1] * (-load.i)[1] + load.v[2] * (-load.i)[2], load.v[2] * (-load.i)[1] - load.v[1] * (-load.i)[2]} ($RES_BND_113) (5) [SCAL] (1) load.Q = load.P * $FUN_2 ($RES_BND_114) (6) [SCAL] (1) $SEV_10 = ((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) - ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)) < (-0.01) ($RES_EVT_150) (7) [SCAL] (1) $SEV_11 = sqrt(tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) <= 1.01 * tra_load.VABase ($RES_EVT_151) (8) [SCAL] (1) $TEV_0 = time < ramp.startTime ($RES_EVT_138) (9) [ARRY] (2) tra_load.Im = {tra_load.V1[1] * tra_load.Zrm[1] + tra_load.V1[2] * tra_load.Zrm[2], tra_load.V1[2] * tra_load.Zrm[1] - tra_load.V1[1] * tra_load.Zrm[2]} / (tra_load.Zrm[1] ^ 2.0 + tra_load.Zrm[2] ^ 2.0) + {tra_load.V1[1] * tra_load.Zlm[1] + tra_load.V1[2] * tra_load.Zlm[2], tra_load.V1[2] * tra_load.Zlm[1] - tra_load.V1[1] * tra_load.Zlm[2]} / (tra_load.Zlm[1] ^ 2.0 + tra_load.Zlm[2] ^ 2.0) ($RES_SIM_70) (10) [SCAL] (1) $TEV_1 = time < (ramp.startTime + ramp.duration) ($RES_EVT_139) (11) [SCAL] (1) tra_load.terminal_p.i[2] + (tra_load.terminal_n.i[2] - tra_load.Im[2]) * tra_load.N = 0.0 ($RES_SIM_71) (12) [SCAL] (1) load.i[2] = -homotopy((load.v[2] * load.P - load.v[1] * load.Q) / (load.v[1] ^ 2.0 + load.v[2] ^ 2.0), 0.0) ($RES_SIM_56) (13) [SCAL] (1) tra_load.terminal_p.i[1] + (tra_load.terminal_n.i[1] - tra_load.Im[1]) * tra_load.N = 0.0 ($RES_SIM_72) (14) [SCAL] (1) load.i[1] = -homotopy((load.v[2] * load.Q + load.v[1] * load.P) / (load.v[1] ^ 2.0 + load.v[2] ^ 2.0), 0.0) ($RES_SIM_57) (15) [ARRY] (2) tra_load.V2 = tra_load.V1 / tra_load.N ($RES_SIM_73) (16) [SCAL] (1) load.omega = $DER.load.terminal.theta[1] ($RES_SIM_58) (17) [SCAL] (1) tra_load.eta = smooth(1, if $SEV_9 then ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)) else if $SEV_10 then ((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) else 0.25 * (((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) - ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0))) * ((-3.0) + (((((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25 * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)) / ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25) - (((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25 * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) / ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25)) / 0.01) ^ 2.0) * (100.0 * (((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) - ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)))) + 0.5 * (((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)) + ((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)))) ($RES_SIM_74) (18) [ARRY] (2) sou.terminal.v = {sou.V * cos(sou.phiSou), sou.V * sin(sou.phiSou)} ($RES_SIM_59) (19) [SCAL] (1) tra_load.omega = $DER.tra_load.terminal_p.theta[1] ($RES_SIM_75) (20) [FOR-] (2) ($RES_SIM_92) (20) [----] for $i1 in 1:2 loop (20) [----] [SCAL] (1) tra_load.terminal_p.i[$i1] + load.terminal.i[$i1] = 0.0 ($RES_SIM_93) (20) [----] end for; (21) [ARRY] (2) tra_load.terminal_p.v = load.terminal.v ($RES_SIM_94) (22) [ARRY] (1) tra_load.terminal_p.theta = load.terminal.theta ($RES_SIM_95) (23) [FOR-] (2) ($RES_SIM_96) (23) [----] for $i1 in 1:2 loop (23) [----] [SCAL] (1) sou.terminal.i[$i1] + tra_load.terminal_n.i[$i1] = 0.0 ($RES_SIM_97) (23) [----] end for; (24) [ARRY] (2) sou.terminal.v = tra_load.terminal_n.v ($RES_SIM_98) (25) [ARRY] (1) sou.terminal.theta = tra_load.terminal_n.theta ($RES_SIM_99) (26) [ARRY] (2) tra_load.Z1 = {tra_load.R1 * tra_load.RBaseHigh, (tra_load.L1 * tra_load.omega * tra_load.RBaseHigh) / tra_load.omega_n} ($RES_BND_101) (27) [ARRY] (2) tra_load.Z2 = {tra_load.R2 * tra_load.RBaseLow, (tra_load.L2 * tra_load.omega * tra_load.RBaseLow) / tra_load.omega_n} ($RES_BND_102) (28) [ARRY] (2) tra_load.Zrm = {10.0 * tra_load.RBaseHigh, 0.0} ($RES_BND_103) (29) [ARRY] (2) tra_load.Zlm = {0.0, (10.0 * tra_load.omega * tra_load.RBaseHigh) / tra_load.omega_n} ($RES_BND_104) (30) [SCAL] (1) $FUN_1 = acos(load.pf) ($RES_$AUX_137) (31) [ARRY] (2) tra_load.P_p = {tra_load.terminal_p.v[1] * tra_load.terminal_p.i[1] + tra_load.terminal_p.v[2] * tra_load.terminal_p.i[2], tra_load.terminal_p.v[2] * tra_load.terminal_p.i[1] - tra_load.terminal_p.v[1] * tra_load.terminal_p.i[2]} ($RES_BND_105) (32) [SCAL] (1) $FUN_2 = tan($FUN_1) ($RES_$AUX_136) (33) [ARRY] (2) tra_load.P_n = {tra_load.terminal_n.v[1] * tra_load.terminal_n.i[1] + tra_load.terminal_n.v[2] * tra_load.terminal_n.i[2], tra_load.terminal_n.v[2] * tra_load.terminal_n.i[1] - tra_load.terminal_n.v[1] * tra_load.terminal_n.i[2]} ($RES_BND_106) (34) [SCAL] (1) tra_load.S_p = (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) / ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 0.010000000000000002) ^ 0.25 ($RES_BND_107) (35) [SCAL] (1) tra_load.S_n = (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) / ((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 0.010000000000000002) ^ 0.25 ($RES_BND_108) (36) [ARRY] (2) sou.S = {sou.terminal.v[1] * sou.terminal.i[1] + sou.terminal.v[2] * sou.terminal.i[2], sou.terminal.v[2] * sou.terminal.i[1] - sou.terminal.v[1] * sou.terminal.i[2]} ($RES_BND_109) (37) [SCAL] (1) sou.terminal.theta[1] = 6.283185307179586 * sou.f * time ($RES_SIM_61) (38) [SCAL] (1) tra_load.v_n = tra_load.terminal_n.v / ((tra_load.terminal_n.v * tra_load.terminal_n.v * (tra_load.terminal_n.v * tra_load.terminal_n.v) + 1.0000000000000002e-10) ^ 0.25 * tra_load.terminal_n.v) ($RES_SIM_62) (39) [SCAL] (1) tra_load.v_p = tra_load.terminal_p.v / ((tra_load.terminal_p.v * tra_load.terminal_p.v * (tra_load.terminal_p.v * tra_load.terminal_p.v) + 1.0000000000000002e-10) ^ 0.25 * tra_load.terminal_p.v) ($RES_SIM_63) (40) [SCAL] (1) load.P = ramp.offset + (if $TEV_0 then 0.0 else if $TEV_1 then (ramp.height * (time - ramp.startTime)) / ramp.duration else ramp.height) ($RES_SIM_48) (41) [SCAL] (1) tra_load.i_n = tra_load.terminal_n.i / ((tra_load.terminal_n.i * tra_load.terminal_n.i * (tra_load.terminal_n.i * tra_load.terminal_n.i) + 1.0000000000000002e-10) ^ 0.25 * tra_load.terminal_n.i) ($RES_SIM_64) (42) [SCAL] (1) tra_load.i_p = tra_load.terminal_p.i / ((tra_load.terminal_p.i * tra_load.terminal_p.i * (tra_load.terminal_p.i * tra_load.terminal_p.i) + 1.0000000000000002e-10) ^ 0.25 * tra_load.terminal_p.i) ($RES_SIM_65) (43) [SCAL] (1) $SEV_9 = ((tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * ((1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * (1e-6 + tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) * (tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0)) - ((tra_load.P_p[2] ^ 2.0 + tra_load.P_p[1] ^ 2.0) * ((1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) * (1e-6 + tra_load.P_n[2] ^ 2.0 + tra_load.P_n[1] ^ 2.0) + 1e-4) ^ 0.25) / (((tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) * (tra_load.P_p[1] ^ 2.0 + tra_load.P_p[2] ^ 2.0) + 1e-4) ^ 0.25 * (1e-6 + tra_load.P_n[1] ^ 2.0 + tra_load.P_n[2] ^ 2.0)) > 0.01 ($RES_EVT_149) (44) [ARRY] (1) tra_load.terminal_p.theta = tra_load.terminal_n.theta ($RES_SIM_66) (45) [ARRY] (2) tra_load.PLoss = tra_load.P_p + tra_load.P_n ($RES_SIM_67) (46) [ARRY] (2) tra_load.terminal_p.v = tra_load.V2 + {tra_load.terminal_p.i[1] * tra_load.Z2[1] - tra_load.terminal_p.i[2] * tra_load.Z2[2], tra_load.terminal_p.i[1] * tra_load.Z2[2] + tra_load.terminal_p.i[2] * tra_load.Z2[1]} ($RES_SIM_68) (47) [ARRY] (2) tra_load.terminal_n.v = tra_load.V1 + {tra_load.terminal_n.i[1] * tra_load.Z1[1] - tra_load.terminal_n.i[2] * tra_load.Z1[2], tra_load.terminal_n.i[1] * tra_load.Z1[2] + tra_load.terminal_n.i[2] * tra_load.Z1[1]} ($RES_SIM_69)