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Failed
tests / 02 testsuite-gcc 2/3 / simulation_modelica_start_value_selection.asmaFlow.mos (from (result.xml))
Stacktrace
Output mismatch (see stdout for details)
Standard Output
+ asmaFlow.mos [BUG: #2429] ... equation mismatch [time: 19]
==== Log /tmp/omc-rtest-unknown/simulation/modelica/start_value_selection/asmaFlow.mos_temp3747/log-asmaFlow.mos
{true}
""
true
""
true
""
Unreplaceable Crefs: (0)
========================================
Replacements: (321)
========================================
const.y -> const.k
torque.tau -> const.k
torque.flange.tau -> -const.k
aimc.flange.phi -> speedSensor.flange.phi
torque.flange.phi -> speedSensor.flange.phi
aimc.strayLoad.flange.phi -> speedSensor.flange.phi
aimc.inertiaRotor.flange_b.phi -> speedSensor.flange.phi
aimc.inertiaRotor.phi -> speedSensor.flange.phi
aimc.inertiaRotor.flange_a.phi -> speedSensor.flange.phi
aimc.airGapS.flange.phi -> speedSensor.flange.phi
aimc.friction.flange.phi -> speedSensor.flange.phi
ground.p.v -> 0.0
star.pin_n.v -> 0.0
star.plug_p.pin[3].v -> 0.0
sinevoltage1.plug_p.pin[3].v -> 0.0
sinevoltage1.sineVoltage[3].p.v -> 0.0
star.plug_p.pin[2].v -> 0.0
sinevoltage1.plug_p.pin[2].v -> 0.0
sinevoltage1.sineVoltage[2].p.v -> 0.0
star.plug_p.pin[1].v -> 0.0
sinevoltage1.plug_p.pin[1].v -> 0.0
sinevoltage1.sineVoltage[1].p.v -> 0.0
terminalBox.plug_sp.pin[3].v -> -sinevoltage1.v[3]
terminalBox.plugSupply.pin[3].v -> -sinevoltage1.v[3]
sinevoltage1.plug_n.pin[3].v -> -sinevoltage1.v[3]
sinevoltage1.sineVoltage[3].n.v -> -sinevoltage1.v[3]
aimc.strayLoad.plug_p.pin[3].v -> -sinevoltage1.v[3]
terminalBox.plug_sp.pin[2].v -> -sinevoltage1.v[2]
terminalBox.plugSupply.pin[2].v -> -sinevoltage1.v[2]
sinevoltage1.plug_n.pin[2].v -> -sinevoltage1.v[2]
sinevoltage1.sineVoltage[2].n.v -> -sinevoltage1.v[2]
aimc.strayLoad.plug_p.pin[2].v -> -sinevoltage1.v[2]
terminalBox.plug_sp.pin[1].v -> -sinevoltage1.v[1]
terminalBox.plugSupply.pin[1].v -> -sinevoltage1.v[1]
sinevoltage1.plug_n.pin[1].v -> -sinevoltage1.v[1]
sinevoltage1.sineVoltage[1].n.v -> -sinevoltage1.v[1]
aimc.strayLoad.plug_p.pin[1].v -> -sinevoltage1.v[1]
terminalBox.plug_sn.pin[3].v -> aimc.plug_sn.pin[3].v
terminalBox.star.plug_p.pin[3].v -> aimc.plug_sn.pin[3].v
terminalBox.star.pin_n.v -> aimc.plug_sn.pin[3].v
terminalBox.starpoint.v -> aimc.plug_sn.pin[3].v
terminalBox.star.plug_p.pin[2].v -> aimc.plug_sn.pin[3].v
terminalBox.plug_sn.pin[2].v -> aimc.plug_sn.pin[3].v
aimc.plug_sn.pin[2].v -> aimc.plug_sn.pin[3].v
aimc.spacePhasorS.plug_n.pin[2].v -> aimc.plug_sn.pin[3].v
terminalBox.star.plug_p.pin[1].v -> aimc.plug_sn.pin[3].v
terminalBox.plug_sn.pin[1].v -> aimc.plug_sn.pin[3].v
aimc.plug_sn.pin[1].v -> aimc.plug_sn.pin[3].v
aimc.spacePhasorS.plug_n.pin[1].v -> aimc.plug_sn.pin[3].v
aimc.spacePhasorS.plug_n.pin[3].v -> aimc.plug_sn.pin[3].v
sinevoltage1.plug_p.pin[1].i -> sinevoltage1.i[1]
sinevoltage1.sineVoltage[1].p.i -> sinevoltage1.i[1]
sinevoltage1.sineVoltage[1].i -> sinevoltage1.i[1]
sinevoltage1.sineVoltage[1].n.i -> -sinevoltage1.i[1]
sinevoltage1.plug_n.pin[1].i -> -sinevoltage1.i[1]
terminalBox.plugSupply.pin[1].i -> sinevoltage1.i[1]
terminalBox.plug_sp.pin[1].i -> -sinevoltage1.i[1]
aimc.plug_sp.pin[1].i -> sinevoltage1.i[1]
aimc.strayLoad.plug_p.pin[1].i -> sinevoltage1.i[1]
aimc.strayLoad.i[1] -> sinevoltage1.i[1]
aimc.strayLoad.plug_n.pin[1].i -> -sinevoltage1.i[1]
aimc.rs.plug_p.pin[1].i -> sinevoltage1.i[1]
aimc.rs.resistor[1].p.i -> sinevoltage1.i[1]
aimc.rs.resistor[1].i -> sinevoltage1.i[1]
aimc.rs.resistor[1].n.i -> -sinevoltage1.i[1]
aimc.rs.plug_n.pin[1].i -> -sinevoltage1.i[1]
aimc.spacePhasorS.plug_p.pin[1].i -> sinevoltage1.i[1]
aimc.spacePhasorS.plug_n.pin[1].i -> -sinevoltage1.i[1]
aimc.plug_sn.pin[1].i -> -sinevoltage1.i[1]
terminalBox.plug_sn.pin[1].i -> sinevoltage1.i[1]
terminalBox.star.plug_p.pin[1].i -> sinevoltage1.i[1]
aimc.rs.i[1] -> sinevoltage1.i[1]
aimc.is[1] -> sinevoltage1.i[1]
star.plug_p.pin[1].i -> -sinevoltage1.i[1]
sinevoltage1.plug_p.pin[2].i -> sinevoltage1.i[2]
sinevoltage1.sineVoltage[2].p.i -> sinevoltage1.i[2]
sinevoltage1.sineVoltage[2].i -> sinevoltage1.i[2]
sinevoltage1.sineVoltage[2].n.i -> -sinevoltage1.i[2]
sinevoltage1.plug_n.pin[2].i -> -sinevoltage1.i[2]
terminalBox.plugSupply.pin[2].i -> sinevoltage1.i[2]
terminalBox.plug_sp.pin[2].i -> -sinevoltage1.i[2]
aimc.plug_sp.pin[2].i -> sinevoltage1.i[2]
aimc.strayLoad.plug_p.pin[2].i -> sinevoltage1.i[2]
aimc.strayLoad.i[2] -> sinevoltage1.i[2]
aimc.strayLoad.plug_n.pin[2].i -> -sinevoltage1.i[2]
aimc.rs.plug_p.pin[2].i -> sinevoltage1.i[2]
aimc.rs.resistor[2].p.i -> sinevoltage1.i[2]
aimc.rs.resistor[2].i -> sinevoltage1.i[2]
aimc.rs.resistor[2].n.i -> -sinevoltage1.i[2]
aimc.rs.plug_n.pin[2].i -> -sinevoltage1.i[2]
aimc.spacePhasorS.plug_p.pin[2].i -> sinevoltage1.i[2]
aimc.spacePhasorS.plug_n.pin[2].i -> -sinevoltage1.i[2]
aimc.plug_sn.pin[2].i -> -sinevoltage1.i[2]
terminalBox.plug_sn.pin[2].i -> sinevoltage1.i[2]
terminalBox.star.plug_p.pin[2].i -> sinevoltage1.i[2]
aimc.rs.i[2] -> sinevoltage1.i[2]
aimc.is[2] -> sinevoltage1.i[2]
star.plug_p.pin[2].i -> -sinevoltage1.i[2]
sinevoltage1.plug_p.pin[3].i -> sinevoltage1.i[3]
sinevoltage1.sineVoltage[3].p.i -> sinevoltage1.i[3]
sinevoltage1.sineVoltage[3].i -> sinevoltage1.i[3]
sinevoltage1.sineVoltage[3].n.i -> -sinevoltage1.i[3]
sinevoltage1.plug_n.pin[3].i -> -sinevoltage1.i[3]
terminalBox.plugSupply.pin[3].i -> sinevoltage1.i[3]
terminalBox.plug_sp.pin[3].i -> -sinevoltage1.i[3]
aimc.plug_sp.pin[3].i -> sinevoltage1.i[3]
aimc.strayLoad.plug_p.pin[3].i -> sinevoltage1.i[3]
aimc.strayLoad.i[3] -> sinevoltage1.i[3]
aimc.strayLoad.plug_n.pin[3].i -> -sinevoltage1.i[3]
aimc.rs.plug_p.pin[3].i -> sinevoltage1.i[3]
aimc.rs.resistor[3].p.i -> sinevoltage1.i[3]
aimc.rs.resistor[3].i -> sinevoltage1.i[3]
aimc.rs.resistor[3].n.i -> -sinevoltage1.i[3]
aimc.rs.plug_n.pin[3].i -> -sinevoltage1.i[3]
aimc.spacePhasorS.plug_p.pin[3].i -> sinevoltage1.i[3]
aimc.spacePhasorS.plug_n.pin[3].i -> -sinevoltage1.i[3]
aimc.plug_sn.pin[3].i -> -sinevoltage1.i[3]
terminalBox.plug_sn.pin[3].i -> sinevoltage1.i[3]
terminalBox.star.plug_p.pin[3].i -> sinevoltage1.i[3]
aimc.rs.i[3] -> sinevoltage1.i[3]
aimc.is[3] -> sinevoltage1.i[3]
star.plug_p.pin[3].i -> -sinevoltage1.i[3]
star.pin_n.i -> -ground.p.i
aimc.statorCore.spacePhasor.v_[2] -> aimc.lssigma.spacePhasor_a.v_[2]
aimc.spacePhasorS.spacePhasor.v_[2] -> aimc.lssigma.spacePhasor_a.v_[2]
aimc.statorCore.spacePhasor.v_[1] -> aimc.lssigma.spacePhasor_a.v_[1]
aimc.spacePhasorS.spacePhasor.v_[1] -> aimc.lssigma.spacePhasor_a.v_[1]
aimc.spacePhasorS.ground.v -> 0.0
aimc.lszero.n.v -> 0.0
aimc.spacePhasorS.zero.v -> aimc.lszero.v
aimc.spacePhasorS.plug_p.pin[3].v -> aimc.rs.plug_n.pin[3].v
aimc.rs.resistor[3].n.v -> aimc.rs.plug_n.pin[3].v
aimc.spacePhasorS.plug_p.pin[2].v -> aimc.rs.plug_n.pin[2].v
aimc.rs.resistor[2].n.v -> aimc.rs.plug_n.pin[2].v
aimc.spacePhasorS.plug_p.pin[1].v -> aimc.rs.plug_n.pin[1].v
aimc.rs.resistor[1].n.v -> aimc.rs.plug_n.pin[1].v
aimc.strayLoad.plug_n.pin[3].v -> -sinevoltage1.v[3]
aimc.rs.resistor[3].p.v -> -sinevoltage1.v[3]
aimc.strayLoad.plug_n.pin[2].v -> -sinevoltage1.v[2]
aimc.rs.resistor[2].p.v -> -sinevoltage1.v[2]
aimc.strayLoad.plug_n.pin[1].v -> -sinevoltage1.v[1]
aimc.rs.resistor[1].p.v -> -sinevoltage1.v[1]
aimc.thermalAmbient.constTs.y -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.temperatureStatorWinding.T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.temperatureStatorWinding.port.T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalCollectorStator.port_b.T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalCollectorStator.port_a[3].T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[3].T -> aimc.thermalAmbient.constTs.k
aimc.internalThermalPort.heatPortStatorWinding[3].T -> aimc.thermalAmbient.constTs.k
aimc.rs.heatPort[3].T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[3].heatPort.T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[3].T_heatPort -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalCollectorStator.port_a[2].T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[2].T -> aimc.thermalAmbient.constTs.k
aimc.internalThermalPort.heatPortStatorWinding[2].T -> aimc.thermalAmbient.constTs.k
aimc.rs.heatPort[2].T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[2].heatPort.T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[2].T_heatPort -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalCollectorStator.port_a[1].T -> aimc.thermalAmbient.constTs.k
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[1].T -> aimc.thermalAmbient.constTs.k
aimc.internalThermalPort.heatPortStatorWinding[1].T -> aimc.thermalAmbient.constTs.k
aimc.rs.heatPort[1].T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[1].heatPort.T -> aimc.thermalAmbient.constTs.k
aimc.rs.resistor[1].T_heatPort -> aimc.thermalAmbient.constTs.k
aimc.fixed.flange.phi -> aimc.fixed.phi0
aimc.airGapS.support.phi -> aimc.fixed.phi0
aimc.strayLoad.support.phi -> aimc.fixed.phi0
aimc.internalSupport.phi -> aimc.fixed.phi0
aimc.inertiaStator.flange_a.phi -> aimc.fixed.phi0
aimc.inertiaStator.phi -> aimc.fixed.phi0
aimc.inertiaStator.flange_b.phi -> aimc.fixed.phi0
aimc.friction.support.phi -> aimc.fixed.phi0
aimc.thermalAmbient.constTr.y -> aimc.thermalAmbient.constTr.k
aimc.thermalAmbient.temperatureRotorWinding.T -> aimc.thermalAmbient.constTr.k
aimc.thermalAmbient.temperatureRotorWinding.port.T -> aimc.thermalAmbient.constTr.k
aimc.thermalAmbient.thermalPort.heatPortRotorWinding.T -> aimc.thermalAmbient.constTr.k
aimc.internalThermalPort.heatPortRotorWinding.T -> aimc.thermalAmbient.constTr.k
aimc.squirrelCageR.heatPort.T -> aimc.thermalAmbient.constTr.k
aimc.squirrelCageR.T_heatPort -> aimc.thermalAmbient.constTr.k
aimc.lssigma.spacePhasor_b.v_[2] -> aimc.airGapS.spacePhasor_s.v_[2]
aimc.lssigma.spacePhasor_b.v_[1] -> aimc.airGapS.spacePhasor_s.v_[1]
aimc.squirrelCageR.spacePhasor_r.v_[2] -> aimc.airGapS.spacePhasor_r.v_[2]
aimc.squirrelCageR.spacePhasor_r.v_[1] -> aimc.airGapS.spacePhasor_r.v_[1]
aimc.inertiaStator.flange_b.tau -> 0.0
aimc.airGapS.i_rr[2] -> aimc.idq_rr[2]
aimc.airGapS.spacePhasor_r.i_[2] -> aimc.idq_rr[2]
aimc.squirrelCageR.spacePhasor_r.i_[2] -> -aimc.idq_rr[2]
aimc.ir[2] -> aimc.idq_rr[2]
aimc.airGapS.i_rr[1] -> aimc.idq_rr[1]
aimc.airGapS.spacePhasor_r.i_[1] -> aimc.idq_rr[1]
aimc.squirrelCageR.spacePhasor_r.i_[1] -> -aimc.idq_rr[1]
aimc.ir[1] -> aimc.idq_rr[1]
aimc.lssigma.spacePhasor_a.i_[2] -> aimc.lssigma.i_[2]
aimc.lssigma.spacePhasor_b.i_[2] -> -aimc.lssigma.i_[2]
aimc.airGapS.spacePhasor_s.i_[2] -> aimc.lssigma.i_[2]
aimc.airGapS.i_ss[2] -> aimc.lssigma.i_[2]
aimc.idq_ss[2] -> aimc.lssigma.i_[2]
aimc.lssigma.spacePhasor_a.i_[1] -> aimc.lssigma.i_[1]
aimc.lssigma.spacePhasor_b.i_[1] -> -aimc.lssigma.i_[1]
aimc.airGapS.spacePhasor_s.i_[1] -> aimc.lssigma.i_[1]
aimc.airGapS.i_ss[1] -> aimc.lssigma.i_[1]
aimc.idq_ss[1] -> aimc.lssigma.i_[1]
aimc.thermalAmbient.temperatureFriction.port.Q_flow -> aimc.powerBalance.lossPowerFriction
aimc.thermalAmbient.thermalPort.heatPortFriction.Q_flow -> aimc.powerBalance.lossPowerFriction
aimc.thermalAmbient.temperatureStrayLoad.port.Q_flow -> aimc.strayLoad.lossPower
aimc.thermalAmbient.thermalPort.heatPortStrayLoad.Q_flow -> aimc.strayLoad.lossPower
aimc.internalThermalPort.heatPortRotorCore.Q_flow -> 0.0
aimc.thermalAmbient.thermalPort.heatPortRotorCore.Q_flow -> 0.0
aimc.thermalAmbient.temperatureRotorCore.port.Q_flow -> 0.0
aimc.thermalAmbient.Q_flowRotorCore -> 0.0
aimc.thermalAmbient.temperatureStatorCore.port.Q_flow -> aimc.statorCore.lossPower
aimc.thermalAmbient.thermalPort.heatPortStatorCore.Q_flow -> aimc.statorCore.lossPower
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[1].Q_flow -> aimc.rs.resistor[1].LossPower
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[2].Q_flow -> aimc.rs.resistor[2].LossPower
aimc.thermalAmbient.thermalPort.heatPortStatorWinding[3].Q_flow -> aimc.rs.resistor[3].LossPower
aimc.thermalAmbient.temperatureRotorWinding.port.Q_flow -> aimc.thermalAmbient.Q_flowRotorWinding
aimc.thermalAmbient.thermalPort.heatPortRotorWinding.Q_flow -> aimc.thermalAmbient.Q_flowRotorWinding
aimc.thermalAmbient.temperatureStatorWinding.port.Q_flow -> aimc.thermalAmbient.Q_flowStatorWinding
aimc.thermalAmbient.thermalCollectorStator.port_b.Q_flow -> -aimc.thermalAmbient.Q_flowStatorWinding
aimc.inertiaRotor.flange_a.tau -> aimc.tauElectrical
aimc.airGapS.flange.tau -> -aimc.tauElectrical
aimc.airGapS.tauElectrical -> aimc.tauElectrical
aimc.airGapS.support.tau -> aimc.tauElectrical
aimc.rs.resistor[1].heatPort.Q_flow -> -aimc.rs.resistor[1].LossPower
aimc.rs.heatPort[1].Q_flow -> -aimc.rs.resistor[1].LossPower
aimc.rs.resistor[2].heatPort.Q_flow -> -aimc.rs.resistor[2].LossPower
aimc.rs.heatPort[2].Q_flow -> -aimc.rs.resistor[2].LossPower
aimc.rs.resistor[3].heatPort.Q_flow -> -aimc.rs.resistor[3].LossPower
aimc.rs.heatPort[3].Q_flow -> -aimc.rs.resistor[3].LossPower
aimc.internalThermalPort.heatPortStatorWinding[1].Q_flow -> 0.0
aimc.internalThermalPort.heatPortStatorWinding[2].Q_flow -> 0.0
aimc.internalThermalPort.heatPortStatorWinding[3].Q_flow -> 0.0
aimc.internalThermalPort.heatPortRotorWinding.Q_flow -> 0.0
aimc.internalThermalPort.heatPortFriction.Q_flow -> 0.0
aimc.internalThermalPort.heatPortStrayLoad.Q_flow -> 0.0
aimc.internalThermalPort.heatPortStatorCore.Q_flow -> 0.0
aimc.spacePhasorS.zero.i -> aimc.i_0_s
aimc.lszero.p.i -> -aimc.i_0_s
aimc.lszero.i -> -aimc.i_0_s
aimc.lszero.n.i -> aimc.i_0_s
aimc.spacePhasorS.ground.i -> -aimc.i_0_s
aimc.internalSupport.tau -> 0.0
terminalBox.starpoint.i -> 0.0
terminalBox.star.pin_n.i -> 0.0
sinevoltage1.sineVoltage[3].signalSource.y -> sinevoltage1.v[3]
sinevoltage1.sineVoltage[2].signalSource.y -> sinevoltage1.v[2]
sinevoltage1.sineVoltage[1].signalSource.y -> sinevoltage1.v[1]
speedSensor.flange.tau -> 0.0
aimc.squirrelCageR.heatPort.Q_flow -> -aimc.thermalAmbient.Q_flowRotorWinding
aimc.powerBalance.lossPowerRotorWinding -> aimc.thermalAmbient.Q_flowRotorWinding
aimc.airGapS.RotationMatrix[1,1] -> aimc.airGapS.RotationMatrix[2,2]
aimc.airGapS.RotationMatrix[1,2] -> -aimc.airGapS.RotationMatrix[2,1]
aimc.strayLoad.tau -> 0.0
aimc.strayLoad.support.tau -> 0.0
aimc.strayLoad.flange.tau -> -0.0
aimc.strayLoad.v[3] -> 0.0
aimc.strayLoad.v[2] -> 0.0
aimc.strayLoad.v[1] -> 0.0
aimc.strayLoad.heatPort.Q_flow -> -0.0
aimc.powerBalance.lossPowerStrayLoad -> 0.0
aimc.statorCore.spacePhasor.i_[2] -> 0.0
aimc.statorCore.spacePhasor.i_[1] -> 0.0
aimc.statorCore.heatPort.Q_flow -> -0.0
aimc.powerBalance.lossPowerStatorCore -> 0.0
aimc.airGapS.i_rs[2] -> aimc.idq_rs[2]
aimc.airGapS.i_rs[1] -> aimc.idq_rs[1]
aimc.airGapS.i_sr[2] -> aimc.idq_sr[2]
aimc.airGapS.i_sr[1] -> aimc.idq_sr[1]
aimc.friction.lossPower -> 0.0
aimc.friction.heatPort.Q_flow -> -0.0
aimc.powerBalance.lossPowerRotorCore -> 0.0
aimc.friction.tau -> 0.0
aimc.friction.support.tau -> 0.0
aimc.friction.flange.tau -> -0.0
aimc.flange.tau -> -(-const.k)
speedSensor.w -> aimc.inertiaRotor.w
aimc.inertiaStator.w -> 0.0
aimc.powerBalance.lossPowerFriction -> 0.0
aimc.thermalAmbient.Q_flowFriction -> 0.0
aimc.lszero.p.v -> aimc.lszero.v
aimc.statorCore.lossPower -> 0.0
aimc.thermalAmbient.Q_flowStatorCore -> 0.0
aimc.strayLoad.lossPower -> 0.0
aimc.thermalAmbient.Q_flowStrayLoad -> 0.0
aimc.plug_sp.pin[1].v -> -sinevoltage1.v[1]
aimc.rs.plug_p.pin[1].v -> -sinevoltage1.v[1]
sinevoltage1.sineVoltage[1].v -> sinevoltage1.v[1]
aimc.plug_sp.pin[2].v -> -sinevoltage1.v[2]
aimc.rs.plug_p.pin[2].v -> -sinevoltage1.v[2]
sinevoltage1.sineVoltage[2].v -> sinevoltage1.v[2]
aimc.plug_sp.pin[3].v -> -sinevoltage1.v[3]
aimc.rs.plug_p.pin[3].v -> -sinevoltage1.v[3]
sinevoltage1.sineVoltage[3].v -> sinevoltage1.v[3]
aimc.tauShaft -> -const.k
aimc.inertiaRotor.flange_b.tau -> const.k
aimc.spacePhasorS.spacePhasor.i_[1] -> -aimc.lssigma.i_[1]
aimc.spacePhasorS.spacePhasor.i_[2] -> -aimc.lssigma.i_[2]
aimc.thermalAmbient.thermalCollectorStator.port_a[3].Q_flow -> aimc.rs.resistor[3].LossPower
aimc.thermalAmbient.thermalCollectorStator.port_a[2].Q_flow -> aimc.rs.resistor[2].LossPower
aimc.thermalAmbient.thermalCollectorStator.port_a[1].Q_flow -> aimc.rs.resistor[1].LossPower
aimc.squirrelCageR.LossPower -> aimc.thermalAmbient.Q_flowRotorWinding
aimc.powerBalance.powerInertiaStator -> 0.0
aimc.inertiaStator.a -> 0.0
aimc.thermalAmbient.temperatureStrayLoad.port.T -> 293.15
aimc.thermalAmbient.thermalPort.heatPortStrayLoad.T -> 293.15
aimc.internalThermalPort.heatPortStrayLoad.T -> 293.15
aimc.strayLoad.heatPort.T -> 293.15
aimc.thermalAmbient.temperatureStatorCore.port.T -> 293.15
aimc.thermalAmbient.thermalPort.heatPortStatorCore.T -> 293.15
aimc.internalThermalPort.heatPortStatorCore.T -> 293.15
aimc.statorCore.heatPort.T -> 293.15
aimc.thermalAmbient.temperatureRotorCore.port.T -> 293.15
aimc.thermalAmbient.thermalPort.heatPortRotorCore.T -> 293.15
aimc.internalThermalPort.heatPortRotorCore.T -> 293.15
aimc.thermalAmbient.temperatureFriction.port.T -> 293.15
aimc.thermalAmbient.thermalPort.heatPortFriction.T -> 293.15
aimc.friction.heatPort.T -> 293.15
aimc.internalThermalPort.heatPortFriction.T -> 293.15
torque.phi_support -> 0.0
aimc.statorCore.Gc -> 0.0
aimc.statorCore.w -> aimc.statorCoreParameters.wRef
ExtendReplacements: (161)
========================================
const -> 0.0
torque -> 0.0
torque.flange -> 0.0
aimc -> 0.0
aimc.flange -> 0.0
aimc.strayLoad -> 0.0
aimc.strayLoad.flange -> 0.0
aimc.inertiaRotor -> 0.0
aimc.inertiaRotor.flange_b -> 0.0
aimc.inertiaRotor.flange_a -> 0.0
aimc.airGapS -> 0.0
aimc.airGapS.flange -> 0.0
aimc.friction -> 0.0
aimc.friction.flange -> 0.0
ground -> 0.0
ground.p -> 0.0
star -> 0.0
star.pin_n -> 0.0
star.plug_p -> 0.0
star.plug_p.pin -> 0.0
sinevoltage1 -> 0.0
sinevoltage1.plug_p -> 0.0
sinevoltage1.plug_p.pin -> 0.0
sinevoltage1.sineVoltage -> 0.0
sinevoltage1.sineVoltage[3].p -> 0.0
sinevoltage1.sineVoltage[2].p -> 0.0
sinevoltage1.sineVoltage[1].p -> 0.0
terminalBox -> 0.0
terminalBox.plug_sp -> 0.0
terminalBox.plug_sp.pin -> 0.0
terminalBox.plugSupply -> 0.0
terminalBox.plugSupply.pin -> 0.0
sinevoltage1.plug_n -> 0.0
sinevoltage1.plug_n.pin -> 0.0
sinevoltage1.sineVoltage[3].n -> 0.0
aimc.strayLoad.plug_p -> 0.0
aimc.strayLoad.plug_p.pin -> 0.0
sinevoltage1.sineVoltage[2].n -> 0.0
sinevoltage1.sineVoltage[1].n -> 0.0
terminalBox.plug_sn -> 0.0
terminalBox.plug_sn.pin -> 0.0
terminalBox.star -> 0.0
terminalBox.star.plug_p -> 0.0
terminalBox.star.plug_p.pin -> 0.0
terminalBox.star.pin_n -> 0.0
terminalBox.starpoint -> 0.0
aimc.plug_sn -> 0.0
aimc.plug_sn.pin -> 0.0
aimc.spacePhasorS -> 0.0
aimc.spacePhasorS.plug_n -> 0.0
aimc.spacePhasorS.plug_n.pin -> 0.0
aimc.plug_sp -> 0.0
aimc.plug_sp.pin -> 0.0
aimc.strayLoad.i -> 0.0
aimc.strayLoad.plug_n -> 0.0
aimc.strayLoad.plug_n.pin -> 0.0
aimc.rs -> 0.0
aimc.rs.plug_p -> 0.0
aimc.rs.plug_p.pin -> 0.0
aimc.rs.resistor -> 0.0
aimc.rs.resistor[1].p -> 0.0
aimc.rs.resistor[1].n -> 0.0
aimc.rs.plug_n -> 0.0
aimc.rs.plug_n.pin -> 0.0
aimc.spacePhasorS.plug_p -> 0.0
aimc.spacePhasorS.plug_p.pin -> 0.0
aimc.rs.i -> 0.0
aimc.is -> 0.0
aimc.rs.resistor[2].p -> 0.0
aimc.rs.resistor[2].n -> 0.0
aimc.rs.resistor[3].p -> 0.0
aimc.rs.resistor[3].n -> 0.0
aimc.statorCore -> 0.0
aimc.statorCore.spacePhasor -> 0.0
aimc.statorCore.spacePhasor.v_ -> 0.0
aimc.spacePhasorS.spacePhasor -> 0.0
aimc.spacePhasorS.spacePhasor.v_ -> 0.0
aimc.spacePhasorS.ground -> 0.0
aimc.lszero -> 0.0
aimc.lszero.n -> 0.0
aimc.spacePhasorS.zero -> 0.0
aimc.thermalAmbient -> 0.0
aimc.thermalAmbient.constTs -> 0.0
aimc.thermalAmbient.temperatureStatorWinding -> 0.0
aimc.thermalAmbient.temperatureStatorWinding.port -> 0.0
aimc.thermalAmbient.thermalCollectorStator -> 0.0
aimc.thermalAmbient.thermalCollectorStator.port_b -> 0.0
aimc.thermalAmbient.thermalCollectorStator.port_a -> 0.0
aimc.thermalAmbient.thermalPort -> 0.0
aimc.thermalAmbient.thermalPort.heatPortStatorWinding -> 0.0
aimc.internalThermalPort -> 0.0
aimc.internalThermalPort.heatPortStatorWinding -> 0.0
aimc.rs.heatPort -> 0.0
aimc.rs.resistor[3].heatPort -> 0.0
aimc.rs.resistor[2].heatPort -> 0.0
aimc.rs.resistor[1].heatPort -> 0.0
aimc.fixed -> 0.0
aimc.fixed.flange -> 0.0
aimc.airGapS.support -> 0.0
aimc.strayLoad.support -> 0.0
aimc.internalSupport -> 0.0
aimc.inertiaStator -> 0.0
aimc.inertiaStator.flange_a -> 0.0
aimc.inertiaStator.flange_b -> 0.0
aimc.friction.support -> 0.0
aimc.thermalAmbient.constTr -> 0.0
aimc.thermalAmbient.temperatureRotorWinding -> 0.0
aimc.thermalAmbient.temperatureRotorWinding.port -> 0.0
aimc.thermalAmbient.thermalPort.heatPortRotorWinding -> 0.0
aimc.internalThermalPort.heatPortRotorWinding -> 0.0
aimc.squirrelCageR -> 0.0
aimc.squirrelCageR.heatPort -> 0.0
aimc.lssigma -> 0.0
aimc.lssigma.spacePhasor_b -> 0.0
aimc.lssigma.spacePhasor_b.v_ -> 0.0
aimc.squirrelCageR.spacePhasor_r -> 0.0
aimc.squirrelCageR.spacePhasor_r.v_ -> 0.0
aimc.airGapS.i_rr -> 0.0
aimc.airGapS.spacePhasor_r -> 0.0
aimc.airGapS.spacePhasor_r.i_ -> 0.0
aimc.squirrelCageR.spacePhasor_r.i_ -> 0.0
aimc.ir -> 0.0
aimc.lssigma.spacePhasor_a -> 0.0
aimc.lssigma.spacePhasor_a.i_ -> 0.0
aimc.lssigma.spacePhasor_b.i_ -> 0.0
aimc.airGapS.spacePhasor_s -> 0.0
aimc.airGapS.spacePhasor_s.i_ -> 0.0
aimc.airGapS.i_ss -> 0.0
aimc.idq_ss -> 0.0
aimc.thermalAmbient.temperatureFriction -> 0.0
aimc.thermalAmbient.temperatureFriction.port -> 0.0
aimc.thermalAmbient.thermalPort.heatPortFriction -> 0.0
aimc.thermalAmbient.temperatureStrayLoad -> 0.0
aimc.thermalAmbient.temperatureStrayLoad.port -> 0.0
aimc.thermalAmbient.thermalPort.heatPortStrayLoad -> 0.0
aimc.internalThermalPort.heatPortRotorCore -> 0.0
aimc.thermalAmbient.thermalPort.heatPortRotorCore -> 0.0
aimc.thermalAmbient.temperatureRotorCore -> 0.0
aimc.thermalAmbient.temperatureRotorCore.port -> 0.0
aimc.thermalAmbient.temperatureStatorCore -> 0.0
aimc.thermalAmbient.temperatureStatorCore.port -> 0.0
aimc.thermalAmbient.thermalPort.heatPortStatorCore -> 0.0
aimc.internalThermalPort.heatPortFriction -> 0.0
aimc.internalThermalPort.heatPortStrayLoad -> 0.0
aimc.internalThermalPort.heatPortStatorCore -> 0.0
aimc.lszero.p -> 0.0
sinevoltage1.sineVoltage[3].signalSource -> 0.0
sinevoltage1.sineVoltage[2].signalSource -> 0.0
sinevoltage1.sineVoltage[1].signalSource -> 0.0
speedSensor -> 0.0
speedSensor.flange -> 0.0
aimc.powerBalance -> 0.0
aimc.airGapS.RotationMatrix -> 0.0
aimc.strayLoad.v -> 0.0
aimc.strayLoad.heatPort -> 0.0
aimc.statorCore.spacePhasor.i_ -> 0.0
aimc.statorCore.heatPort -> 0.0
aimc.airGapS.i_rs -> 0.0
aimc.airGapS.i_sr -> 0.0
aimc.friction.heatPort -> 0.0
aimc.spacePhasorS.spacePhasor.i_ -> 0.0
DerConstReplacements: (3)
========================================
aimc.inertiaRotor.phi -> speedSensor.w
aimc.inertiaStator.phi -> 0.0
aimc.inertiaStator.w -> 0.0
Unreplaceable Crefs: (1)
========================================
$cse1
Replacements: (20)
========================================
ground.p.i -> 0.0
aimc.airGapS.RotationMatrix[2,1] -> $cse1
aimc.strayLoad.w -> aimc.inertiaRotor.w
$DER.aimc.strayLoad.phi -> aimc.inertiaRotor.w
aimc.rs.resistor[3].v -> aimc.rs.v[3]
aimc.rs.resistor[2].v -> aimc.rs.v[2]
aimc.rs.resistor[1].v -> aimc.rs.v[1]
aimc.powerBalance.lossPowerStatorWinding -> aimc.thermalAmbient.Q_flowStatorWinding
aimc.powerBalance.lossPowerTotal -> aimc.thermalAmbient.Q_flowTotal
aimc.friction.w -> aimc.inertiaRotor.w
$DER.aimc.friction.phi -> aimc.inertiaRotor.w
aimc.inertiaStator.flange_a.tau -> 0.0
aimc.fixed.flange.tau -> -aimc.tauElectrical
aimc.wMechanical -> aimc.inertiaRotor.w
$DER.aimc.phiMechanical -> aimc.inertiaRotor.w
$DER.ground.p.i -> 0.0
$DER.aimc.airGapS.psi_mr[1] -> aimc.airGapS.spacePhasor_r.v_[1]
$DER.aimc.airGapS.psi_mr[2] -> aimc.airGapS.spacePhasor_r.v_[2]
$DER.aimc.airGapS.psi_ms[1] -> aimc.airGapS.spacePhasor_s.v_[1]
$DER.aimc.airGapS.psi_ms[2] -> aimc.airGapS.spacePhasor_s.v_[2]
ExtendReplacements: (23)
========================================
ground -> 0.0
ground.p -> 0.0
aimc -> 0.0
aimc.airGapS -> 0.0
aimc.airGapS.RotationMatrix -> 0.0
aimc.strayLoad -> 0.0
$DER -> 0.0
$DER.aimc -> 0.0
$DER.aimc.strayLoad -> 0.0
aimc.rs -> 0.0
aimc.rs.resistor -> 0.0
aimc.powerBalance -> 0.0
aimc.friction -> 0.0
$DER.aimc.friction -> 0.0
aimc.inertiaStator -> 0.0
aimc.inertiaStator.flange_a -> 0.0
aimc.fixed -> 0.0
aimc.fixed.flange -> 0.0
$DER.ground -> 0.0
$DER.ground.p -> 0.0
$DER.aimc.airGapS -> 0.0
$DER.aimc.airGapS.psi_mr -> 0.0
$DER.aimc.airGapS.psi_ms -> 0.0
########################################
dumpindxdae
########################################
unspecified partition
========================================
Variables (1)
========================================
1: star.pin_n.i:VARIABLE(flow=true unit = "A" ) "Current flowing into the pin" type: Real
Equations (1, 1)
========================================
1/1 (1): star.pin_n.i = 0.0 [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: ground.p.i:DUMMY_STATE(flow=true unit = "A" stateSelect=StateSelect.never ) "Current flowing into the pin" type: Real
Equations (1, 1)
========================================
1/1 (1): ground.p.i = 0.0 [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: aimc.inertiaStator.flange_a.tau:VARIABLE(flow=true unit = "N.m" ) "Cut torque in the flange" type: Real
Equations (1, 1)
========================================
1/1 (1): aimc.inertiaStator.flange_a.tau = 0.0 [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: $DER.ground.p.i:DUMMY_DER(flow=true fixed = false ) "Current flowing into the pin" type: Real
Equations (1, 1)
========================================
1/1 (1): $DER.ground.p.i = 0.0 [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: $DER.aimc.phiMechanical:DUMMY_DER(fixed = false ) "Mechanical angle of rotor against stator" type: Real
Equations (1, 1)
========================================
1/1 (1): $DER.aimc.phiMechanical = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: aimc.wMechanical:VARIABLE(start = 0.0 unit = "rad/s" fixed = false ) "Mechanical angular velocity of rotor against stator" type: Real
Equations (1, 1)
========================================
1/1 (1): aimc.wMechanical = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: $DER.aimc.friction.phi:DUMMY_DER(fixed = false ) "Angle between shaft and support" type: Real
Equations (1, 1)
========================================
1/1 (1): $DER.aimc.friction.phi = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: aimc.friction.w:VARIABLE(unit = "rad/s" fixed = false ) "Relative angular velocity of flange and support" type: Real
Equations (1, 1)
========================================
1/1 (1): aimc.friction.w = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: $DER.aimc.strayLoad.phi:DUMMY_DER(fixed = false ) "Angle between shaft and support" type: Real
Equations (1, 1)
========================================
1/1 (1): $DER.aimc.strayLoad.phi = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (1)
========================================
1: aimc.strayLoad.w:VARIABLE(unit = "rad/s" fixed = false ) "Relative angular velocity of flange and support" type: Real
Equations (1, 1)
========================================
1/1 (1): aimc.strayLoad.w = aimc.inertiaRotor.w [binding |0|0|0|0|]
Matching
========================================
1 variables and equations
var 1 is solved in eqn 1
StrongComponents
========================================
{1:1}
unspecified partition
========================================
Variables (93)
========================================
1: sinevoltage1.i[3]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Currents flowing into positive plugs" type: Real [3]
2: sinevoltage1.i[2]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Currents flowing into positive plugs" type: Real [3]
3: sinevoltage1.i[1]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Currents flowing into positive plugs" type: Real [3]
4: sinevoltage1.v[3]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
5: sinevoltage1.v[2]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
6: sinevoltage1.v[1]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
7: speedSensor.flange.phi:STATE(1,aimc.inertiaRotor.w)(flow=false unit = "rad" fixed = true ) "Absolute rotation angle of flange" type: Real
8: aimc.thermalAmbient.Q_flowTotal:VARIABLE(unit = "W" final = true ) type: Real
9: aimc.thermalAmbient.Q_flowRotorWinding:VARIABLE(unit = "W" final = true ) "Heat flow rate of rotor (squirrel cage)" type: Real
10: aimc.thermalAmbient.Q_flowStatorWinding:VARIABLE(unit = "W" final = true ) "Heat flow rate of stator windings" type: Real
11: aimc.airGapS.i_ms[2]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Magnetizing current space phasor with respect to the stator fixed frame" type: Real [2]
12: aimc.airGapS.i_ms[1]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Magnetizing current space phasor with respect to the stator fixed frame" type: Real [2]
13: aimc.airGapS.spacePhasor_r.v_[2]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
14: aimc.airGapS.spacePhasor_r.v_[1]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
15: aimc.airGapS.spacePhasor_s.v_[2]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
16: aimc.airGapS.spacePhasor_s.v_[1]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
17: aimc.airGapS.RotationMatrix[2,2]:DUMMY_STATE(stateSelect=StateSelect.never ) "Matrix of rotation from rotor to stator" type: Real [2,2]
18: aimc.airGapS.psi_mr[2]:DUMMY_STATE(unit = "Wb" ) "Magnetizing flux phasor with respect to the rotor fixed frame" type: Real [2]
19: aimc.airGapS.psi_mr[1]:DUMMY_STATE(unit = "Wb" ) "Magnetizing flux phasor with respect to the rotor fixed frame" type: Real [2]
20: aimc.airGapS.psi_ms[2]:DUMMY_STATE(unit = "Wb" ) "Magnetizing flux phasor with respect to the stator fixed frame" type: Real [2]
21: aimc.airGapS.psi_ms[1]:DUMMY_STATE(unit = "Wb" ) "Magnetizing flux phasor with respect to the stator fixed frame" type: Real [2]
22: aimc.airGapS.gamma:DUMMY_STATE(unit = "rad" stateSelect=StateSelect.never ) "Rotor displacement angle" type: Real
23: aimc.strayLoad.iRMS:VARIABLE(unit = "A" ) type: Real
24: aimc.strayLoad.phi:DUMMY_STATE(unit = "rad" ) "Angle between shaft and support" type: Real
25: aimc.spacePhasorS.i[3]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Instantaneous phase currents" type: Real [3]
26: aimc.spacePhasorS.i[2]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Instantaneous phase currents" type: Real [3]
27: aimc.spacePhasorS.i[1]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Instantaneous phase currents" type: Real [3]
28: aimc.spacePhasorS.v[3]:VARIABLE(unit = "V" ) "Instantaneous phase voltages" type: Real [3]
29: aimc.spacePhasorS.v[2]:VARIABLE(unit = "V" ) "Instantaneous phase voltages" type: Real [3]
30: aimc.spacePhasorS.v[1]:VARIABLE(unit = "V" ) "Instantaneous phase voltages" type: Real [3]
31: aimc.lszero.v:VARIABLE(unit = "V" ) "Voltage drop between the two pins (= p.v - n.v)" type: Real
32: aimc.lssigma.spacePhasor_a.v_[2]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
33: aimc.lssigma.spacePhasor_a.v_[1]:VARIABLE(flow=false unit = "V" ) "1=real, 2=imaginary part" type: Real [2]
34: aimc.lssigma.i_[2]:DUMMY_STATE(unit = "A" ) type: Real [2]
35: aimc.lssigma.i_[1]:DUMMY_STATE(unit = "A" ) type: Real [2]
36: aimc.lssigma.v_[2]:VARIABLE(unit = "V" ) type: Real [2]
37: aimc.lssigma.v_[1]:VARIABLE(unit = "V" ) type: Real [2]
38: aimc.rs.resistor[3].LossPower:VARIABLE(unit = "W" ) "Loss power leaving component via HeatPort" type: Real [3]
39: aimc.rs.resistor[2].LossPower:VARIABLE(unit = "W" ) "Loss power leaving component via HeatPort" type: Real [3]
40: aimc.rs.resistor[1].LossPower:VARIABLE(unit = "W" ) "Loss power leaving component via HeatPort" type: Real [3]
41: aimc.rs.plug_n.pin[3].v:VARIABLE(flow=false unit = "V" ) "Potential at the pin" type: Real [3]
42: aimc.rs.plug_n.pin[2].v:VARIABLE(flow=false unit = "V" ) "Potential at the pin" type: Real [3]
43: aimc.rs.plug_n.pin[1].v:VARIABLE(flow=false unit = "V" ) "Potential at the pin" type: Real [3]
44: aimc.rs.v[3]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
45: aimc.rs.v[2]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
46: aimc.rs.v[1]:VARIABLE(unit = "V" ) "Voltage drops between the two plugs" type: Real [3]
47: aimc.plug_sn.pin[3].v:VARIABLE(flow=false unit = "V" ) "Potential at the pin" type: Real [3]
48: aimc.idq_rr[2]:STATE(1)(unit = "A" fixed = true stateSelect=StateSelect.prefer ) "Rotor space phasor current / rotor fixed frame" type: Real [2]
49: aimc.idq_rr[1]:STATE(1)(unit = "A" fixed = true stateSelect=StateSelect.prefer ) "Rotor space phasor current / rotor fixed frame" type: Real [2]
50: aimc.idq_rs[2]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Rotor space phasor current / stator fixed frame" type: Real [2]
51: aimc.idq_rs[1]:DUMMY_STATE(unit = "A" stateSelect=StateSelect.never ) "Rotor space phasor current / stator fixed frame" type: Real [2]
52: aimc.idq_sr[2]:STATE(1)(unit = "A" fixed = true stateSelect=StateSelect.prefer ) "Stator space phasor current / rotor fixed frame" type: Real [2]
53: aimc.idq_sr[1]:STATE(1)(unit = "A" fixed = true stateSelect=StateSelect.prefer ) "Stator space phasor current / rotor fixed frame" type: Real [2]
54: aimc.i_0_s:DUMMY_STATE(start = 0.0 unit = "A" stateSelect=StateSelect.prefer ) "Stator zero-sequence current" type: Real
55: aimc.vs[3]:VARIABLE(unit = "V" ) "Stator instantaneous voltages" type: Real [3]
56: aimc.vs[2]:VARIABLE(unit = "V" ) "Stator instantaneous voltages" type: Real [3]
57: aimc.vs[1]:VARIABLE(unit = "V" ) "Stator instantaneous voltages" type: Real [3]
58: aimc.powerBalance.powerInertiaRotor:VARIABLE(unit = "W" final = true ) "Rotor inertia power" type: Real
59: aimc.powerBalance.powerMechanical:VARIABLE(unit = "W" final = true ) "Mechanical power" type: Real
60: aimc.powerBalance.powerStator:VARIABLE(unit = "W" final = true ) "Electrical power (stator)" type: Real
61: aimc.friction.phi:DUMMY_STATE(unit = "rad" ) "Angle between shaft and support" type: Real
62: aimc.inertiaRotor.a:VARIABLE(unit = "rad/s2" ) "Absolute angular acceleration of component (= der(w))" type: Real
63: aimc.inertiaRotor.w:STATE(1,aimc.inertiaRotor.a)(unit = "rad/s" fixed = true ) "Absolute angular velocity of component (= der(phi))" type: Real
64: aimc.tauElectrical:VARIABLE(unit = "N.m" ) "Electromagnetic torque" type: Real
65: aimc.phiMechanical:DUMMY_STATE(start = 0.0 unit = "rad" ) "Mechanical angle of rotor against stator" type: Real
66: $DER.aimc.airGapS.gamma:DUMMY_DER(fixed = false ) "Rotor displacement angle" type: Real
67: $DER.aimc.airGapS.RotationMatrix[2,1]:DUMMY_DER(fixed = false ) "Matrix of rotation from rotor to stator" type: Real [2,2]
68: $DER.aimc.airGapS.RotationMatrix[2,2]:DUMMY_DER(fixed = false ) "Matrix of rotation from rotor to stator" type: Real [2,2]
69: $DER.aimc.idq_rs[1]:DUMMY_DER(fixed = false ) "Rotor space phasor current / stator fixed frame" type: Real [2]
70: $DER.aimc.idq_rs[2]:DUMMY_DER(fixed = false ) "Rotor space phasor current / stator fixed frame" type: Real [2]
71: $DER.aimc.airGapS.i_ms[1]:DUMMY_DER(fixed = false ) "Magnetizing current space phasor with respect to the stator fixed frame" type: Real [2]
72: $DER.aimc.airGapS.i_ms[2]:DUMMY_DER(fixed = false ) "Magnetizing current space phasor with respect to the stator fixed frame" type: Real [2]
73: $DER.sinevoltage1.i[1]:DUMMY_DER(fixed = false ) "Currents flowing into positive plugs" type: Real [3]
74: $DER.sinevoltage1.i[2]:DUMMY_DER(fixed = false ) "Currents flowing into positive plugs" type: Real [3]
75: $DER.sinevoltage1.i[3]:DUMMY_DER(fixed = false ) "Currents flowing into positive plugs" type: Real [3]
76: $DER.aimc.spacePhasorS.i[1]:DUMMY_DER(fixed = false ) "Instantaneous phase currents" type: Real [3]
77: $DER.aimc.spacePhasorS.i[2]:DUMMY_DER(fixed = false ) "Instantaneous phase currents" type: Real [3]
78: $DER.aimc.spacePhasorS.i[3]:DUMMY_DER(fixed = false ) "Instantaneous phase currents" type: Real [3]
79: $DER.aimc.lssigma.i_[1]:DUMMY_DER(fixed = false ) type: Real [2]
80: $DER.aimc.lssigma.i_[2]:DUMMY_DER(fixed = false ) type: Real [2]
81: $DER.aimc.i_0_s:DUMMY_DER(fixed = false ) "Stator zero-sequence current" type: Real
82: $cse1:VARIABLE(protected = true ) type: Real unreplaceable
83: aimc.airGapS.RotationMatrix[2,1]:DUMMY_STATE(fixed = false stateSelect=StateSelect.never ) "Matrix of rotation from rotor to stator" type: Real [2,2]
84: aimc.rs.resistor[3].v:VARIABLE(unit = "V" fixed = false ) "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
85: aimc.rs.resistor[2].v:VARIABLE(unit = "V" fixed = false ) "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
86: aimc.rs.resistor[1].v:VARIABLE(unit = "V" fixed = false ) "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
87: aimc.powerBalance.lossPowerStatorWinding:VARIABLE(unit = "W" fixed = false final = true ) "Stator copper losses" type: Real
88: aimc.powerBalance.lossPowerTotal:VARIABLE(unit = "W" fixed = false final = true ) "Total loss power" type: Real
89: aimc.fixed.flange.tau:VARIABLE(flow=true unit = "N.m" fixed = false ) "Cut torque in the flange" type: Real
90: $DER.aimc.airGapS.psi_mr[1]:DUMMY_DER(fixed = false ) "Magnetizing flux phasor with respect to the rotor fixed frame" type: Real [2]
91: $DER.aimc.airGapS.psi_mr[2]:DUMMY_DER(fixed = false ) "Magnetizing flux phasor with respect to the rotor fixed frame" type: Real [2]
92: $DER.aimc.airGapS.psi_ms[1]:DUMMY_DER(fixed = false ) "Magnetizing flux phasor with respect to the stator fixed frame" type: Real [2]
93: $DER.aimc.airGapS.psi_ms[2]:DUMMY_DER(fixed = false ) "Magnetizing flux phasor with respect to the stator fixed frame" type: Real [2]
Equations (93, 93)
========================================
1/1 (1): aimc.phiMechanical = speedSensor.flange.phi - aimc.fixed.phi0 [binding |0|0|0|0|]
2/2 (1): aimc.friction.phi = speedSensor.flange.phi - aimc.fixed.phi0 [dynamic |0|0|0|0|]
3/3 (1): aimc.strayLoad.phi = speedSensor.flange.phi - aimc.fixed.phi0 [dynamic |0|0|0|0|]
4/4 (1): aimc.airGapS.gamma = /*Real*/(aimc.airGapS.p) * (speedSensor.flange.phi - aimc.fixed.phi0) [dynamic |0|0|0|0|]
5/5 (1): aimc.airGapS.RotationMatrix[2,2] = cos(aimc.airGapS.gamma) [unknown |0|0|0|0|]
6/6 (1): $cse1 = sin(aimc.airGapS.gamma) [unknown |0|0|0|0|]
7/7 (1): aimc.lssigma.i_[1] = aimc.airGapS.RotationMatrix[2,2] * aimc.idq_sr[1] - $cse1 * aimc.idq_sr[2] [dynamic |0|0|0|0|]
8/8 (1): aimc.lssigma.i_[2] = $cse1 * aimc.idq_sr[1] + aimc.airGapS.RotationMatrix[2,2] * aimc.idq_sr[2] [dynamic |0|0|0|0|]
9/9 (1): aimc.idq_rs[1] = aimc.airGapS.RotationMatrix[2,2] * aimc.idq_rr[1] - $cse1 * aimc.idq_rr[2] [dynamic |0|0|0|0|]
10/10 (1): aimc.airGapS.i_ms[1] = aimc.lssigma.i_[1] + aimc.idq_rs[1] [dynamic |0|0|0|0|]
11/11 (1): aimc.idq_rs[2] = $cse1 * aimc.idq_rr[1] + aimc.airGapS.RotationMatrix[2,2] * aimc.idq_rr[2] [dynamic |0|0|0|0|]
12/12 (1): aimc.airGapS.i_ms[2] = aimc.lssigma.i_[2] + aimc.idq_rs[2] [dynamic |0|0|0|0|]
13/13 (1): aimc.airGapS.psi_ms[2] = aimc.airGapS.L[2,1] * aimc.airGapS.i_ms[1] + aimc.airGapS.L[2,2] * aimc.airGapS.i_ms[2] [dynamic |0|0|0|0|]
14/14 (1): aimc.airGapS.psi_ms[1] = aimc.airGapS.L[1,1] * aimc.airGapS.i_ms[1] + aimc.airGapS.L[1,2] * aimc.airGapS.i_ms[2] [dynamic |0|0|0|0|]
15/15 (1): aimc.airGapS.psi_mr[2] = aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.psi_ms[2] - $cse1 * aimc.airGapS.psi_ms[1] [dynamic |0|0|0|0|]
16/16 (1): aimc.airGapS.psi_mr[1] = aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.psi_ms[1] + $cse1 * aimc.airGapS.psi_ms[2] [dynamic |0|0|0|0|]
17/17 (1): (-sinevoltage1.i[1]) - sinevoltage1.i[3] - sinevoltage1.i[2] = 0.0 [dynamic |0|0|0|0|]
18/18 (1): aimc.spacePhasorS.i[2] * aimc.spacePhasorS.turnsRatio = sinevoltage1.i[2] [dynamic |0|0|0|0|]
19/19 (1): aimc.lssigma.i_[1] = aimc.spacePhasorS.TransformationMatrix[1,1] * aimc.spacePhasorS.i[1] + aimc.spacePhasorS.TransformationMatrix[1,2] * aimc.spacePhasorS.i[2] + aimc.spacePhasorS.TransformationMatrix[1,3] * aimc.spacePhasorS.i[3] [dynamic |0|0|0|0|]
20/20 (1): aimc.spacePhasorS.i[3] * aimc.spacePhasorS.turnsRatio = sinevoltage1.i[3] [dynamic |0|0|0|0|]
21/21 (1): aimc.lssigma.i_[2] = aimc.spacePhasorS.TransformationMatrix[2,1] * aimc.spacePhasorS.i[1] + aimc.spacePhasorS.TransformationMatrix[2,2] * aimc.spacePhasorS.i[2] + aimc.spacePhasorS.TransformationMatrix[2,3] * aimc.spacePhasorS.i[3] [dynamic |0|0|0|0|]
22/22 (1): aimc.spacePhasorS.i[1] * aimc.spacePhasorS.turnsRatio = sinevoltage1.i[1] [dynamic |0|0|0|0|]
23/23 (1): aimc.i_0_s = (aimc.spacePhasorS.i[1] + aimc.spacePhasorS.i[2] + aimc.spacePhasorS.i[3]) / (-3.0) [dynamic |0|0|0|0|]
24/24 (1): sinevoltage1.v[3] = sinevoltage1.sineVoltage[3].signalSource.offset + (if time < sinevoltage1.sineVoltage[3].signalSource.startTime then 0.0 else sinevoltage1.sineVoltage[3].signalSource.amplitude * sin(6.283185307179586 * sinevoltage1.sineVoltage[3].signalSource.freqHz * (time - sinevoltage1.sineVoltage[3].signalSource.startTime) + sinevoltage1.sineVoltage[3].signalSource.phase)) [dynamic |0|0|0|0|]
25/25 (1): sinevoltage1.v[2] = sinevoltage1.sineVoltage[2].signalSource.offset + (if time < sinevoltage1.sineVoltage[2].signalSource.startTime then 0.0 else sinevoltage1.sineVoltage[2].signalSource.amplitude * sin(6.283185307179586 * sinevoltage1.sineVoltage[2].signalSource.freqHz * (time - sinevoltage1.sineVoltage[2].signalSource.startTime) + sinevoltage1.sineVoltage[2].signalSource.phase)) [dynamic |0|0|0|0|]
26/26 (1): sinevoltage1.v[1] = sinevoltage1.sineVoltage[1].signalSource.offset + (if time < sinevoltage1.sineVoltage[1].signalSource.startTime then 0.0 else sinevoltage1.sineVoltage[1].signalSource.amplitude * sin(6.283185307179586 * sinevoltage1.sineVoltage[1].signalSource.freqHz * (time - sinevoltage1.sineVoltage[1].signalSource.startTime) + sinevoltage1.sineVoltage[1].signalSource.phase)) [dynamic |0|0|0|0|]
27/27 (1): der(speedSensor.flange.phi) = aimc.inertiaRotor.w [dynamic |0|0|0|0|]
28/28 (1): aimc.thermalAmbient.Q_flowRotorWinding = 1.5 * aimc.squirrelCageR.Rr_actual * (aimc.idq_rr[1] ^ 2.0 + aimc.idq_rr[2] ^ 2.0) [dynamic |0|0|0|0|]
29/29 (1): aimc.tauElectrical = 1.5 * /*Real*/(aimc.airGapS.p) * (aimc.lssigma.i_[2] * aimc.airGapS.psi_ms[1] - aimc.lssigma.i_[1] * aimc.airGapS.psi_ms[2]) [dynamic |0|0|0|0|]
30/30 (1): $DER.aimc.airGapS.gamma = /*Real*/(aimc.airGapS.p) * aimc.inertiaRotor.w [dynamic |0|0|0|0|]
31/31 (1): $DER.aimc.airGapS.RotationMatrix[2,2] = (-$cse1) * $DER.aimc.airGapS.gamma [dynamic |0|0|0|0|]
32/32 (1): $DER.aimc.airGapS.RotationMatrix[2,1] = aimc.airGapS.RotationMatrix[2,2] * $DER.aimc.airGapS.gamma [dynamic |0|0|0|0|]
33/33 (1): aimc.strayLoad.iRMS = sqrt(sinevoltage1.i[1] ^ 2.0 / 3.0 + sinevoltage1.i[2] ^ 2.0 / 3.0 + sinevoltage1.i[3] ^ 2.0 / 3.0) [binding |0|0|0|0|]
34/34 (1): aimc.rs.v[3] = aimc.rs.resistor[3].R_actual * sinevoltage1.i[3] [dynamic |0|0|0|0|]
35/35 (1): aimc.rs.resistor[3].LossPower = aimc.rs.v[3] * sinevoltage1.i[3] [dynamic |0|0|0|0|]
36/36 (1): aimc.rs.plug_n.pin[3].v = (-sinevoltage1.v[3]) - aimc.rs.v[3] [dynamic |0|0|0|0|]
37/37 (1): aimc.rs.v[2] = aimc.rs.resistor[2].R_actual * sinevoltage1.i[2] [dynamic |0|0|0|0|]
38/38 (1): aimc.rs.resistor[2].LossPower = aimc.rs.v[2] * sinevoltage1.i[2] [dynamic |0|0|0|0|]
39/39 (1): aimc.rs.plug_n.pin[2].v = (-sinevoltage1.v[2]) - aimc.rs.v[2] [dynamic |0|0|0|0|]
40/40 (1): aimc.rs.v[1] = aimc.rs.resistor[1].R_actual * sinevoltage1.i[1] [dynamic |0|0|0|0|]
41/41 (1): aimc.rs.resistor[1].LossPower = aimc.rs.v[1] * sinevoltage1.i[1] [dynamic |0|0|0|0|]
42/42 (1): aimc.thermalAmbient.Q_flowStatorWinding = aimc.rs.resistor[1].LossPower + aimc.rs.resistor[2].LossPower + aimc.rs.resistor[3].LossPower [dynamic |0|0|0|0|]
43/43 (1): aimc.thermalAmbient.Q_flowTotal = aimc.thermalAmbient.Q_flowStatorWinding + aimc.thermalAmbient.Q_flowRotorWinding [binding |0|0|0|0|]
44/44 (1): aimc.rs.plug_n.pin[1].v = (-sinevoltage1.v[1]) - aimc.rs.v[1] [dynamic |0|0|0|0|]
45/45 (1): aimc.inertiaRotor.a = (aimc.tauElectrical + const.k) / aimc.inertiaRotor.J [dynamic |0|0|0|0|]
46/46 (1): aimc.powerBalance.powerInertiaRotor = aimc.inertiaRotor.J * aimc.inertiaRotor.a * aimc.inertiaRotor.w [binding |0|0|0|0|]
47/47 (1): der(aimc.inertiaRotor.w) = aimc.inertiaRotor.a [dynamic |0|0|0|0|]
48/48 (1): aimc.powerBalance.powerMechanical = (-aimc.inertiaRotor.w) * const.k [binding |0|0|0|0|]
49/49 (1): (-$DER.sinevoltage1.i[1]) - $DER.sinevoltage1.i[2] - $DER.sinevoltage1.i[3] = 0.0 [dynamic |0|0|0|0|]
50/50 (1): $DER.aimc.spacePhasorS.i[3] * aimc.spacePhasorS.turnsRatio = $DER.sinevoltage1.i[3] [dynamic |0|0|0|0|]
51/51 (1): $DER.aimc.lssigma.i_[2] = aimc.spacePhasorS.TransformationMatrix[2,1] * $DER.aimc.spacePhasorS.i[1] + aimc.spacePhasorS.TransformationMatrix[2,2] * $DER.aimc.spacePhasorS.i[2] + aimc.spacePhasorS.TransformationMatrix[2,3] * $DER.aimc.spacePhasorS.i[3] [dynamic |0|0|0|0|]
52/52 (1): $DER.aimc.lssigma.i_[1] = aimc.spacePhasorS.TransformationMatrix[1,1] * $DER.aimc.spacePhasorS.i[1] + aimc.spacePhasorS.TransformationMatrix[1,2] * $DER.aimc.spacePhasorS.i[2] + aimc.spacePhasorS.TransformationMatrix[1,3] * $DER.aimc.spacePhasorS.i[3] [dynamic |0|0|0|0|]
53/53 (1): (-3.0) * $DER.aimc.i_0_s = $DER.aimc.spacePhasorS.i[1] + $DER.aimc.spacePhasorS.i[2] + $DER.aimc.spacePhasorS.i[3] [dynamic |0|0|0|0|]
54/54 (1): (-aimc.lszero.L) * $DER.aimc.i_0_s = aimc.lszero.v [dynamic |0|0|0|0|]
55/55 (1): 3.0 * aimc.lszero.v = aimc.spacePhasorS.v[1] + aimc.spacePhasorS.v[2] + aimc.spacePhasorS.v[3] [dynamic |0|0|0|0|]
56/56 (1): aimc.lssigma.spacePhasor_a.v_[2] = aimc.spacePhasorS.TransformationMatrix[2,1] * aimc.spacePhasorS.v[1] + aimc.spacePhasorS.TransformationMatrix[2,2] * aimc.spacePhasorS.v[2] + aimc.spacePhasorS.TransformationMatrix[2,3] * aimc.spacePhasorS.v[3] [dynamic |0|0|0|0|]
57/57 (1): aimc.lssigma.v_[2] = aimc.lssigma.spacePhasor_a.v_[2] - aimc.airGapS.spacePhasor_s.v_[2] [dynamic |0|0|0|0|]
58/58 (1): aimc.airGapS.spacePhasor_r.v_[2] = aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.spacePhasor_s.v_[2] + $DER.aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.psi_ms[2] + (-$cse1) * aimc.airGapS.spacePhasor_s.v_[1] - $DER.aimc.airGapS.RotationMatrix[2,1] * aimc.airGapS.psi_ms[1] [dynamic |0|0|0|0|]
59/59 (1): aimc.airGapS.spacePhasor_r.v_[1] = aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.spacePhasor_s.v_[1] + $DER.aimc.airGapS.RotationMatrix[2,2] * aimc.airGapS.psi_ms[1] + $cse1 * aimc.airGapS.spacePhasor_s.v_[2] + $DER.aimc.airGapS.RotationMatrix[2,1] * aimc.airGapS.psi_ms[2] [dynamic |0|0|0|0|]
60/60 (1): aimc.airGapS.spacePhasor_r.v_[1] = (-aimc.idq_rr[1]) * aimc.squirrelCageR.Rr_actual - der(aimc.idq_rr[1]) * aimc.squirrelCageR.Lrsigma [dynamic |0|0|0|0|]
61/61 (1): $DER.aimc.idq_rs[2] = $cse1 * der(aimc.idq_rr[1]) + $DER.aimc.airGapS.RotationMatrix[2,1] * aimc.idq_rr[1] + aimc.airGapS.RotationMatrix[2,2] * der(aimc.idq_rr[2]) + $DER.aimc.airGapS.RotationMatrix[2,2] * aimc.idq_rr[2] [dynamic |0|0|0|0|]
62/62 (1): $DER.aimc.airGapS.i_ms[2] = $DER.aimc.lssigma.i_[2] + $DER.aimc.idq_rs[2] [dynamic |0|0|0|0|]
63/63 (1): aimc.lssigma.v_[2] = aimc.lss
...[truncated 53601 chars]...
(flow=false unit = "V" ) = ground.p.v "Potential at the pin" type: Real [3]
19: terminalBox.plug_sp.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
20: terminalBox.plugSupply.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
21: sinevoltage1.plug_n.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
22: sinevoltage1.sineVoltage[3].n.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
23: aimc.strayLoad.plug_p.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
24: terminalBox.plug_sp.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
25: terminalBox.plugSupply.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
26: sinevoltage1.plug_n.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
27: sinevoltage1.sineVoltage[2].n.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
28: aimc.strayLoad.plug_p.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
29: terminalBox.plug_sp.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
30: terminalBox.plugSupply.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
31: sinevoltage1.plug_n.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
32: sinevoltage1.sineVoltage[1].n.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
33: aimc.strayLoad.plug_p.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
34: terminalBox.plug_sn.pin[3].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
35: terminalBox.star.plug_p.pin[3].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
36: terminalBox.star.pin_n.v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real
37: terminalBox.starpoint.v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real
38: terminalBox.star.plug_p.pin[2].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
39: terminalBox.plug_sn.pin[2].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
40: aimc.plug_sn.pin[2].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
41: aimc.spacePhasorS.plug_n.pin[2].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
42: terminalBox.star.plug_p.pin[1].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
43: terminalBox.plug_sn.pin[1].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
44: aimc.plug_sn.pin[1].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
45: aimc.spacePhasorS.plug_n.pin[1].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
46: aimc.spacePhasorS.plug_n.pin[3].v:VARIABLE(flow=false unit = "V" ) = aimc.plug_sn.pin[3].v "Potential at the pin" type: Real [3]
47: sinevoltage1.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
48: sinevoltage1.sineVoltage[1].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
49: sinevoltage1.sineVoltage[1].i:VARIABLE(unit = "A" ) = sinevoltage1.i[1] "Current flowing from pin p to pin n" type: Real [3]
50: sinevoltage1.sineVoltage[1].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
51: sinevoltage1.plug_n.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
52: terminalBox.plugSupply.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
53: terminalBox.plug_sp.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
54: aimc.plug_sp.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
55: aimc.strayLoad.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
56: aimc.strayLoad.i[1]:VARIABLE(unit = "A" ) = sinevoltage1.i[1] "Currents flowing into positive plugs" type: Real [3]
57: aimc.strayLoad.plug_n.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
58: aimc.rs.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
59: aimc.rs.resistor[1].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
60: aimc.rs.resistor[1].i:VARIABLE(unit = "A" ) = sinevoltage1.i[1] "Current flowing from pin p to pin n" type: Real [3]
61: aimc.rs.resistor[1].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
62: aimc.rs.plug_n.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
63: aimc.spacePhasorS.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
64: aimc.spacePhasorS.plug_n.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
65: aimc.plug_sn.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
66: terminalBox.plug_sn.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
67: terminalBox.star.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
68: aimc.rs.i[1]:VARIABLE(unit = "A" ) = sinevoltage1.i[1] "Currents flowing into positive plugs" type: Real [3]
69: aimc.is[1]:VARIABLE(unit = "A" ) = sinevoltage1.i[1] "Stator instantaneous currents" type: Real [3]
70: star.plug_p.pin[1].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[1] "Current flowing into the pin" type: Real [3]
71: sinevoltage1.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
72: sinevoltage1.sineVoltage[2].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
73: sinevoltage1.sineVoltage[2].i:VARIABLE(unit = "A" ) = sinevoltage1.i[2] "Current flowing from pin p to pin n" type: Real [3]
74: sinevoltage1.sineVoltage[2].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
75: sinevoltage1.plug_n.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
76: terminalBox.plugSupply.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
77: terminalBox.plug_sp.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
78: aimc.plug_sp.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
79: aimc.strayLoad.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
80: aimc.strayLoad.i[2]:VARIABLE(unit = "A" ) = sinevoltage1.i[2] "Currents flowing into positive plugs" type: Real [3]
81: aimc.strayLoad.plug_n.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
82: aimc.rs.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
83: aimc.rs.resistor[2].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
84: aimc.rs.resistor[2].i:VARIABLE(unit = "A" ) = sinevoltage1.i[2] "Current flowing from pin p to pin n" type: Real [3]
85: aimc.rs.resistor[2].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
86: aimc.rs.plug_n.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
87: aimc.spacePhasorS.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
88: aimc.spacePhasorS.plug_n.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
89: aimc.plug_sn.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
90: terminalBox.plug_sn.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
91: terminalBox.star.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
92: aimc.rs.i[2]:VARIABLE(unit = "A" ) = sinevoltage1.i[2] "Currents flowing into positive plugs" type: Real [3]
93: aimc.is[2]:VARIABLE(unit = "A" ) = sinevoltage1.i[2] "Stator instantaneous currents" type: Real [3]
94: star.plug_p.pin[2].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[2] "Current flowing into the pin" type: Real [3]
95: sinevoltage1.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
96: sinevoltage1.sineVoltage[3].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
97: sinevoltage1.sineVoltage[3].i:VARIABLE(unit = "A" ) = sinevoltage1.i[3] "Current flowing from pin p to pin n" type: Real [3]
98: sinevoltage1.sineVoltage[3].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
99: sinevoltage1.plug_n.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
100: terminalBox.plugSupply.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
101: terminalBox.plug_sp.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
102: aimc.plug_sp.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
103: aimc.strayLoad.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
104: aimc.strayLoad.i[3]:VARIABLE(unit = "A" ) = sinevoltage1.i[3] "Currents flowing into positive plugs" type: Real [3]
105: aimc.strayLoad.plug_n.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
106: aimc.rs.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
107: aimc.rs.resistor[3].p.i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
108: aimc.rs.resistor[3].i:VARIABLE(unit = "A" ) = sinevoltage1.i[3] "Current flowing from pin p to pin n" type: Real [3]
109: aimc.rs.resistor[3].n.i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
110: aimc.rs.plug_n.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
111: aimc.spacePhasorS.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
112: aimc.spacePhasorS.plug_n.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
113: aimc.plug_sn.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
114: terminalBox.plug_sn.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
115: terminalBox.star.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
116: aimc.rs.i[3]:VARIABLE(unit = "A" ) = sinevoltage1.i[3] "Currents flowing into positive plugs" type: Real [3]
117: aimc.is[3]:VARIABLE(unit = "A" ) = sinevoltage1.i[3] "Stator instantaneous currents" type: Real [3]
118: star.plug_p.pin[3].i:VARIABLE(flow=true unit = "A" ) = -sinevoltage1.i[3] "Current flowing into the pin" type: Real [3]
119: aimc.statorCore.spacePhasor.v_[2]:VARIABLE(flow=false unit = "V" ) = aimc.lssigma.spacePhasor_a.v_[2] "1=real, 2=imaginary part" type: Real [2]
120: aimc.spacePhasorS.spacePhasor.v_[2]:VARIABLE(flow=false unit = "V" ) = aimc.lssigma.spacePhasor_a.v_[2] "1=real, 2=imaginary part" type: Real [2]
121: aimc.statorCore.spacePhasor.v_[1]:VARIABLE(flow=false unit = "V" ) = aimc.lssigma.spacePhasor_a.v_[1] "1=real, 2=imaginary part" type: Real [2]
122: aimc.spacePhasorS.spacePhasor.v_[1]:VARIABLE(flow=false unit = "V" ) = aimc.lssigma.spacePhasor_a.v_[1] "1=real, 2=imaginary part" type: Real [2]
123: aimc.lszero.n.v:VARIABLE(flow=false unit = "V" ) = aimc.spacePhasorS.ground.v "Potential at the pin" type: Real
124: aimc.spacePhasorS.zero.v:VARIABLE(flow=false unit = "V" ) = aimc.lszero.v "Potential at the pin" type: Real
125: aimc.spacePhasorS.plug_p.pin[3].v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[3].v "Potential at the pin" type: Real [3]
126: aimc.rs.resistor[3].n.v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[3].v "Potential at the pin" type: Real [3]
127: aimc.spacePhasorS.plug_p.pin[2].v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[2].v "Potential at the pin" type: Real [3]
128: aimc.rs.resistor[2].n.v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[2].v "Potential at the pin" type: Real [3]
129: aimc.spacePhasorS.plug_p.pin[1].v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[1].v "Potential at the pin" type: Real [3]
130: aimc.rs.resistor[1].n.v:VARIABLE(flow=false unit = "V" ) = aimc.rs.plug_n.pin[1].v "Potential at the pin" type: Real [3]
131: aimc.strayLoad.plug_n.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
132: aimc.rs.resistor[3].p.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
133: aimc.strayLoad.plug_n.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
134: aimc.rs.resistor[2].p.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
135: aimc.strayLoad.plug_n.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
136: aimc.rs.resistor[1].p.v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
137: aimc.lssigma.spacePhasor_b.v_[2]:VARIABLE(flow=false unit = "V" ) = aimc.airGapS.spacePhasor_s.v_[2] "1=real, 2=imaginary part" type: Real [2]
138: aimc.lssigma.spacePhasor_b.v_[1]:VARIABLE(flow=false unit = "V" ) = aimc.airGapS.spacePhasor_s.v_[1] "1=real, 2=imaginary part" type: Real [2]
139: aimc.squirrelCageR.spacePhasor_r.v_[2]:VARIABLE(flow=false unit = "V" ) = aimc.airGapS.spacePhasor_r.v_[2] "1=real, 2=imaginary part" type: Real [2]
140: aimc.squirrelCageR.spacePhasor_r.v_[1]:VARIABLE(flow=false unit = "V" ) = aimc.airGapS.spacePhasor_r.v_[1] "1=real, 2=imaginary part" type: Real [2]
141: aimc.airGapS.i_rr[2]:VARIABLE(unit = "A" ) = aimc.idq_rr[2] "Rotor current space phasor with respect to the rotor fixed frame" type: Real [2]
142: aimc.airGapS.spacePhasor_r.i_[2]:VARIABLE(flow=true unit = "A" ) = aimc.idq_rr[2] "1=real, 2=imaginary part" type: Real [2]
143: aimc.squirrelCageR.spacePhasor_r.i_[2]:DUMMY_STATE(flow=true unit = "A" ) = -aimc.idq_rr[2] "1=real, 2=imaginary part" type: Real [2]
144: aimc.ir[2]:VARIABLE(unit = "A" ) = aimc.idq_rr[2] "Rotor cage currents" type: Real [2]
145: aimc.airGapS.i_rr[1]:VARIABLE(unit = "A" ) = aimc.idq_rr[1] "Rotor current space phasor with respect to the rotor fixed frame" type: Real [2]
146: aimc.airGapS.spacePhasor_r.i_[1]:VARIABLE(flow=true unit = "A" ) = aimc.idq_rr[1] "1=real, 2=imaginary part" type: Real [2]
147: aimc.squirrelCageR.spacePhasor_r.i_[1]:DUMMY_STATE(flow=true unit = "A" ) = -aimc.idq_rr[1] "1=real, 2=imaginary part" type: Real [2]
148: aimc.ir[1]:VARIABLE(unit = "A" ) = aimc.idq_rr[1] "Rotor cage currents" type: Real [2]
149: aimc.lssigma.spacePhasor_a.i_[2]:VARIABLE(flow=true unit = "A" ) = aimc.lssigma.i_[2] "1=real, 2=imaginary part" type: Real [2]
150: aimc.lssigma.spacePhasor_b.i_[2]:VARIABLE(flow=true unit = "A" ) = -aimc.lssigma.i_[2] "1=real, 2=imaginary part" type: Real [2]
151: aimc.airGapS.spacePhasor_s.i_[2]:VARIABLE(flow=true unit = "A" ) = aimc.lssigma.i_[2] "1=real, 2=imaginary part" type: Real [2]
152: aimc.airGapS.i_ss[2]:VARIABLE(unit = "A" ) = aimc.lssigma.i_[2] "Stator current space phasor with respect to the stator fixed frame" type: Real [2]
153: aimc.idq_ss[2]:VARIABLE(unit = "A" ) = aimc.lssigma.i_[2] "Stator space phasor current / stator fixed frame" type: Real [2]
154: aimc.lssigma.spacePhasor_a.i_[1]:VARIABLE(flow=true unit = "A" ) = aimc.lssigma.i_[1] "1=real, 2=imaginary part" type: Real [2]
155: aimc.lssigma.spacePhasor_b.i_[1]:VARIABLE(flow=true unit = "A" ) = -aimc.lssigma.i_[1] "1=real, 2=imaginary part" type: Real [2]
156: aimc.airGapS.spacePhasor_s.i_[1]:VARIABLE(flow=true unit = "A" ) = aimc.lssigma.i_[1] "1=real, 2=imaginary part" type: Real [2]
157: aimc.airGapS.i_ss[1]:VARIABLE(unit = "A" ) = aimc.lssigma.i_[1] "Stator current space phasor with respect to the stator fixed frame" type: Real [2]
158: aimc.idq_ss[1]:VARIABLE(unit = "A" ) = aimc.lssigma.i_[1] "Stator space phasor current / stator fixed frame" type: Real [2]
159: aimc.thermalAmbient.temperatureFriction.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.powerBalance.lossPowerFriction "Heat flow rate (positive if flowing from outside into the component)" type: Real
160: aimc.thermalAmbient.thermalPort.heatPortFriction.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.powerBalance.lossPowerFriction "Heat flow rate (positive if flowing from outside into the component)" type: Real
161: aimc.thermalAmbient.temperatureStrayLoad.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.strayLoad.lossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real
162: aimc.thermalAmbient.thermalPort.heatPortStrayLoad.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.strayLoad.lossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real
163: aimc.thermalAmbient.thermalPort.heatPortRotorCore.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.internalThermalPort.heatPortRotorCore.Q_flow "Heat flow rate (positive if flowing from outside into the component)" type: Real
164: aimc.thermalAmbient.temperatureRotorCore.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.internalThermalPort.heatPortRotorCore.Q_flow "Heat flow rate (positive if flowing from outside into the component)" type: Real
165: aimc.thermalAmbient.Q_flowRotorCore:VARIABLE(unit = "W" final = true ) = aimc.internalThermalPort.heatPortRotorCore.Q_flow "Heat flow rate of stator core losses" type: Real
166: aimc.thermalAmbient.temperatureStatorCore.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.statorCore.lossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real
167: aimc.thermalAmbient.thermalPort.heatPortStatorCore.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.statorCore.lossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real
168: aimc.thermalAmbient.thermalPort.heatPortStatorWinding[1].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[1].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
169: aimc.thermalAmbient.thermalPort.heatPortStatorWinding[2].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[2].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
170: aimc.thermalAmbient.thermalPort.heatPortStatorWinding[3].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[3].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
171: aimc.thermalAmbient.temperatureRotorWinding.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.thermalAmbient.Q_flowRotorWinding "Heat flow rate (positive if flowing from outside into the component)" type: Real
172: aimc.thermalAmbient.thermalPort.heatPortRotorWinding.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.thermalAmbient.Q_flowRotorWinding "Heat flow rate (positive if flowing from outside into the component)" type: Real
173: aimc.thermalAmbient.temperatureStatorWinding.port.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.thermalAmbient.Q_flowStatorWinding "Heat flow rate (positive if flowing from outside into the component)" type: Real
174: aimc.thermalAmbient.thermalCollectorStator.port_b.Q_flow:VARIABLE(flow=true unit = "W" final = true ) = -aimc.thermalAmbient.Q_flowStatorWinding "Heat flow rate (positive if flowing from outside into the component)" type: Real
175: aimc.inertiaRotor.flange_a.tau:VARIABLE(flow=true unit = "N.m" ) = aimc.tauElectrical "Cut torque in the flange" type: Real
176: aimc.airGapS.flange.tau:VARIABLE(flow=true unit = "N.m" ) = -aimc.tauElectrical "Cut torque in the flange" type: Real
177: aimc.airGapS.tauElectrical:VARIABLE(unit = "N.m" ) = aimc.tauElectrical type: Real
178: aimc.airGapS.support.tau:VARIABLE(flow=true unit = "N.m" ) = aimc.tauElectrical "Cut torque in the flange" type: Real
179: aimc.rs.resistor[1].heatPort.Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[1].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
180: aimc.rs.heatPort[1].Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[1].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
181: aimc.rs.resistor[2].heatPort.Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[2].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
182: aimc.rs.heatPort[2].Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[2].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
183: aimc.rs.resistor[3].heatPort.Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[3].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
184: aimc.rs.heatPort[3].Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.rs.resistor[3].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
185: aimc.spacePhasorS.zero.i:VARIABLE(flow=true unit = "A" ) = aimc.i_0_s "Current flowing into the pin" type: Real
186: aimc.lszero.p.i:VARIABLE(flow=true unit = "A" ) = -aimc.i_0_s "Current flowing into the pin" type: Real
187: aimc.lszero.i:DUMMY_STATE(start = 0.0 unit = "A" ) = -aimc.i_0_s "Current flowing from pin p to pin n" type: Real
188: aimc.lszero.n.i:VARIABLE(flow=true unit = "A" ) = aimc.i_0_s "Current flowing into the pin" type: Real
189: aimc.spacePhasorS.ground.i:VARIABLE(flow=true unit = "A" ) = -aimc.i_0_s "Current flowing into the pin" type: Real
190: terminalBox.star.pin_n.i:VARIABLE(flow=true unit = "A" ) = terminalBox.starpoint.i "Current flowing into the pin" type: Real
191: sinevoltage1.sineVoltage[3].signalSource.y:VARIABLE() = sinevoltage1.v[3] "Connector of Real output signal" type: Real [3]
192: sinevoltage1.sineVoltage[2].signalSource.y:VARIABLE() = sinevoltage1.v[2] "Connector of Real output signal" type: Real [3]
193: sinevoltage1.sineVoltage[1].signalSource.y:VARIABLE() = sinevoltage1.v[1] "Connector of Real output signal" type: Real [3]
194: aimc.squirrelCageR.heatPort.Q_flow:VARIABLE(flow=true unit = "W" ) = -aimc.thermalAmbient.Q_flowRotorWinding "Heat flow rate (positive if flowing from outside into the component)" type: Real
195: aimc.powerBalance.lossPowerRotorWinding:VARIABLE(unit = "W" final = true ) = aimc.thermalAmbient.Q_flowRotorWinding "Rotor copper losses" type: Real
196: aimc.airGapS.RotationMatrix[1,1]:VARIABLE() = aimc.airGapS.RotationMatrix[2,2] "Matrix of rotation from rotor to stator" type: Real [2,2]
197: aimc.airGapS.RotationMatrix[1,2]:VARIABLE() = -$cse1 "Matrix of rotation from rotor to stator" type: Real [2,2]
198: aimc.strayLoad.support.tau:VARIABLE(flow=true unit = "N.m" ) = aimc.strayLoad.tau "Cut torque in the flange" type: Real
199: aimc.powerBalance.lossPowerStrayLoad:VARIABLE(unit = "W" final = true ) = aimc.strayLoad.lossPower "Stray load losses" type: Real
200: aimc.powerBalance.lossPowerStatorCore:VARIABLE(unit = "W" final = true ) = aimc.statorCore.lossPower "Stator core losses" type: Real
201: aimc.airGapS.i_rs[2]:VARIABLE(unit = "A" ) = aimc.idq_rs[2] "Rotor current space phasor with respect to the stator fixed frame" type: Real [2]
202: aimc.airGapS.i_rs[1]:VARIABLE(unit = "A" ) = aimc.idq_rs[1] "Rotor current space phasor with respect to the stator fixed frame" type: Real [2]
203: aimc.airGapS.i_sr[2]:VARIABLE(unit = "A" ) = aimc.idq_sr[2] "Stator current space phasor with respect to the rotor fixed frame" type: Real [2]
204: aimc.airGapS.i_sr[1]:VARIABLE(unit = "A" ) = aimc.idq_sr[1] "Stator current space phasor with respect to the rotor fixed frame" type: Real [2]
205: aimc.friction.lossPower:VARIABLE(unit = "W" ) = aimc.powerBalance.lossPowerFriction "Loss power leaving component via heatPort (> 0, if heat is flowing out of component)" type: Real
206: aimc.friction.support.tau:VARIABLE(flow=true unit = "N.m" ) = aimc.friction.tau "Cut torque in the flange" type: Real
207: speedSensor.w:VARIABLE(unit = "rad/s" ) = aimc.inertiaRotor.w "Absolute angular velocity of flange as output signal" type: Real
208: aimc.thermalAmbient.Q_flowFriction:VARIABLE(unit = "W" final = true ) = aimc.powerBalance.lossPowerFriction "Heat flow rate of friction losses" type: Real
209: aimc.lszero.p.v:VARIABLE(flow=false unit = "V" ) = aimc.lszero.v "Potential at the pin" type: Real
210: aimc.thermalAmbient.Q_flowStatorCore:VARIABLE(unit = "W" final = true ) = aimc.statorCore.lossPower "Heat flow rate of stator core losses" type: Real
211: aimc.thermalAmbient.Q_flowStrayLoad:VARIABLE(unit = "W" final = true ) = aimc.strayLoad.lossPower "Heat flow rate of stray load losses" type: Real
212: aimc.plug_sp.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
213: aimc.rs.plug_p.pin[1].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[1] "Potential at the pin" type: Real [3]
214: sinevoltage1.sineVoltage[1].v:VARIABLE(unit = "V" ) = sinevoltage1.v[1] "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
215: aimc.plug_sp.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
216: aimc.rs.plug_p.pin[2].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[2] "Potential at the pin" type: Real [3]
217: sinevoltage1.sineVoltage[2].v:VARIABLE(unit = "V" ) = sinevoltage1.v[2] "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
218: aimc.plug_sp.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
219: aimc.rs.plug_p.pin[3].v:VARIABLE(flow=false unit = "V" ) = -sinevoltage1.v[3] "Potential at the pin" type: Real [3]
220: sinevoltage1.sineVoltage[3].v:VARIABLE(unit = "V" ) = sinevoltage1.v[3] "Voltage drop between the two pins (= p.v - n.v)" type: Real [3]
221: aimc.spacePhasorS.spacePhasor.i_[1]:VARIABLE(flow=true unit = "A" ) = -aimc.lssigma.i_[1] "1=real, 2=imaginary part" type: Real [2]
222: aimc.spacePhasorS.spacePhasor.i_[2]:VARIABLE(flow=true unit = "A" ) = -aimc.lssigma.i_[2] "1=real, 2=imaginary part" type: Real [2]
223: aimc.thermalAmbient.thermalCollectorStator.port_a[3].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[3].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
224: aimc.thermalAmbient.thermalCollectorStator.port_a[2].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[2].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
225: aimc.thermalAmbient.thermalCollectorStator.port_a[1].Q_flow:VARIABLE(flow=true unit = "W" final = true ) = aimc.rs.resistor[1].LossPower "Heat flow rate (positive if flowing from outside into the component)" type: Real [3]
226: aimc.squirrelCageR.LossPower:VARIABLE(unit = "W" ) = aimc.thermalAmbient.Q_flowRotorWinding "Loss power leaving component via HeatPort" type: Real
227: aimc.thermalAmbient.thermalPort.heatPortStrayLoad.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureStrayLoad.port.T "Port temperature" type: Real
228: aimc.internalThermalPort.heatPortStrayLoad.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureStrayLoad.port.T "Port temperature" type: Real
229: aimc.strayLoad.heatPort.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 ) = aimc.thermalAmbient.temperatureStrayLoad.port.T "Port temperature" type: Real
230: aimc.thermalAmbient.thermalPort.heatPortStatorCore.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureStatorCore.port.T "Port temperature" type: Real
231: aimc.internalThermalPort.heatPortStatorCore.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureStatorCore.port.T "Port temperature" type: Real
232: aimc.statorCore.heatPort.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 ) = aimc.thermalAmbient.temperatureStatorCore.port.T "Port temperature" type: Real
233: aimc.thermalAmbient.thermalPort.heatPortRotorCore.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureRotorCore.port.T "Port temperature" type: Real
234: aimc.internalThermalPort.heatPortRotorCore.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureRotorCore.port.T "Port temperature" type: Real
235: aimc.thermalAmbient.thermalPort.heatPortFriction.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureFriction.port.T "Port temperature" type: Real
236: aimc.friction.heatPort.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 ) = aimc.thermalAmbient.temperatureFriction.port.T "Port temperature" type: Real
237: aimc.internalThermalPort.heatPortFriction.T:VARIABLE(flow=false min = 0.0 start = 288.15 unit = "K" nominal = 300.0 final = true ) = aimc.thermalAmbient.temperatureFriction.port.T "Port temperature" type: Real
Zero Crossings (3)
========================================
time < sinevoltage1.sineVoltage[3].signalSource.startTime with index = 0 in equations [24]
time < sinevoltage1.sineVoltage[2].signalSource.startTime with index = 1 in equations [25]
time < sinevoltage1.sineVoltage[1].signalSource.startTime with index = 2 in equations [26]
Relations (3)
========================================
time < sinevoltage1.sineVoltage[3].signalSource.startTime with index = 0 in equations [24]
time < sinevoltage1.sineVoltage[2].signalSource.startTime with index = 1 in equations [25]
time < sinevoltage1.sineVoltage[1].signalSource.startTime with index = 2 in equations [26]
record SimulationResult
resultFile = "asmaFlow_res.mat",
simulationOptions = "startTime = 0.0, stopTime = 20.0, numberOfIntervals = 10000, tolerance = 1e-6, method = 'dassl', fileNamePrefix = 'asmaFlow', options = '', outputFormat = 'mat', variableFilter = '.*', cflags = '', simflags = ''",
messages = "LOG_STDOUT | info | Using sparse solver for linear system 1,
| | | | because density of 0.101 remains under threshold of 0.200.
LOG_STDOUT | info | Using sparse solver for linear system 4,
| | | | because density of 0.101 remains under threshold of 0.200.
LOG_STDOUT | info | The maximum density for using sparse solvers can be specified
| | | | using the runtime flag '<-lssMaxDensity=value>'.
LOG_SUCCESS | info | The initialization finished successfully without homotopy method.
LOG_SUCCESS | info | The simulation finished successfully.
"
end SimulationResult;
"[Modelica 3.2.1+maint.om/Electrical/Machines.mo:4746:9-4748:76:writable] Warning: Parameter aimc.TrOperational has no value, and is fixed during initialization (fixed=true), using available start value (start=293.15) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:4743:9-4745:73:writable] Warning: Parameter aimc.alpha20r has no value, and is fixed during initialization (fixed=true), using available start value (start=0.0) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:4740:9-4742:73:writable] Warning: Parameter aimc.TrRef has no value, and is fixed during initialization (fixed=true), using available start value (start=293.15) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:10940:7-10941:52:writable] Warning: Parameter aimc.strayLoadParameters.IRef has no value, and is fixed during initialization (fixed=true), using available start value (start=100.0) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:10964:7-10965:79:writable] Warning: Parameter aimc.statorCoreParameters.VRef has no value, and is fixed during initialization (fixed=true), using available start value (start=100.0) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:12803:7-12804:76:writable] Warning: Parameter aimc.Js has no value, and is fixed during initialization (fixed=true), using available start value (start=aimc.Jr) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:12927:7-12929:71:writable] Warning: Parameter aimc.alpha20s has no value, and is fixed during initialization (fixed=true), using available start value (start=0.0) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:12924:7-12926:71:writable] Warning: Parameter aimc.TsRef has no value, and is fixed during initialization (fixed=true), using available start value (start=293.15) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:12918:7-12920:69:writable] Warning: Parameter aimc.TsOperational has no value, and is fixed during initialization (fixed=true), using available start value (start=293.15) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:15348:7-15350:33:writable] Warning: Parameter terminalBox.terminalConnection has no value, and is fixed during initialization (fixed=true), using available start value (start=\"Y\") as default value.
Warning: The initial conditions are not fully specified. For more information set -d=initialization. In OMEdit Tools->Options->Simulation->Show additional information from the initialization process, in OMNotebook call setCommandLineOptions(\"-d=initialization\").
"
-15.0
-15.0
Equation mismatch: diff says:
--- /tmp/omc-rtest-unknown/simulation/modelica/start_value_selection/asmaFlow.mos_temp3747/equations-expected2024-01-13 02:56:55.677451318 +0000
+++ /tmp/omc-rtest-unknown/simulation/modelica/start_value_selection/asmaFlow.mos_temp3747/equations-got2024-01-13 02:57:14.333591501 +0000
@@ -501,23 +501,10 @@
========================================
aimc.inertiaRotor.phi -> speedSensor.w
aimc.inertiaStator.phi -> 0.0
aimc.inertiaStator.w -> 0.0
-Unreplaceable Crefs: (2)
-========================================
-$res_LSJac0_2.$pDERLSJac0.dummyVarLSJac0
-$res_LSJac0_1.$pDERLSJac0.dummyVarLSJac0
-
-Unreplaceable Crefs: (5)
-========================================
-$res_LSJac1_5.$pDERLSJac1.dummyVarLSJac1
-$res_LSJac1_4.$pDERLSJac1.dummyVarLSJac1
-$res_LSJac1_3.$pDERLSJac1.dummyVarLSJac1
-$res_LSJac1_2.$pDERLSJac1.dummyVarLSJac1
-$res_LSJac1_1.$pDERLSJac1.dummyVarLSJac1
-
Unreplaceable Crefs: (1)
========================================
$cse1
Replacements: (20)
@@ -567,23 +554,10 @@
$DER.ground.p -> 0.0
$DER.aimc.airGapS -> 0.0
$DER.aimc.airGapS.psi_mr -> 0.0
$DER.aimc.airGapS.psi_ms -> 0.0
-Unreplaceable Crefs: (2)
-========================================
-$res_LSJac2_2.$pDERLSJac2.dummyVarLSJac2
-$res_LSJac2_1.$pDERLSJac2.dummyVarLSJac2
-
-Unreplaceable Crefs: (5)
-========================================
-$res_LSJac3_5.$pDERLSJac3.dummyVarLSJac3
-$res_LSJac3_4.$pDERLSJac3.dummyVarLSJac3
-$res_LSJac3_3.$pDERLSJac3.dummyVarLSJac3
-$res_LSJac3_2.$pDERLSJac3.dummyVarLSJac3
-$res_LSJac3_1.$pDERLSJac3.dummyVarLSJac3
-
########################################
dumpindxdae
########################################
@@ -1151,13 +1125,11 @@
{5:17}
{32:67}
{6:82}
{7:35}
{8:34}
-{{{22:3}, {21:25}, {20:1}, {18:2}}
-,{17, 19:26, 27}} Size: 2 linear
-For more information please use "-d=tearingdump".
+{21, 19, 22, 17, 20, 18:2, 25, 1, 3, 27, 26} Size: 6 Jacobian Linear
{37:45}
{39:42}
{85:85}
{38:39}
{34:44}
@@ -1186,13 +1158,11 @@
{47:63}
{89:89}
{15:18}
{16:19}
{31:68}
-{{{74:30}, {73:29}, {72:28}, {56:32}, {71:33}, {55:31}, {54:81}, {69:37}, {70:79}, {59:14}, {58:13}, {60:49}, {65:48}, {64:69}, {61:70}, {68:71}, {67:72}, {57:36}, {63:80}, {75:73}, {51:77}, {76:74}, {50:75}}
-,{62, 49, 53, 52, 66:78, 76, 15, 16, 47}} Size: 5 linear
-For more information please use "-d=tearingdump".
+{64, 68, 67, 66, 69, 70, 52, 53, 75, 49, 76, 51, 63, 57, 56, 74, 73, 71, 55, 54, 72, 62, 61, 60, 59, 58, 65, 50:75, 48, 13, 15, 14, 49, 70, 28, 81, 31, 33, 29, 47, 30, 32, 36, 80, 77, 74, 73, 76, 78, 79, 37, 16, 72, 71, 69} Size: 28 Jacobian Linear
{91:91}
{93:93}
{90:90}
{77:57}
{78:56}
@@ -1271,11 +1241,11 @@
57: aimc.statorCore.heatPort.Q_flow:VARIABLE(flow=true unit = "W" fixed = true ) = -0.0 "Heat flow rate (positive if flowing from outside into the component)" type: Real
58: aimc.strayLoad.heatPort.Q_flow:VARIABLE(flow=true unit = "W" fixed = true ) = -0.0 "Heat flow rate (positive if flowing from outside into the component)" type: Real
59: aimc.strayLoad.flange.tau:VARIABLE(flow=true unit = "N.m" fixed = true ) = -0.0 "Cut torque in the flange" type: Real
60: sinevoltage1.freqHz[3]:PARAM(start = 1.0 unit = "Hz" ) = 50.0 "Frequencies of sine waves" type: Real [3]
61: sinevoltage1.sineVoltage[3].freqHz:PARAM(start = 1.0 unit = "Hz" ) = sinevoltage1.freqHz[3] "Frequency of sine wave" type: Real [3]
-62: sinevoltage1.phase[3]:PARAM(unit = "rad" ) = -4.188790204786391 "Phases of sine waves" type: Real [3]
+62: sinevoltage1.phase[3]:PARAM(unit = "rad" ) = -4.1887902047863905 "Phases of sine waves" type: Real [3]
63: sinevoltage1.sineVoltage[3].phase:PARAM(unit = "rad" ) = sinevoltage1.phase[3] "Phase of sine wave" type: Real [3]
64: sinevoltage1.V[3]:PARAM(start = 1.0 unit = "V" ) = 187.794213613377 "Amplitudes of sine waves" type: Real [3]
65: sinevoltage1.sineVoltage[3].V:PARAM(start = 1.0 unit = "V" ) = sinevoltage1.V[3] "Amplitude of sine wave" type: Real [3]
66: sinevoltage1.sineVoltage[3].signalSource.pi:CONST(protected = true ) = 3.141592653589793 type: Real [3]
67: sinevoltage1.startTime[3]:PARAM(unit = "s" ) = 0.0 "Time offsets" type: Real [3]
@@ -1287,11 +1257,11 @@
73: sinevoltage1.sineVoltage[3].signalSource.phase:PARAM(unit = "rad" ) = sinevoltage1.sineVoltage[3].phase "Phase of sine wave" type: Real [3]
74: sinevoltage1.sineVoltage[3].signalSource.freqHz:PARAM(start = 1.0 unit = "Hz" ) = sinevoltage1.sineVoltage[3].freqHz "Frequency of sine wave" type: Real [3]
75: sinevoltage1.sineVoltage[3].signalSource.amplitude:PARAM() = sinevoltage1.sineVoltage[3].V "Amplitude of sine wave" type: Real [3]
76: sinevoltage1.freqHz[2]:PARAM(start = 1.0 unit = "Hz" ) = 50.0 "Frequencies of sine waves" type: Real [3]
77: sinevoltage1.sineVoltage[2].freqHz:PARAM(start = 1.0 unit = "Hz" ) = sinevoltage1.freqHz[2] "Frequency of sine wave" type: Real [3]
-78: sinevoltage1.phase[2]:PARAM(unit = "rad" ) = -2.094395102393195 "Phases of sine waves" type: Real [3]
+78: sinevoltage1.phase[2]:PARAM(unit = "rad" ) = -2.0943951023931953 "Phases of sine waves" type: Real [3]
79: sinevoltage1.sineVoltage[2].phase:PARAM(unit = "rad" ) = sinevoltage1.phase[2] "Phase of sine wave" type: Real [3]
80: sinevoltage1.V[2]:PARAM(start = 1.0 unit = "V" ) = 187.794213613377 "Amplitudes of sine waves" type: Real [3]
81: sinevoltage1.sineVoltage[2].V:PARAM(start = 1.0 unit = "V" ) = sinevoltage1.V[2] "Amplitude of sine wave" type: Real [3]
82: sinevoltage1.sineVoltage[2].signalSource.pi:CONST(protected = true ) = 3.141592653589793 type: Real [3]
83: sinevoltage1.startTime[2]:PARAM(unit = "s" ) = 0.0 "Time offsets" type: Real [3]
@@ -1338,11 +1308,11 @@
124: aimc.alpha20r:PARAM(start = 0.0 unit = "1/K" ) "Temperature coefficient of rotor resistance at 20 degC" type: Real
125: aimc.squirrelCageR.alpha:PARAM(unit = "1/K" ) = aimc.alpha20r / (1.0 + aimc.alpha20r * (-293.15 + aimc.TrRef)) "Temperature coefficient of resistance at T_ref" type: Real
126: aimc.squirrelCageR.T_ref:PARAM(min = 0.0 start = 288.15 unit = "K" nominal = 300.0 ) = aimc.TrRef "Reference temperature" type: Real
127: aimc.Rr:PARAM(start = 0.04 unit = "Ohm" ) = 0.4 "Rotor resistance per phase (equivalent three phase winding) at TRef" type: Real
128: aimc.squirrelCageR.Rr:PARAM(unit = "Ohm" ) = aimc.Rr "Rotor resistance per phase translated to stator at T_ref" type: Real
-129: aimc.Lrsigma:PARAM(start = 0.1017764061411688 / (6.283185307179586 * aimc.fsNominal) unit = "H" ) = 0.002 "Rotor stray inductance per phase (equivalent three phase winding)" type: Real
+129: aimc.Lrsigma:PARAM(start = 0.10177640614116878 / (6.283185307179586 * aimc.fsNominal) unit = "H" ) = 0.002 "Rotor stray inductance per phase (equivalent three phase winding)" type: Real
130: aimc.squirrelCageR.Lrsigma:PARAM(unit = "H" ) = aimc.Lrsigma "Rotor stray inductance per phase translated to stator" type: Real
131: aimc.squirrelCageR.T:PARAM(min = 0.0 start = 288.15 unit = "K" nominal = 300.0 ) = aimc.TrRef "Fixed device temperature if useHeatPort = false" type: Real
132: aimc.squirrelCageR.useHeatPort:PARAM(final = true ) = true "=true, if HeatPort is enabled" type: Boolean
133: aimc.Lm:PARAM(start = 2.898223593858831 / (6.283185307179586 * aimc.fsNominal) unit = "H" ) = 0.06931 "Stator main field inductance per phase" type: Real
134: aimc.airGapS.Lm:PARAM(unit = "H" ) = aimc.Lm "Main field inductance" type: Real
@@ -1376,29 +1346,29 @@
162: aimc.spacePhasorS.InverseTransformation[1,1]:PARAM(protected = true ) = 1.0 type: Real [3,2]
163: aimc.spacePhasorS.TransformationMatrix[2,3]:PARAM(protected = true ) = -0.5773502691896255 type: Real [2,3]
164: aimc.spacePhasorS.TransformationMatrix[2,2]:PARAM(protected = true ) = 0.5773502691896257 type: Real [2,3]
165: aimc.spacePhasorS.TransformationMatrix[2,1]:PARAM(protected = true ) = 0.0 type: Real [2,3]
166: aimc.spacePhasorS.TransformationMatrix[1,3]:PARAM(protected = true ) = -0.3333333333333336 type: Real [2,3]
-167: aimc.spacePhasorS.TransformationMatrix[1,2]:PARAM(protected = true ) = -0.3333333333333331 type: Real [2,3]
+167: aimc.spacePhasorS.TransformationMatrix[1,2]:PARAM(protected = true ) = -0.33333333333333315 type: Real [2,3]
168: aimc.spacePhasorS.TransformationMatrix[1,1]:PARAM(protected = true ) = 0.6666666666666666 type: Real [2,3]
169: aimc.spacePhasorS.turnsRatio:PARAM() = 1.0 "Turns ratio" type: Real
170: aimc.spacePhasorS.pi:CONST() = 3.141592653589793 type: Real
171: aimc.spacePhasorS.m:CONST() = 3 "Number of phases" type: Integer
172: aimc.statorCore.turnsRatio:PARAM(min = 1e-60 ) = 1.0 "Effective number of stator turns / effective number of rotor turns (if used as rotor core)" type: Real
173: aimc.statorCoreParameters.m:PARAM() = 3 "Number of phases (1 for DC, 3 for induction machines)" type: Integer
174: aimc.statorCore.coreParameters.m:PARAM() = aimc.statorCoreParameters.m "Number of phases (1 for DC, 3 for induction machines)" type: Integer
175: aimc.statorCore.m:PARAM(final = true ) = aimc.statorCore.coreParameters.m "Number of phases" type: Integer
-176: aimc.statorCoreParameters.wMin:PARAM(unit = "rad/s" final = true ) = 1e-06 * aimc.statorCoreParameters.wRef type: Real
+176: aimc.statorCoreParameters.wMin:PARAM(unit = "rad/s" final = true ) = 1e-6 * aimc.statorCoreParameters.wRef type: Real
177: aimc.statorCore.coreParameters.wMin:PARAM(unit = "rad/s" final = true ) = aimc.statorCoreParameters.wMin type: Real
178: aimc.statorCore.coreParameters.GcRef:PARAM(unit = "S" final = true ) = 0.0 "Reference conductance at reference frequency and voltage" type: Real
179: aimc.statorCore.coreParameters.ratioHysteresis:PARAM(min = 0.0 max = 1.0 start = 0.775 final = true ) = 0.0 "Ratio of hysteresis losses with respect to the total core losses at VRef and fRef" type: Real
180: aimc.statorCore.coreParameters.wRef:PARAM(min = 1e-60 unit = "rad/s" ) = aimc.statorCoreParameters.wRef "Reference angular velocity that reference core losses PRef refer to" type: Real
181: aimc.statorCoreParameters.VRef:PARAM(min = 1e-60 start = 100.0 unit = "V" ) "Reference inner RMS voltage that reference core losses PRef refer to" type: Real
182: aimc.statorCore.coreParameters.VRef:PARAM(min = 1e-60 unit = "V" ) = aimc.statorCoreParameters.VRef "Reference inner RMS voltage that reference core losses PRef refer to" type: Real
183: aimc.statorCore.coreParameters.PRef:PARAM(min = 0.0 unit = "W" final = true ) = 0.0 "Reference core losses at reference inner voltage VRef" type: Real
184: aimc.statorCore.useHeatPort:PARAM(final = true ) = true "=true, if heatPort is enabled" type: Boolean
-185: aimc.Lssigma:PARAM(start = 0.1017764061411688 / (6.283185307179586 * aimc.fsNominal) unit = "H" ) = 0.004 "Stator stray inductance per phase" type: Real
+185: aimc.Lssigma:PARAM(start = 0.10177640614116878 / (6.283185307179586 * aimc.fsNominal) unit = "H" ) = 0.004 "Stator stray inductance per phase" type: Real
186: aimc.Lszero:PARAM(unit = "H" ) = aimc.Lssigma "Stator zero sequence inductance" type: Real
187: aimc.lszero.L:PARAM(start = 1.0 unit = "H" ) = aimc.Lszero "Inductance" type: Real
188: aimc.lssigma.L[2]:PARAM(unit = "H" ) = aimc.Lssigma "Inductance of both axes" type: Real [2]
189: aimc.lssigma.L[1]:PARAM(unit = "H" ) = aimc.Lssigma "Inductance of both axes" type: Real [2]
190: aimc.TsRef:PARAM(min = 0.0 start = 293.15 unit = "K" nominal = 300.0 ) "Reference temperature of stator resistance" type: Real
@@ -1772,12 +1742,18 @@
time < sinevoltage1.sineVoltage[1].signalSource.startTime with index = 2 in equations [26]
record SimulationResult
resultFile = "asmaFlow_res.mat",
-simulationOptions = "startTime = 0.0, stopTime = 20.0, numberOfIntervals = 10000, tolerance = 1e-06, method = 'dassl', fileNamePrefix = 'asmaFlow', options = '', outputFormat = 'mat', variableFilter = '.*', cflags = '', simflags = ''",
-messages = "LOG_SUCCESS | info | The initialization finished successfully without homotopy method.
+simulationOptions = "startTime = 0.0, stopTime = 20.0, numberOfIntervals = 10000, tolerance = 1e-6, method = 'dassl', fileNamePrefix = 'asmaFlow', options = '', outputFormat = 'mat', variableFilter = '.*', cflags = '', simflags = ''",
+messages = "LOG_STDOUT | info | Using sparse solver for linear system 1,
+| | | | because density of 0.101 remains under threshold of 0.200.
+LOG_STDOUT | info | Using sparse solver for linear system 4,
+| | | | because density of 0.101 remains under threshold of 0.200.
+LOG_STDOUT | info | The maximum density for using sparse solvers can be specified
+| | | | using the runtime flag '<-lssMaxDensity=value>'.
+LOG_SUCCESS | info | The initialization finished successfully without homotopy method.
LOG_SUCCESS | info | The simulation finished successfully.
"
end SimulationResult;
"[Modelica 3.2.1+maint.om/Electrical/Machines.mo:4746:9-4748:76:writable] Warning: Parameter aimc.TrOperational has no value, and is fixed during initialization (fixed=true), using available start value (start=293.15) as default value.
[Modelica 3.2.1+maint.om/Electrical/Machines.mo:4743:9-4745:73:writable] Warning: Parameter aimc.alpha20r has no value, and is fixed during initialization (fixed=true), using available start value (start=0.0) as default value.
Equation mismatch: omc-diff says:
Line 506: Integer 2 != 1
== 1 out of 1 tests failed [simulation/modelica/start_value_selection/asmaFlow.mos_temp3747, time: 19]