WOLFRAM SYSTEMMODELER

Resistor

Ideal linear electrical resistors

Diagram

Wolfram Language

In[1]:=
Click for copyable input
SystemModel["Modelica.Electrical.MultiPhase.Basic.Resistor"]
Out[1]:=

Information

This information is part of the Modelica Standard Library maintained by the Modelica Association.

Contains m resistors (Modelica.Electrical.Analog.Basic.Resistor)

Connectors (3)

plug_p

Type: PositivePlug

Description:

plug_n

Type: NegativePlug

Description:

heatPort

Type: HeatPort_a[mh]

Description: Conditional heat ports

Parameters (7)

m

Value: 3

Type: Integer

Description: Number of phases

mh

Value: m

Type: Integer

Description: Number of heatPorts=number of phases

useHeatPort

Value: false

Type: Boolean

Description: =true, if all heat ports are enabled

T

Value: T_ref

Type: Temperature[mh] (K)

Description: Fixed device temperatures if useHeatPort = false

R

Value:

Type: Resistance[m] (Ω)

Description: Resistances R_ref at temperatures T_ref

T_ref

Value: fill(300.15, m)

Type: Temperature[m] (K)

Description: Reference temperatures

alpha

Value: zeros(m)

Type: LinearTemperatureCoefficient[m] (¹/K)

Description: Temperature coefficients of resistances at reference temperatures

Components (1)

resistor

Type: Resistor[m]

Description:

Used in Examples (10)

SMEE_LoadDump

Test example: ElectricalExcitedSynchronousInductionMachine with voltage controller

TransformerTestbench

Transformer Testbench

TransformerYY

Test example with multiphase components

TransformerYD

Test example with multiphase components

TestSensors

ThyristorBridge2mPulse_DC_Drive

2*m pulse thyristor bridge feeding a DC drive

MultiPhaseTwoLevel_R

Multi phase DC to AC converter with R load

MultiPhaseTwoLevel_RL

Multi phase DC to AC converter with R-L load

EddyCurrentLosses

Comparison of equivalent circuits of eddy current loss models

MultiPhaseInductance

Multi phase inductance

Used in Components (51)

AIM_SquirrelCage

Asynchronous induction machine with squirrel cage rotor

AIM_SlipRing

Asynchronous induction machine with slipring rotor

SM_PermanentMagnet

Permanent magnet synchronous induction machine

SM_ElectricalExcited

Electrical excited synchronous induction machine with damper cage

SM_ReluctanceRotor

Synchronous induction machine with reluctance rotor and damper cage

Yy00

Transformer Yy0

Yy02

Transformer Yy2

Yy04

Transformer Yy4

Yy06

Transformer Yy6

Yy08

Transformer Yy8

Yy10

Transformer Yy10

Yd01

Transformer Yd1

Yd03

Transformer Yd3

Yd05

Transformer Yd5

Yd07

Transformer Yd7

Yd09

Transformer Yd9

Yd11

Transformer Yd11

Yz01

Transformer Yz1

Yz03

Transformer Yz3

Yz05

Transformer Yz5

Yz07

Transformer Yz7

Yz09

Transformer Yz9

Yz11

Transformer Yz11

Dy01

Transformer Dy1

Dy03

Transformer Dy3

Dy05

Transformer Dy5

Dy07

Transformer Dy7

Dy09

Transformer Dy9

Dy11

Transformer Dy11

Dd00

Transformer Dd0

Dd02

Transformer Dd2

Dd04

Transformer Dd4

Dd06

Transformer Dd6

Dd08

Transformer Dd8

Dd10

Transformer Dd10

Dz00

Transformer Dz0

Dz02

Transformer Dz2

Dz04

Transformer Dz4

Dz06

Transformer Dz6

Dz08

Transformer Dz8

Dz10

Transformer Dz10

BasicTransformer

Partial model of three-phase transformer

PartialBasicInductionMachine

Partial model for induction machine

PartialBasicTransformer

Partial model of three-phase transformer

SwitchedRheostat

Rheostat which is shortened after a given time

MultiStarResistance

Resistance connection of star points

SymmetricMultiPhaseWinding

Symmetric winding model coupling electrical and magnetic domain

SymmetricMultiPhaseCageWinding

Symmetrical rotor cage

SaliencyCageWinding

Rotor cage with saliency in d- and q-axis

SymmetricMultiPhaseCageWinding_obsolete

Symmetrical rotor cage

SaliencyCageWinding_obsolete

Rotor cage with saliency in d- and q-axis