bancada-motores/Simulink/VF Control/VFControl_sg_rtw/VFControl.h
Pedro Jose Romero Gombau 3e7835e670 Proyecto
2024-10-25 16:51:18 +02:00

863 lines
38 KiB
C
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/*
* VFControl.h
*
* Academic License - for use in teaching, academic research, and meeting
* course requirements at degree granting institutions only. Not for
* government, commercial, or other organizational use.
*
* Code generation for model "VFControl".
*
* Model version : 1.1
* Simulink Coder version : 24.1 (R2024a) 19-Nov-2023
* C++ source code generated on : Wed Oct 16 11:33:22 2024
*
* Target selection: speedgoat.tlc
* Note: GRT includes extra infrastructure and instrumentation for prototyping
* Embedded hardware selection: Intel->x86-64 (Linux 64)
* Code generation objectives: Unspecified
* Validation result: Not run
*/
#ifndef VFControl_h_
#define VFControl_h_
#include "rtwtypes.h"
#include "simstruc.h"
#include "fixedpoint.h"
#include "sg_fpga_io30x_setup_util.h"
#include "sg_fpga_io31x_io32x_setup_util.h"
#include "sg_fpga_io33x_setup_util.h"
#include "sg_fpga_io36x_setup_util.h"
#include "sg_fpga_io39x_setup_util.h"
#include "sg_fpga_io3xx_scatter_gather_dma.h"
#include "sg_common.h"
#include "sg_printf.h"
#include "VFControl_types.h"
#include "PWMGenerator.h"
#include <stddef.h>
#include "rtGetNaN.h"
#include <cstring>
#include "VFControl_cal.h"
extern "C"
{
#include "rt_nonfinite.h"
}
/* Macros for accessing real-time model data structure */
#ifndef rtmGetContTimeOutputInconsistentWithStateAtMajorStepFlag
#define rtmGetContTimeOutputInconsistentWithStateAtMajorStepFlag(rtm) ((rtm)->CTOutputIncnstWithState)
#endif
#ifndef rtmSetContTimeOutputInconsistentWithStateAtMajorStepFlag
#define rtmSetContTimeOutputInconsistentWithStateAtMajorStepFlag(rtm, val) ((rtm)->CTOutputIncnstWithState = (val))
#endif
#ifndef rtmGetDerivCacheNeedsReset
#define rtmGetDerivCacheNeedsReset(rtm) ((rtm)->derivCacheNeedsReset)
#endif
#ifndef rtmSetDerivCacheNeedsReset
#define rtmSetDerivCacheNeedsReset(rtm, val) ((rtm)->derivCacheNeedsReset = (val))
#endif
#ifndef rtmGetFinalTime
#define rtmGetFinalTime(rtm) ((rtm)->Timing.tFinal)
#endif
#ifndef rtmGetSampleHitArray
#define rtmGetSampleHitArray(rtm) ((rtm)->Timing.sampleHitArray)
#endif
#ifndef rtmGetStepSize
#define rtmGetStepSize(rtm) ((rtm)->Timing.stepSize)
#endif
#ifndef rtmGetZCCacheNeedsReset
#define rtmGetZCCacheNeedsReset(rtm) ((rtm)->zCCacheNeedsReset)
#endif
#ifndef rtmSetZCCacheNeedsReset
#define rtmSetZCCacheNeedsReset(rtm, val) ((rtm)->zCCacheNeedsReset = (val))
#endif
#ifndef rtmGet_TimeOfLastOutput
#define rtmGet_TimeOfLastOutput(rtm) ((rtm)->Timing.timeOfLastOutput)
#endif
#ifndef rtmCounterLimit
#define rtmCounterLimit(rtm, idx) ((rtm)->Timing.TaskCounters.cLimit[(idx)])
#endif
#ifndef rtmGetErrorStatus
#define rtmGetErrorStatus(rtm) ((rtm)->errorStatus)
#endif
#ifndef rtmSetErrorStatus
#define rtmSetErrorStatus(rtm, val) ((rtm)->errorStatus = (val))
#endif
#ifndef rtmGetErrorStatusPointer
#define rtmGetErrorStatusPointer(rtm) ((const char_T **)(&((rtm)->errorStatus)))
#endif
#ifndef rtmStepTask
#define rtmStepTask(rtm, idx) ((rtm)->Timing.TaskCounters.TID[(idx)] == 0)
#endif
#ifndef rtmGetStopRequested
#define rtmGetStopRequested(rtm) ((rtm)->Timing.stopRequestedFlag)
#endif
#ifndef rtmSetStopRequested
#define rtmSetStopRequested(rtm, val) ((rtm)->Timing.stopRequestedFlag = (val))
#endif
#ifndef rtmGetStopRequestedPtr
#define rtmGetStopRequestedPtr(rtm) (&((rtm)->Timing.stopRequestedFlag))
#endif
#ifndef rtmGetT
#define rtmGetT(rtm) (rtmGetTPtr((rtm))[0])
#endif
#ifndef rtmGetTFinal
#define rtmGetTFinal(rtm) ((rtm)->Timing.tFinal)
#endif
#ifndef rtmGetTPtr
#define rtmGetTPtr(rtm) ((rtm)->Timing.t)
#endif
#ifndef rtmGetTStart
#define rtmGetTStart(rtm) ((rtm)->Timing.tStart)
#endif
#ifndef rtmTaskCounter
#define rtmTaskCounter(rtm, idx) ((rtm)->Timing.TaskCounters.TID[(idx)])
#endif
#ifndef rtmGetTimeOfLastOutput
#define rtmGetTimeOfLastOutput(rtm) ((rtm)->Timing.timeOfLastOutput)
#endif
/* Block signals (default storage) */
struct B_VFControl_T {
real_T xk1[4]; /* '<S23>/fluxes' */
real_T Gain[4]; /* '<S21>/Gain' */
real_T fluxes[4]; /* '<S21>/fluxes' */
real_T Sum2[4]; /* '<S21>/Sum2' */
real_T Linv[16]; /* '<S16>/Switch' */
real_T Product3[4]; /* '<S16>/Product3' */
real_T Rotoranglethetam; /* '<S15>/Rotor angle thetam' */
real_T wm_delay; /* '<S38>/wm_delay' */
real_T F2; /* '<S38>/F2' */
real_T wm_predict; /* '<S38>/wm_predict' */
real_T Sum1; /* '<S38>/Sum1' */
real_T MultiportSwitch[4]; /* '<S19>/Multiport Switch' */
real_T MultiportSwitch_p[2]; /* '<S18>/Multiport Switch' */
real_T MultiportSwitch1[2]; /* '<S18>/Multiport Switch1' */
real_T ib[4]; /* '<S18>/ib' */
real_T GainVr_Vs1[2]; /* '<S13>/Gain Vr_Vs1' */
real_T StateSpace_o1[14]; /* '<S96>/State-Space' */
real_T StateSpace_o2[6]; /* '<S96>/State-Space' */
real_T iqsids[2]; /* '<S20>/1-1' */
real_T Mult1[2]; /* '<S20>/Mult1' */
real_T Sum2_k; /* '<S20>/Sum2' */
real_T Switch2; /* '<S16>/Switch2' */
real_T GainVr_Vs[2]; /* '<S13>/Gain Vr_Vs' */
real_T u_Vb[4]; /* '<S17>/1_Vb' */
real_T MultiportSwitch1_f[2]; /* '<S17>/Multiport Switch1' */
real_T MultiportSwitch_p2[2]; /* '<S17>/Multiport Switch' */
real_T voltages[4]; /* '<S23>/voltages' */
real_T DigitalClock; /* '<S23>/Digital Clock' */
real_T IC[4]; /* '<S23>/IC' */
real_T Sum2_l; /* '<S18>/Sum2' */
real_T Sum3; /* '<S18>/Sum3' */
real_T unitconversion[19]; /* '<S13>/unit conversion' */
real_T up; /* '<S15>/1\p' */
real_T wTethr[3]; /* '<S15>/1\p1' */
real_T Unitconversion; /* '<S15>/Unit conversion' */
real_T F; /* '<S15>/F' */
real_T Sum; /* '<S15>/Sum' */
real_T u_2H; /* '<S15>/1_2H' */
real_T Rotorspeedwm; /* '<S15>/Rotor speed(wm)' */
real_T web_psb; /* '<S15>/web_psb' */
real_T DigitalClock_k; /* '<S57>/Digital Clock' */
real_T LookUpTable; /* '<S57>/Look-Up Table' */
real_T Toff; /* '<S56>/Step1' */
real_T Ton; /* '<S56>/Step' */
real_T DiscreteTimeIntegrator1; /* '<S47>/Discrete-Time Integrator1' */
real_T UnitDelay1; /* '<S47>/Unit Delay1' */
real_T Switch2_d; /* '<S56>/Switch2' */
real_T Switch3; /* '<S56>/Switch3' */
real_T Switch2_a; /* '<S41>/Switch2' */
real_T Sum3_e; /* '<S41>/Sum3' */
real_T Switch1; /* '<S49>/Switch1' */
real_T Switch5[3]; /* '<S50>/Switch5' */
real_T t; /* '<S42>/t' */
real_T Gain_p; /* '<S42>/Gain' */
real_T Product; /* '<S42>/Product' */
real_T DiscreteTimeIntegrator; /* '<S42>/Discrete-Time Integrator' */
real_T Sum_n; /* '<S42>/Sum' */
real_T Gain3; /* '<S45>/Gain3' */
real_T Switch3_o; /* '<S45>/Switch3' */
real_T Sum2_j[3]; /* '<S45>/Sum2' */
real_T Switch1_a[3]; /* '<S54>/Switch1' */
real_T Switch5_b[3]; /* '<S55>/Switch5' */
real_T Sum7[3]; /* '<S40>/Sum7' */
real_T TrigonometricFunction1[3]; /* '<S40>/Trigonometric Function1' */
real_T Product2[3]; /* '<S40>/Product2' */
real_T Ton_e; /* '<S51>/Step' */
real_T Toff_e; /* '<S51>/Step1' */
real_T Sum4; /* '<S51>/Sum4' */
real_T DataTypeConversion; /* '<S51>/Data Type Conversion' */
real_T Gain1; /* '<S52>/Gain1' */
real_T Gain3_f; /* '<S52>/Gain3' */
real_T Sum1_m; /* '<S52>/Sum1' */
real_T MultiportSwitch_h[3]; /* '<S52>/Multiport Switch' */
real_T Sum_j[3]; /* '<S52>/Sum' */
real_T TrigonometricFunction1_d[3]; /* '<S52>/Trigonometric Function1' */
real_T Product1[3]; /* '<S52>/Product1' */
real_T Gain1_m; /* '<S53>/Gain1' */
real_T Gain3_a; /* '<S53>/Gain3' */
real_T Sum1_m3; /* '<S53>/Sum1' */
real_T MultiportSwitch_n[3]; /* '<S53>/Multiport Switch' */
real_T Sum_i[3]; /* '<S53>/Sum' */
real_T TrigonometricFunction1_c[3]; /* '<S53>/Trigonometric Function1' */
real_T Product1_i[3]; /* '<S53>/Product1' */
real_T Sum4_o[3]; /* '<S43>/Sum4' */
real_T Sum8[3]; /* '<S40>/Sum8' */
real_T Clock; /* '<S73>/Clock' */
real_T Add1; /* '<S73>/Add1' */
real_T MathFunction; /* '<S73>/Math Function' */
real_T uib1; /* '<S73>/1\ib1' */
real_T uDLookupTable; /* '<S73>/1-D Lookup Table' */
real_T Add3; /* '<S73>/Add3' */
real_T Model_o1; /* '<Root>/Model' */
real_T Model_o2; /* '<Root>/Model' */
real_T Model_o3; /* '<Root>/Model' */
real_T DigitalClock_m; /* '<S74>/Digital Clock' */
real_T Add1_e; /* '<S74>/Add1' */
real_T MathFunction_l; /* '<S74>/Math Function' */
real_T uib1_h; /* '<S74>/1\ib1' */
real_T uDLookupTable_b; /* '<S74>/1-D Lookup Table' */
real_T Add3_h; /* '<S74>/Add3' */
real_T Model1_o1; /* '<Root>/Model1' */
real_T Model1_o2; /* '<Root>/Model1' */
real_T Model1_o3; /* '<Root>/Model1' */
real_T DigitalClock_ms; /* '<S75>/Digital Clock' */
real_T Add1_l; /* '<S75>/Add1' */
real_T MathFunction_o; /* '<S75>/Math Function' */
real_T uib1_e; /* '<S75>/1\ib1' */
real_T uDLookupTable_bk; /* '<S75>/1-D Lookup Table' */
real_T Add3_n; /* '<S75>/Add3' */
real_T Model2_o1; /* '<Root>/Model2' */
real_T Model2_o2; /* '<Root>/Model2' */
real_T Model2_o3; /* '<Root>/Model2' */
real_T TransportDelay; /* '<S3>/Transport Delay' */
real_T TransportDelay_i; /* '<S4>/Transport Delay' */
real_T TransportDelay_n; /* '<S5>/Transport Delay' */
real_T Switch; /* '<S84>/Switch' */
real_T Saturation[6]; /* '<S76>/Saturation' */
real_T DataTypeConversion_p[6]; /* '<S76>/Data Type Conversion' */
real_T DataTypeConversion1; /* '<S76>/Data Type Conversion1' */
real_T Product4[6]; /* '<S76>/Product4' */
real_T DataTypeConversion_f; /* '<S84>/Data Type Conversion' */
real_T Switch_e; /* '<S86>/Switch' */
real_T DataTypeConversion_l; /* '<S86>/Data Type Conversion' */
real_T Switch_k; /* '<S88>/Switch' */
real_T DataTypeConversion_h; /* '<S88>/Data Type Conversion' */
real_T Switch_i; /* '<S90>/Switch' */
real_T DataTypeConversion_k; /* '<S90>/Data Type Conversion' */
real_T Switch_a; /* '<S92>/Switch' */
real_T DataTypeConversion_i; /* '<S92>/Data Type Conversion' */
real_T Switch_a4; /* '<S94>/Switch' */
real_T DataTypeConversion_c; /* '<S94>/Data Type Conversion' */
real_T Product_n; /* '<S3>/Product' */
real_T Product_b; /* '<S4>/Product' */
real_T Product_l; /* '<S5>/Product' */
real_T Switch4; /* '<S42>/Switch4' */
real_T Gain2; /* '<S42>/Gain2' */
real_T Sum1_o; /* '<S42>/Sum1' */
real_T Gain3_m[3]; /* '<S40>/Gain3' */
real_T wtrad; /* '<S44>/Math Function' */
real_T Switch_c; /* '<S56>/Switch' */
real_T donotdeletethisgain; /* '<S64>/do not delete this gain' */
real_T donotdeletethisgain_k; /* '<S65>/do not delete this gain' */
real_T donotdeletethisgain_o; /* '<S66>/do not delete this gain' */
real_T Kv1[3]; /* '<S7>/Kv1' */
real_T donotdeletethisgain_kv; /* '<S61>/do not delete this gain' */
real_T donotdeletethisgain_b; /* '<S62>/do not delete this gain' */
real_T donotdeletethisgain_h; /* '<S63>/do not delete this gain' */
real_T Kv[3]; /* '<S7>/Kv' */
real_T UnitDelay; /* '<S73>/Unit Delay' */
real_T uRsw; /* '<S94>/1//Rsw' */
real_T uRsw_n; /* '<S92>/1//Rsw' */
real_T uRsw_i; /* '<S90>/1//Rsw' */
real_T uRsw_g; /* '<S88>/1//Rsw' */
real_T uRsw_c; /* '<S86>/1//Rsw' */
real_T uRsw_k; /* '<S84>/1//Rsw' */
real_T Switch1_j; /* '<S56>/Switch1' */
real_T MultiportSwitch1_b; /* '<S56>/Multiport Switch1' */
real_T Gain1_f; /* '<S56>/Gain1' */
real_T Product1_f; /* '<S56>/Product1' */
real_T TrigonometricFunction1_l; /* '<S56>/Trigonometric Function1' */
real_T Mod; /* '<S56>/Product' */
real_T Step; /* '<S56>/Product2' */
real_T Gain4; /* '<S45>/Gain4' */
real_T Gain3_n; /* '<S54>/Gain3' */
real_T Sum2_lw[3]; /* '<S54>/Sum2' */
real_T Constant[2]; /* '<S37>/Constant' */
real_T Gain3_e; /* '<S37>/Gain3' */
real_T TrigonometricFunction_o1; /* '<S37>/Trigonometric Function' */
real_T TrigonometricFunction_o2; /* '<S37>/Trigonometric Function' */
real_T W34wr[16]; /* '<S37>/W(3,4)=-wr' */
real_T W43wr[16]; /* '<S37>/W(4,3)=wr' */
real_T Constant_e[2]; /* '<S36>/Constant' */
real_T Gain1_e; /* '<S36>/Gain1' */
real_T TrigonometricFunction_o1_d; /* '<S36>/Trigonometric Function' */
real_T TrigonometricFunction_o2_j; /* '<S36>/Trigonometric Function' */
real_T W12wr[16]; /* '<S36>/W(1,2)=wr' */
real_T W21wr[16]; /* '<S36>/W(2,1)=-wr' */
real_T DigitalClock_kx; /* '<S35>/Digital Clock' */
real_T wewr; /* '<S35>/Sum' */
real_T Gain2_k; /* '<S35>/Gain2' */
real_T th; /* '<S35>/web_psb' */
real_T beta; /* '<S35>/Sum1' */
real_T TrigonometricFunction_o1_dn; /* '<S35>/Trigonometric Function' */
real_T TrigonometricFunction_o2_k; /* '<S35>/Trigonometric Function' */
real_T TrigonometricFunction1_o1; /* '<S35>/Trigonometric Function1' */
real_T TrigonometricFunction1_o2; /* '<S35>/Trigonometric Function1' */
real_T W341wr[16]; /* '<S35>/W(3,4)=1-wr' */
real_T W43wr1[16]; /* '<S35>/W(4,3)=wr-1' */
real_T ira; /* '<S34>/ira' */
real_T irb; /* '<S34>/irb' */
real_T isa; /* '<S34>/isa' */
real_T isb; /* '<S34>/isb' */
real_T ira_g; /* '<S33>/ira' */
real_T irb_g; /* '<S33>/irb' */
real_T isa_a; /* '<S33>/isa' */
real_T isb_f; /* '<S33>/isb' */
real_T ira_p; /* '<S32>/ira' */
real_T irb_n; /* '<S32>/irb' */
real_T isa_m; /* '<S32>/isa' */
real_T isb_p; /* '<S32>/isb' */
real_T vdr; /* '<S30>/vdr' */
real_T vds; /* '<S30>/vds' */
real_T vqr; /* '<S30>/vqr' */
real_T vqs; /* '<S30>/vqs' */
real_T vdr_p; /* '<S29>/vdr' */
real_T vds_i; /* '<S29>/vds' */
real_T vqr_l; /* '<S29>/vqr' */
real_T vqs_i; /* '<S29>/vqs' */
real_T vdr_l; /* '<S28>/vdr' */
real_T vds_f; /* '<S28>/vds' */
real_T vqr_j; /* '<S28>/vqr' */
real_T vqs_l; /* '<S28>/vqs' */
real_T ukuk1[4]; /* '<S23>/sum' */
real_T RLinv[16]; /* '<S16>/Switch1' */
real_T MultiportSwitch1_l[16]; /* '<S19>/Multiport Switch1' */
real_T A[16]; /* '<S16>/Sum1' */
real_T wbaseTs2[16]; /* '<S27>/wbase*Ts//2' */
real_T Sum1_k[16]; /* '<S27>/Sum1' */
real_T inversion[16]; /* '<S27>/inversion' */
real_T wbaseTs2_c[16]; /* '<S27>/wbase*Ts//2 ' */
real_T Product1_d[4]; /* '<S23>/Product1' */
real_T Sum5[16]; /* '<S27>/Sum5' */
real_T Product4_k[16]; /* '<S27>/Product4' */
real_T Product2_o[4]; /* '<S23>/Product2' */
real_T xk[4]; /* '<S23>/Ad*x(k-1) + Bd*( u(k-1) + u(k))' */
real_T Delay; /* '<S22>/Delay' */
real_T TmpSignalConversionAtMathFuncti[3];
real_T MathFunction_p[3]; /* '<S24>/Math Function' */
real_T Sum2_i; /* '<S24>/Sum2' */
real_T MathFunction1; /* '<S24>/Math Function1' */
real_T Product2_m[2]; /* '<S26>/Product2' */
real_T Product_c[2]; /* '<S26>/Product' */
real_T phimq; /* '<S26>/Sum2' */
real_T Product1_j[2]; /* '<S26>/Product1' */
real_T phimd; /* '<S26>/Sum1' */
real_T Phisat; /* '<S22>/Math Function' */
real_T Isat; /* '<S22>/1-D Lookup Table' */
real_T Switch_g; /* '<S22>/Switch' */
real_T Lminrows13col13[16]; /* '<S25>/Lm in rows[1,3] & col[1,3]' */
real_T Lminrows24col24[16]; /* '<S25>/Lm in rows[2,4] & col[2,4]' */
real_T Sum2_e[16]; /* '<S25>/Sum2' */
real_T Linv_h[16]; /* '<S22>/inversion' */
real_T RLinv_m[16]; /* '<S22>/Product1' */
real_T Lm; /* '<S22>/Product' */
boolean_T RelationalOperator3; /* '<S49>/Relational Operator3' */
boolean_T Amplitude; /* '<S46>/Relational Operator' */
boolean_T LogicalOperator1; /* '<S49>/Logical Operator1' */
boolean_T DataTypeConversion2; /* '<S56>/Data Type Conversion2' */
boolean_T LogicalOperator1_l; /* '<S56>/Logical Operator1' */
boolean_T RelationalOperator1; /* '<S56>/Relational Operator1' */
boolean_T DataTypeConversion1_f; /* '<S56>/Data Type Conversion1' */
boolean_T LogicalOperator; /* '<S56>/Logical Operator' */
boolean_T RelationalOperator3_f; /* '<S54>/Relational Operator3' */
boolean_T Phase; /* '<S46>/Relational Operator1' */
boolean_T LogicalOperator1_b; /* '<S54>/Logical Operator1' */
boolean_T DataTypeConversion1_j; /* '<S51>/Data Type Conversion1' */
boolean_T DataTypeConversion2_m; /* '<S51>/Data Type Conversion2' */
boolean_T LogicalOperator_l; /* '<S51>/Logical Operator' */
boolean_T Compare; /* '<S77>/Compare' */
boolean_T Frequency; /* '<S46>/Relational Operator2' */
boolean_T RelationalOperator; /* '<S56>/Relational Operator' */
};
/* Block states (default storage) for system '<Root>' */
struct DW_VFControl_T {
real_T fluxes_DSTATE[4]; /* '<S23>/fluxes' */
real_T fluxes_DSTATE_l[4]; /* '<S21>/fluxes' */
real_T Rotoranglethetam_DSTATE; /* '<S15>/Rotor angle thetam' */
real_T wm_delay_DSTATE; /* '<S38>/wm_delay' */
real_T wm_predict_DSTATE; /* '<S38>/wm_predict' */
real_T voltages_DSTATE[4]; /* '<S23>/voltages' */
real_T Rotorspeedwm_DSTATE; /* '<S15>/Rotor speed(wm)' */
real_T DiscreteTimeIntegrator1_DSTATE;/* '<S47>/Discrete-Time Integrator1' */
real_T UnitDelay1_DSTATE; /* '<S47>/Unit Delay1' */
real_T DiscreteTimeIntegrator_DSTATE;/* '<S42>/Discrete-Time Integrator' */
real_T UnitDelay_DSTATE; /* '<S73>/Unit Delay' */
real_T Delay_DSTATE; /* '<S22>/Delay' */
real_T inversion_DWORK1[16]; /* '<S27>/inversion' */
real_T inversion_DWORK3[16]; /* '<S27>/inversion' */
real_T inversion_DWORK4[16]; /* '<S27>/inversion' */
real_T inversion_DWORK4_k[16]; /* '<S22>/inversion' */
struct {
real_T modelTStart;
real_T TUbufferArea[2048];
} TransportDelay_RWORK; /* '<S3>/Transport Delay' */
struct {
real_T modelTStart;
real_T TUbufferArea[2048];
} TransportDelay_RWORK_d; /* '<S4>/Transport Delay' */
struct {
real_T modelTStart;
real_T TUbufferArea[2048];
} TransportDelay_RWORK_m; /* '<S5>/Transport Delay' */
struct {
void *AS;
void *BS;
void *CS;
void *DS;
void *DX_COL;
void *BD_COL;
void *TMP1;
void *TMP2;
void *XTMP;
void *SWITCH_STATUS;
void *SWITCH_STATUS_INIT;
void *SW_CHG;
void *G_STATE;
void *USWLAST;
void *XKM12;
void *XKP12;
void *XLAST;
void *ULAST;
void *IDX_SW_CHG;
void *Y_SWITCH;
void *SWITCH_TYPES;
void *IDX_OUT_SW;
void *SWITCH_TOPO_SAVED_IDX;
void *SWITCH_MAP;
} StateSpace_PWORK; /* '<S96>/State-Space' */
struct {
void *LoggedData[3];
} DebugPWM_PWORK; /* '<Root>/Debug PWM' */
struct {
void *LoggedData[4];
} DebugfaseA_PWORK; /* '<Root>/Debug fase A' */
struct {
void *LoggedData[4];
} DebugfaseB_PWORK; /* '<Root>/Debug fase B' */
struct {
void *LoggedData[4];
} DebugfaseC_PWORK; /* '<Root>/Debug fase C' */
struct {
void *TUbufferPtrs[2];
} TransportDelay_PWORK; /* '<S3>/Transport Delay' */
struct {
void *TUbufferPtrs[2];
} TransportDelay_PWORK_m; /* '<S4>/Transport Delay' */
struct {
void *TUbufferPtrs[2];
} TransportDelay_PWORK_f; /* '<S5>/Transport Delay' */
void *Digitaloutput1_PWORK[2]; /* '<Root>/Digital output1' */
void *Digitaloutput2_PWORK[2]; /* '<Root>/Digital output2' */
struct {
void *LoggedData[2];
} Corrientetensinmotorideal_PWORK;
/* '<Root>/Corriente//tensi<73>n motor ideal' */
struct {
void *USERIO_P_IND;
void *PROG_SPACE_P_IND;
void *CONFIG_REGISTER_P_IND;
void *CONDITIONING_MODULE_IO3xx_2x_P_IND;
void *DEVICENAME_P_IND;
void *DMA_CONTROLLER_P_IND;
} Setup_PWORK; /* '<Root>/Setup' */
int32_T inversion_DWORK2[4]; /* '<S27>/inversion' */
uint32_T m_bpIndex; /* '<S73>/1-D Lookup Table' */
uint32_T m_bpIndex_e; /* '<S74>/1-D Lookup Table' */
uint32_T m_bpIndex_p; /* '<S75>/1-D Lookup Table' */
uint32_T m_bpIndex_b; /* '<S22>/1-D Lookup Table' */
int_T StateSpace_IWORK[11]; /* '<S96>/State-Space' */
struct {
int_T Tail;
int_T Head;
int_T Last;
int_T CircularBufSize;
} TransportDelay_IWORK; /* '<S3>/Transport Delay' */
struct {
int_T Tail;
int_T Head;
int_T Last;
int_T CircularBufSize;
} TransportDelay_IWORK_g; /* '<S4>/Transport Delay' */
struct {
int_T Tail;
int_T Head;
int_T Last;
int_T CircularBufSize;
} TransportDelay_IWORK_m; /* '<S5>/Transport Delay' */
struct {
int_T MODULEARCHITECTURE_I_IND;
} Setup_IWORK; /* '<Root>/Setup' */
int8_T sinthrcosthr1_SubsysRanBC; /* '<S19>/sin(thr),cos(thr)1' */
int8_T sinthrcosthr_SubsysRanBC; /* '<S19>/sin(thr),cos(thr)' */
int8_T sinbetacosbetasinthcosth_Subsys;
/* '<S19>/sin(beta),cos(beta),sin(th),cos(th)' */
int8_T Synchronousreferenceframe_Subsy;/* '<S18>/Synchronous reference frame' */
int8_T Stationaryreferenceframe_Subsys;/* '<S18>/Stationary reference frame' */
int8_T Rotorreferenceframe_SubsysRanBC;/* '<S18>/Rotor reference frame' */
int8_T Synchronousreferenceframe_Sub_k;/* '<S17>/Synchronous reference frame' */
int8_T Stationaryreferenceframe_Subs_n;/* '<S17>/Stationary reference frame' */
int8_T Rotorreferenceframe_SubsysRan_i;/* '<S17>/Rotor reference frame' */
int8_T Saturation_SubsysRanBC; /* '<S16>/Saturation' */
uint8_T Rotorspeedwm_SYSTEM_ENABLE; /* '<S15>/Rotor speed(wm)' */
boolean_T sinthrcosthr1_MODE; /* '<S19>/sin(thr),cos(thr)1' */
boolean_T sinthrcosthr_MODE; /* '<S19>/sin(thr),cos(thr)' */
boolean_T Synchronousreferenceframe_MODE;/* '<S18>/Synchronous reference frame' */
boolean_T Stationaryreferenceframe_MODE;/* '<S18>/Stationary reference frame' */
boolean_T Rotorreferenceframe_MODE; /* '<S18>/Rotor reference frame' */
boolean_T Synchronousreferenceframe_MOD_l;/* '<S17>/Synchronous reference frame' */
boolean_T Stationaryreferenceframe_MODE_p;/* '<S17>/Stationary reference frame' */
boolean_T Rotorreferenceframe_MODE_m;/* '<S17>/Rotor reference frame' */
MdlrefDW_PWMGenerator_T Model_InstanceData;/* '<Root>/Model' */
MdlrefDW_PWMGenerator_T Model1_InstanceData;/* '<Root>/Model1' */
MdlrefDW_PWMGenerator_T Model2_InstanceData;/* '<Root>/Model2' */
};
/* Real-time Model Data Structure */
struct tag_RTM_VFControl_T {
struct SimStruct_tag * *childSfunctions;
const char_T *errorStatus;
SS_SimMode simMode;
RTWSolverInfo solverInfo;
RTWSolverInfo *solverInfoPtr;
void *sfcnInfo;
/*
* NonInlinedSFcns:
* The following substructure contains information regarding
* non-inlined s-functions used in the model.
*/
struct {
RTWSfcnInfo sfcnInfo;
time_T *taskTimePtrs[3];
SimStruct childSFunctions[2];
SimStruct *childSFunctionPtrs[2];
struct _ssBlkInfo2 blkInfo2[2];
struct _ssSFcnModelMethods2 methods2[2];
struct _ssSFcnModelMethods3 methods3[2];
struct _ssSFcnModelMethods4 methods4[2];
struct _ssStatesInfo2 statesInfo2[2];
ssPeriodicStatesInfo periodicStatesInfo[2];
struct _ssPortInfo2 inputOutputPortInfo2[2];
struct {
time_T sfcnPeriod[1];
time_T sfcnOffset[1];
int_T sfcnTsMap[1];
struct _ssPortInputs inputPortInfo[3];
struct _ssInPortUnit inputPortUnits[3];
struct _ssInPortCoSimAttribute inputPortCoSimAttribute[3];
uint_T attribs[6];
mxArray *params[6];
struct _ssDWorkRecord dWork[1];
struct _ssDWorkAuxRecord dWorkAux[1];
} Sfcn0;
struct {
time_T sfcnPeriod[1];
time_T sfcnOffset[1];
int_T sfcnTsMap[1];
struct _ssPortInputs inputPortInfo[3];
struct _ssInPortUnit inputPortUnits[3];
struct _ssInPortCoSimAttribute inputPortCoSimAttribute[3];
uint_T attribs[6];
mxArray *params[6];
struct _ssDWorkRecord dWork[1];
struct _ssDWorkAuxRecord dWorkAux[1];
} Sfcn1;
} NonInlinedSFcns;
boolean_T zCCacheNeedsReset;
boolean_T derivCacheNeedsReset;
boolean_T CTOutputIncnstWithState;
/*
* Sizes:
* The following substructure contains sizes information
* for many of the model attributes such as inputs, outputs,
* dwork, sample times, etc.
*/
struct {
uint32_T options;
int_T numContStates;
int_T numU;
int_T numY;
int_T numSampTimes;
int_T numBlocks;
int_T numBlockIO;
int_T numBlockPrms;
int_T numDwork;
int_T numSFcnPrms;
int_T numSFcns;
int_T numIports;
int_T numOports;
int_T numNonSampZCs;
int_T sysDirFeedThru;
int_T rtwGenSfcn;
} Sizes;
/*
* Timing:
* The following substructure contains information regarding
* the timing information for the model.
*/
struct {
time_T stepSize;
uint32_T clockTick0;
uint32_T clockTickH0;
time_T stepSize0;
uint32_T clockTick1;
uint32_T clockTickH1;
time_T stepSize1;
uint32_T clockTick2;
uint32_T clockTickH2;
struct {
uint32_T TID[3];
uint32_T cLimit[3];
} TaskCounters;
time_T tStart;
time_T tFinal;
time_T timeOfLastOutput;
SimTimeStep simTimeStep;
boolean_T stopRequestedFlag;
time_T *sampleTimes;
time_T *offsetTimes;
int_T *sampleTimeTaskIDPtr;
int_T *sampleHits;
int_T *perTaskSampleHits;
time_T *t;
time_T sampleTimesArray[3];
time_T offsetTimesArray[3];
int_T sampleTimeTaskIDArray[3];
int_T sampleHitArray[3];
int_T perTaskSampleHitsArray[9];
time_T tArray[3];
} Timing;
};
/* Block signals (default storage) */
#ifdef __cplusplus
extern "C"
{
#endif
extern struct B_VFControl_T VFControl_B;
#ifdef __cplusplus
}
#endif
/* Block states (default storage) */
extern struct DW_VFControl_T VFControl_DW;
#ifdef __cplusplus
extern "C"
{
#endif
/* Model entry point functions */
extern void VFControl_initialize(void);
extern void VFControl_step0(void);
extern void VFControl_step2(void);
extern void VFControl_terminate(void);
#ifdef __cplusplus
}
#endif
/* Real-time Model object */
#ifdef __cplusplus
extern "C"
{
#endif
extern RT_MODEL_VFControl_T *const VFControl_M;
#ifdef __cplusplus
}
#endif
/*-
* The generated code includes comments that allow you to trace directly
* back to the appropriate location in the model. The basic format
* is <system>/block_name, where system is the system number (uniquely
* assigned by Simulink) and block_name is the name of the block.
*
* Use the MATLAB hilite_system command to trace the generated code back
* to the model. For example,
*
* hilite_system('<S3>') - opens system 3
* hilite_system('<S3>/Kp') - opens and selects block Kp which resides in S3
*
* Here is the system hierarchy for this model
*
* '<Root>' : 'VFControl'
* '<S1>' : 'VFControl/Asynchronous Machine SI Units'
* '<S2>' : 'VFControl/DC Voltage Source'
* '<S3>' : 'VFControl/Inversi<73>n A'
* '<S4>' : 'VFControl/Inversi<73>n B'
* '<S5>' : 'VFControl/Inversi<73>n C'
* '<S6>' : 'VFControl/Three-Phase Programmable Generator'
* '<S7>' : 'VFControl/Three-Phase V-I Measurement'
* '<S8>' : 'VFControl/Triangle Generator'
* '<S9>' : 'VFControl/Triangle Generator1'
* '<S10>' : 'VFControl/Triangle Generator2'
* '<S11>' : 'VFControl/Two-Level Converter1'
* '<S12>' : 'VFControl/powergui'
* '<S13>' : 'VFControl/Asynchronous Machine SI Units/Electrical model'
* '<S14>' : 'VFControl/Asynchronous Machine SI Units/Measurements'
* '<S15>' : 'VFControl/Asynchronous Machine SI Units/Mechanical model'
* '<S16>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model'
* '<S17>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/abc to dq transformation'
* '<S18>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/dq to abc transformation'
* '<S19>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/sin,cos'
* '<S20>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Electromagnetic Torque'
* '<S21>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Flux Prediction'
* '<S22>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Saturation'
* '<S23>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/phiqd_SR'
* '<S24>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Saturation/Laq=Lad'
* '<S25>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Saturation/Matrix L'
* '<S26>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/Saturation/phimqd'
* '<S27>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/Asynchronous Machine State-space model/phiqd_SR/Subsystem'
* '<S28>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/abc to dq transformation/Rotor reference frame'
* '<S29>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/abc to dq transformation/Stationary reference frame'
* '<S30>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/abc to dq transformation/Synchronous reference frame'
* '<S31>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/abc to dq transformation/transit'
* '<S32>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/dq to abc transformation/Rotor reference frame'
* '<S33>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/dq to abc transformation/Stationary reference frame'
* '<S34>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/dq to abc transformation/Synchronous reference frame'
* '<S35>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/sin,cos/sin(beta),cos(beta),sin(th),cos(th)'
* '<S36>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/sin,cos/sin(thr),cos(thr)'
* '<S37>' : 'VFControl/Asynchronous Machine SI Units/Electrical model/sin,cos/sin(thr),cos(thr)1'
* '<S38>' : 'VFControl/Asynchronous Machine SI Units/Mechanical model/Delay Prediction'
* '<S39>' : 'VFControl/DC Voltage Source/Model'
* '<S40>' : 'VFControl/Three-Phase Programmable Generator/Model'
* '<S41>' : 'VFControl/Three-Phase Programmable Generator/Model/Amplitude'
* '<S42>' : 'VFControl/Three-Phase Programmable Generator/Model/Frequency'
* '<S43>' : 'VFControl/Three-Phase Programmable Generator/Model/Harmonic Generation'
* '<S44>' : 'VFControl/Three-Phase Programmable Generator/Model/Measurements'
* '<S45>' : 'VFControl/Three-Phase Programmable Generator/Model/Phase'
* '<S46>' : 'VFControl/Three-Phase Programmable Generator/Model/Type of Variation selector'
* '<S47>' : 'VFControl/Three-Phase Programmable Generator/Model/Variation value (step ramp mod)'
* '<S48>' : 'VFControl/Three-Phase Programmable Generator/Model/Variation value (time table)'
* '<S49>' : 'VFControl/Three-Phase Programmable Generator/Model/Amplitude/Time-Amplitude pairs'
* '<S50>' : 'VFControl/Three-Phase Programmable Generator/Model/Amplitude/Variation on phase A only'
* '<S51>' : 'VFControl/Three-Phase Programmable Generator/Model/Harmonic Generation/Enable Harmonics'
* '<S52>' : 'VFControl/Three-Phase Programmable Generator/Model/Harmonic Generation/Harmonic A generation'
* '<S53>' : 'VFControl/Three-Phase Programmable Generator/Model/Harmonic Generation/Harmonic B generation'
* '<S54>' : 'VFControl/Three-Phase Programmable Generator/Model/Phase/Time-Phase pairs'
* '<S55>' : 'VFControl/Three-Phase Programmable Generator/Model/Phase/Variation on phase A only'
* '<S56>' : 'VFControl/Three-Phase Programmable Generator/Model/Variation value (step ramp mod)/Subsystem1'
* '<S57>' : 'VFControl/Three-Phase Programmable Generator/Model/Variation value (time table)/Model'
* '<S58>' : 'VFControl/Three-Phase V-I Measurement/Mode I'
* '<S59>' : 'VFControl/Three-Phase V-I Measurement/Mode V'
* '<S60>' : 'VFControl/Three-Phase V-I Measurement/Model'
* '<S61>' : 'VFControl/Three-Phase V-I Measurement/Model/I A:'
* '<S62>' : 'VFControl/Three-Phase V-I Measurement/Model/I B:'
* '<S63>' : 'VFControl/Three-Phase V-I Measurement/Model/I C:'
* '<S64>' : 'VFControl/Three-Phase V-I Measurement/Model/U AB:'
* '<S65>' : 'VFControl/Three-Phase V-I Measurement/Model/U BC:'
* '<S66>' : 'VFControl/Three-Phase V-I Measurement/Model/U CA:'
* '<S67>' : 'VFControl/Three-Phase V-I Measurement/Model/I A:/Model'
* '<S68>' : 'VFControl/Three-Phase V-I Measurement/Model/I B:/Model'
* '<S69>' : 'VFControl/Three-Phase V-I Measurement/Model/I C:/Model'
* '<S70>' : 'VFControl/Three-Phase V-I Measurement/Model/U AB:/Model'
* '<S71>' : 'VFControl/Three-Phase V-I Measurement/Model/U BC:/Model'
* '<S72>' : 'VFControl/Three-Phase V-I Measurement/Model/U CA:/Model'
* '<S73>' : 'VFControl/Triangle Generator/Model'
* '<S74>' : 'VFControl/Triangle Generator1/Model'
* '<S75>' : 'VFControl/Triangle Generator2/Model'
* '<S76>' : 'VFControl/Two-Level Converter1/Model'
* '<S77>' : 'VFControl/Two-Level Converter1/Model/Compare To Constant'
* '<S78>' : 'VFControl/Two-Level Converter1/Model/Sw1'
* '<S79>' : 'VFControl/Two-Level Converter1/Model/Sw2'
* '<S80>' : 'VFControl/Two-Level Converter1/Model/Sw3'
* '<S81>' : 'VFControl/Two-Level Converter1/Model/Sw4'
* '<S82>' : 'VFControl/Two-Level Converter1/Model/Sw5'
* '<S83>' : 'VFControl/Two-Level Converter1/Model/Sw6'
* '<S84>' : 'VFControl/Two-Level Converter1/Model/Sw1/Model'
* '<S85>' : 'VFControl/Two-Level Converter1/Model/Sw1/Model/Measurement list'
* '<S86>' : 'VFControl/Two-Level Converter1/Model/Sw2/Model'
* '<S87>' : 'VFControl/Two-Level Converter1/Model/Sw2/Model/Measurement list'
* '<S88>' : 'VFControl/Two-Level Converter1/Model/Sw3/Model'
* '<S89>' : 'VFControl/Two-Level Converter1/Model/Sw3/Model/Measurement list'
* '<S90>' : 'VFControl/Two-Level Converter1/Model/Sw4/Model'
* '<S91>' : 'VFControl/Two-Level Converter1/Model/Sw4/Model/Measurement list'
* '<S92>' : 'VFControl/Two-Level Converter1/Model/Sw5/Model'
* '<S93>' : 'VFControl/Two-Level Converter1/Model/Sw5/Model/Measurement list'
* '<S94>' : 'VFControl/Two-Level Converter1/Model/Sw6/Model'
* '<S95>' : 'VFControl/Two-Level Converter1/Model/Sw6/Model/Measurement list'
* '<S96>' : 'VFControl/powergui/EquivalentModel1'
* '<S97>' : 'VFControl/powergui/EquivalentModel1/Gates'
* '<S98>' : 'VFControl/powergui/EquivalentModel1/Sources'
* '<S99>' : 'VFControl/powergui/EquivalentModel1/Status'
* '<S100>' : 'VFControl/powergui/EquivalentModel1/Yout'
*/
#endif /* VFControl_h_ */