hoverboard-firmware-hack-fo.../Src/BLDC_controller.c

2671 lines
80 KiB
C

/*
* File: BLDC_controller.c
*
* Code generated for Simulink model 'BLDC_controller'.
*
* Model version : 1.1199
* Simulink Coder version : 8.13 (R2017b) 24-Jul-2017
* C/C++ source code generated on : Sun Nov 3 12:28:16 2019
*
* Target selection: ert.tlc
* Embedded hardware selection: ARM Compatible->ARM Cortex
* Emulation hardware selection:
* Differs from embedded hardware (MATLAB Host)
* Code generation objectives:
* 1. Execution efficiency
* 2. RAM efficiency
* Validation result: Not run
*/
#include "BLDC_controller.h"
/* Named constants for Chart: '<S4>/F03_02_Control_Mode_Manager' */
#define IN_ACTIVE ((uint8_T)1U)
#define IN_NO_ACTIVE_CHILD ((uint8_T)0U)
#define IN_OPEN ((uint8_T)2U)
#define IN_SPEED_MODE ((uint8_T)1U)
#define IN_TORQUE_MODE ((uint8_T)2U)
#define IN_VOLTAGE_MODE ((uint8_T)3U)
#define OPEN_MODE ((uint8_T)0U)
#define SPD_MODE ((uint8_T)2U)
#define TRQ_MODE ((uint8_T)3U)
#define VLT_MODE ((uint8_T)1U)
#ifndef UCHAR_MAX
#include <limits.h>
#endif
#if ( UCHAR_MAX != (0xFFU) ) || ( SCHAR_MAX != (0x7F) )
#error Code was generated for compiler with different sized uchar/char. \
Consider adjusting Test hardware word size settings on the \
Hardware Implementation pane to match your compiler word sizes as \
defined in limits.h of the compiler. Alternatively, you can \
select the Test hardware is the same as production hardware option and \
select the Enable portable word sizes option on the Code Generation > \
Verification pane for ERT based targets, which will disable the \
preprocessor word size checks.
#endif
#if ( USHRT_MAX != (0xFFFFU) ) || ( SHRT_MAX != (0x7FFF) )
#error Code was generated for compiler with different sized ushort/short. \
Consider adjusting Test hardware word size settings on the \
Hardware Implementation pane to match your compiler word sizes as \
defined in limits.h of the compiler. Alternatively, you can \
select the Test hardware is the same as production hardware option and \
select the Enable portable word sizes option on the Code Generation > \
Verification pane for ERT based targets, which will disable the \
preprocessor word size checks.
#endif
#if ( UINT_MAX != (0xFFFFFFFFU) ) || ( INT_MAX != (0x7FFFFFFF) )
#error Code was generated for compiler with different sized uint/int. \
Consider adjusting Test hardware word size settings on the \
Hardware Implementation pane to match your compiler word sizes as \
defined in limits.h of the compiler. Alternatively, you can \
select the Test hardware is the same as production hardware option and \
select the Enable portable word sizes option on the Code Generation > \
Verification pane for ERT based targets, which will disable the \
preprocessor word size checks.
#endif
#if ( ULONG_MAX != (0xFFFFFFFFU) ) || ( LONG_MAX != (0x7FFFFFFF) )
#error Code was generated for compiler with different sized ulong/long. \
Consider adjusting Test hardware word size settings on the \
Hardware Implementation pane to match your compiler word sizes as \
defined in limits.h of the compiler. Alternatively, you can \
select the Test hardware is the same as production hardware option and \
select the Enable portable word sizes option on the Code Generation > \
Verification pane for ERT based targets, which will disable the \
preprocessor word size checks.
#endif
#if 0
/* Skip this size verification because of preprocessor limitation */
#if ( ULLONG_MAX != (0xFFFFFFFFFFFFFFFFULL) ) || ( LLONG_MAX != (0x7FFFFFFFFFFFFFFFLL) )
#error Code was generated for compiler with different sized ulong_long/long_long. \
Consider adjusting Test hardware word size settings on the \
Hardware Implementation pane to match your compiler word sizes as \
defined in limits.h of the compiler. Alternatively, you can \
select the Test hardware is the same as production hardware option and \
select the Enable portable word sizes option on the Code Generation > \
Verification pane for ERT based targets, which will disable the \
preprocessor word size checks.
#endif
#endif
uint8_T plook_u8u16_evencka(uint16_T u, uint16_T bp0, uint16_T bpSpace, uint32_T
maxIndex);
uint8_T plook_u8s16_evencka(int16_T u, int16_T bp0, uint16_T bpSpace, uint32_T
maxIndex);
uint8_T plook_u8s16u8n6_evenc_s(int16_T u, int16_T bp0, uint16_T bpSpace,
uint32_T maxIndex, uint8_T *fraction);
int16_T intrp1d_s16s32s32u8u8n6l_s(uint8_T bpIndex, uint8_T frac, const int16_T
table[]);
extern void Counter_Init(DW_Counter *localDW, int16_T rtp_z_cntInit);
extern int16_T Counter(int16_T rtu_inc, int16_T rtu_max, boolean_T rtu_rst,
DW_Counter *localDW);
extern void PI_clamp_fixdt_Reset(DW_PI_clamp_fixdt *localDW);
extern void PI_clamp_fixdt(int16_T rtu_err, uint16_T rtu_P, uint16_T rtu_I,
int16_T rtu_satMax, int16_T rtu_satMin, int32_T rtu_ext_limProt, int16_T
*rty_out, DW_PI_clamp_fixdt *localDW);
extern void Low_Pass_Filter_Reset(DW_Low_Pass_Filter *localDW);
extern void Low_Pass_Filter(const int16_T rtu_u[2], uint16_T rtu_coef, int16_T
rty_y[2], DW_Low_Pass_Filter *localDW);
extern void PI_clamp_fixdt_n_Reset(DW_PI_clamp_fixdt_c *localDW);
extern int16_T PI_clamp_fixdt_n(int16_T rtu_err, uint16_T rtu_P, uint16_T rtu_I,
int16_T rtu_satMax, int16_T rtu_satMin, int16_T rtu_ext_limProt,
DW_PI_clamp_fixdt_c *localDW);
extern void Counter_b_Init(DW_Counter_l *localDW, uint16_T rtp_z_cntInit);
extern uint16_T Counter_i(uint16_T rtu_inc, uint16_T rtu_max, boolean_T rtu_rst,
DW_Counter_l *localDW);
extern void either_edge_Reset(DW_either_edge *localDW);
extern boolean_T either_edge(boolean_T rtu_u, DW_either_edge *localDW);
extern void Debounce_Filter_Init(DW_Debounce_Filter *localDW);
extern void Debounce_Filter_Reset(DW_Debounce_Filter *localDW);
extern void Debounce_Filter(boolean_T rtu_u, uint16_T rtu_tAcv, uint16_T
rtu_tDeacv, boolean_T *rty_y, DW_Debounce_Filter *localDW);
uint8_T plook_u8u16_evencka(uint16_T u, uint16_T bp0, uint16_T bpSpace, uint32_T
maxIndex)
{
uint8_T bpIndex;
uint16_T fbpIndex;
/* Prelookup - Index only
Index Search method: 'even'
Extrapolation method: 'Clip'
Use previous index: 'off'
Use last breakpoint for index at or above upper limit: 'on'
Remove protection against out-of-range input in generated code: 'off'
*/
if (u <= bp0) {
bpIndex = 0U;
} else {
fbpIndex = (uint16_T)((uint32_T)(uint16_T)((uint32_T)u - bp0) / bpSpace);
if (fbpIndex < maxIndex) {
bpIndex = (uint8_T)fbpIndex;
} else {
bpIndex = (uint8_T)maxIndex;
}
}
return bpIndex;
}
uint8_T plook_u8s16_evencka(int16_T u, int16_T bp0, uint16_T bpSpace, uint32_T
maxIndex)
{
uint8_T bpIndex;
uint16_T fbpIndex;
/* Prelookup - Index only
Index Search method: 'even'
Extrapolation method: 'Clip'
Use previous index: 'off'
Use last breakpoint for index at or above upper limit: 'on'
Remove protection against out-of-range input in generated code: 'off'
*/
if (u <= bp0) {
bpIndex = 0U;
} else {
fbpIndex = (uint16_T)((uint32_T)(uint16_T)(u - bp0) / bpSpace);
if (fbpIndex < maxIndex) {
bpIndex = (uint8_T)fbpIndex;
} else {
bpIndex = (uint8_T)maxIndex;
}
}
return bpIndex;
}
uint8_T plook_u8s16u8n6_evenc_s(int16_T u, int16_T bp0, uint16_T bpSpace,
uint32_T maxIndex, uint8_T *fraction)
{
uint8_T bpIndex;
uint16_T uAdjust;
uint16_T fbpIndex;
/* Prelookup - Index and Fraction
Index Search method: 'even'
Extrapolation method: 'Clip'
Use previous index: 'off'
Use last breakpoint for index at or above upper limit: 'off'
Remove protection against out-of-range input in generated code: 'off'
Rounding mode: 'simplest'
*/
if (u <= bp0) {
bpIndex = 0U;
*fraction = 0U;
} else {
uAdjust = (uint16_T)(u - bp0);
fbpIndex = (uint16_T)((uint32_T)uAdjust / bpSpace);
if (fbpIndex < maxIndex) {
bpIndex = (uint8_T)fbpIndex;
*fraction = (uint8_T)(((uint32_T)(uint16_T)((uint32_T)uAdjust - (uint16_T)
((uint32_T)bpIndex * bpSpace)) << 6) / bpSpace);
} else {
bpIndex = (uint8_T)(maxIndex - 1U);
*fraction = 64U;
}
}
return bpIndex;
}
int16_T intrp1d_s16s32s32u8u8n6l_s(uint8_T bpIndex, uint8_T frac, const int16_T
table[])
{
uint32_T offset_0d;
/* Interpolation 1-D
Interpolation method: 'Linear'
Use last breakpoint for index at or above upper limit: 'off'
Rounding mode: 'simplest'
Overflow mode: 'wrapping'
*/
offset_0d = bpIndex;
return (int16_T)((int16_T)(((table[offset_0d + 1U] - table[offset_0d]) * frac)
>> 6) + table[offset_0d]);
}
/* System initialize for atomic system: '<S11>/Counter' */
void Counter_Init(DW_Counter *localDW, int16_T rtp_z_cntInit)
{
/* InitializeConditions for UnitDelay: '<S17>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtp_z_cntInit;
}
/* Output and update for atomic system: '<S11>/Counter' */
int16_T Counter(int16_T rtu_inc, int16_T rtu_max, boolean_T rtu_rst, DW_Counter *
localDW)
{
int16_T rtu_rst_0;
int16_T rty_cnt_0;
/* Switch: '<S17>/Switch1' incorporates:
* Constant: '<S17>/Constant23'
* UnitDelay: '<S17>/UnitDelay'
*/
if (rtu_rst) {
rtu_rst_0 = 0;
} else {
rtu_rst_0 = localDW->UnitDelay_DSTATE;
}
/* End of Switch: '<S17>/Switch1' */
/* Sum: '<S15>/Sum1' */
rty_cnt_0 = (int16_T)(rtu_inc + rtu_rst_0);
/* MinMax: '<S15>/MinMax' */
if (rty_cnt_0 < rtu_max) {
/* Update for UnitDelay: '<S17>/UnitDelay' */
localDW->UnitDelay_DSTATE = rty_cnt_0;
} else {
/* Update for UnitDelay: '<S17>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtu_max;
}
/* End of MinMax: '<S15>/MinMax' */
return rty_cnt_0;
}
/*
* System reset for atomic system:
* '<S40>/PI_clamp_fixdt_id'
* '<S39>/PI_clamp_fixdt_iq'
*/
void PI_clamp_fixdt_Reset(DW_PI_clamp_fixdt *localDW)
{
/* InitializeConditions for UnitDelay: '<S62>/UnitDelay1' */
localDW->UnitDelay1_DSTATE = false;
/* InitializeConditions for UnitDelay: '<S65>/UnitDelay' */
localDW->UnitDelay_DSTATE = 0;
}
/*
* Output and update for atomic system:
* '<S40>/PI_clamp_fixdt_id'
* '<S39>/PI_clamp_fixdt_iq'
*/
void PI_clamp_fixdt(int16_T rtu_err, uint16_T rtu_P, uint16_T rtu_I, int16_T
rtu_satMax, int16_T rtu_satMin, int32_T rtu_ext_limProt,
int16_T *rty_out, DW_PI_clamp_fixdt *localDW)
{
boolean_T rtb_LowerRelop1_e;
boolean_T rtb_UpperRelop_f;
int32_T rtb_Sum1_b4;
int32_T q0;
int32_T tmp;
int16_T tmp_0;
/* Sum: '<S62>/Sum2' incorporates:
* Product: '<S62>/Divide2'
*/
q0 = rtu_err * rtu_I;
if ((q0 < 0) && (rtu_ext_limProt < MIN_int32_T - q0)) {
q0 = MIN_int32_T;
} else if ((q0 > 0) && (rtu_ext_limProt > MAX_int32_T - q0)) {
q0 = MAX_int32_T;
} else {
q0 += rtu_ext_limProt;
}
/* Switch: '<S62>/Switch1' incorporates:
* Constant: '<S62>/a_elecPeriod1'
* Sum: '<S62>/Sum2'
* UnitDelay: '<S62>/UnitDelay1'
*/
if (localDW->UnitDelay1_DSTATE) {
tmp = 0;
} else {
tmp = q0;
}
/* End of Switch: '<S62>/Switch1' */
/* Sum: '<S65>/Sum1' incorporates:
* UnitDelay: '<S65>/UnitDelay'
*/
rtb_Sum1_b4 = tmp + localDW->UnitDelay_DSTATE;
/* Product: '<S62>/Divide5' */
tmp = (rtu_err * rtu_P) >> 11;
if (tmp > 32767) {
tmp = 32767;
} else {
if (tmp < -32768) {
tmp = -32768;
}
}
/* Sum: '<S62>/Sum1' incorporates:
* DataTypeConversion: '<S65>/Data Type Conversion1'
* Product: '<S62>/Divide5'
*/
tmp = (((rtb_Sum1_b4 >> 16) << 1) + tmp) >> 1;
if (tmp > 32767) {
tmp = 32767;
} else {
if (tmp < -32768) {
tmp = -32768;
}
}
/* RelationalOperator: '<S66>/LowerRelop1' incorporates:
* Sum: '<S62>/Sum1'
*/
rtb_LowerRelop1_e = ((int16_T)tmp > rtu_satMax);
/* RelationalOperator: '<S66>/UpperRelop' incorporates:
* Sum: '<S62>/Sum1'
*/
rtb_UpperRelop_f = ((int16_T)tmp < rtu_satMin);
/* Switch: '<S66>/Switch1' incorporates:
* Sum: '<S62>/Sum1'
* Switch: '<S66>/Switch3'
*/
if (rtb_LowerRelop1_e) {
*rty_out = rtu_satMax;
} else if (rtb_UpperRelop_f) {
/* Switch: '<S66>/Switch3' */
*rty_out = rtu_satMin;
} else {
*rty_out = (int16_T)tmp;
}
/* End of Switch: '<S66>/Switch1' */
/* Signum: '<S64>/SignDeltaU2' incorporates:
* Sum: '<S62>/Sum2'
*/
if (q0 < 0) {
q0 = -1;
} else {
q0 = (q0 > 0);
}
/* End of Signum: '<S64>/SignDeltaU2' */
/* Signum: '<S64>/SignDeltaU3' incorporates:
* Sum: '<S62>/Sum1'
*/
if ((int16_T)tmp < 0) {
tmp_0 = -1;
} else {
tmp_0 = (int16_T)((int16_T)tmp > 0);
}
/* End of Signum: '<S64>/SignDeltaU3' */
/* Update for UnitDelay: '<S62>/UnitDelay1' incorporates:
* DataTypeConversion: '<S64>/DataTypeConv4'
* Logic: '<S62>/AND1'
* Logic: '<S64>/AND1'
* RelationalOperator: '<S64>/Equal1'
*/
localDW->UnitDelay1_DSTATE = ((q0 == tmp_0) && (rtb_LowerRelop1_e ||
rtb_UpperRelop_f));
/* Update for UnitDelay: '<S65>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtb_Sum1_b4;
}
/* System reset for atomic system: '<S31>/Low_Pass_Filter' */
void Low_Pass_Filter_Reset(DW_Low_Pass_Filter *localDW)
{
/* InitializeConditions for UnitDelay: '<S44>/UnitDelay3' */
localDW->UnitDelay3_DSTATE[0] = 0;
localDW->UnitDelay3_DSTATE[1] = 0;
}
/* Output and update for atomic system: '<S31>/Low_Pass_Filter' */
void Low_Pass_Filter(const int16_T rtu_u[2], uint16_T rtu_coef, int16_T rty_y[2],
DW_Low_Pass_Filter *localDW)
{
uint16_T rtb_Sum5;
/* Sum: '<S44>/Sum5' */
rtb_Sum5 = (uint16_T)(65535U - rtu_coef);
/* Sum: '<S44>/Sum1' incorporates:
* Product: '<S44>/Divide1'
* Product: '<S44>/Divide2'
* UnitDelay: '<S44>/UnitDelay3'
*/
rty_y[0] = (int16_T)(((rtu_u[0] * rtu_coef) >> 16) +
((localDW->UnitDelay3_DSTATE[0] * rtb_Sum5) >> 16));
/* Update for UnitDelay: '<S44>/UnitDelay3' */
localDW->UnitDelay3_DSTATE[0] = rty_y[0];
/* Sum: '<S44>/Sum1' incorporates:
* Product: '<S44>/Divide1'
* Product: '<S44>/Divide2'
* UnitDelay: '<S44>/UnitDelay3'
*/
rty_y[1] = (int16_T)(((rtu_u[1] * rtu_coef) >> 16) +
((localDW->UnitDelay3_DSTATE[1] * rtb_Sum5) >> 16));
/* Update for UnitDelay: '<S44>/UnitDelay3' */
localDW->UnitDelay3_DSTATE[1] = rty_y[1];
}
/* System reset for atomic system: '<S38>/PI_clamp_fixdt_n' */
void PI_clamp_fixdt_n_Reset(DW_PI_clamp_fixdt_c *localDW)
{
/* InitializeConditions for UnitDelay: '<S53>/UnitDelay1' */
localDW->UnitDelay1_DSTATE = false;
/* InitializeConditions for UnitDelay: '<S55>/UnitDelay' */
localDW->UnitDelay_DSTATE = 0;
}
/* Output and update for atomic system: '<S38>/PI_clamp_fixdt_n' */
int16_T PI_clamp_fixdt_n(int16_T rtu_err, uint16_T rtu_P, uint16_T rtu_I,
int16_T rtu_satMax, int16_T rtu_satMin, int16_T rtu_ext_limProt,
DW_PI_clamp_fixdt_c *localDW)
{
boolean_T rtb_LowerRelop1_ge;
boolean_T rtb_UpperRelop_cm;
int32_T rtb_Sum1_mz;
int32_T q0;
int32_T q1;
int16_T tmp;
int16_T rty_out_0;
/* Sum: '<S53>/Sum2' incorporates:
* Product: '<S53>/Divide2'
*/
q0 = rtu_err * rtu_I;
q1 = rtu_ext_limProt << 10;
if ((q0 < 0) && (q1 < MIN_int32_T - q0)) {
q0 = MIN_int32_T;
} else if ((q0 > 0) && (q1 > MAX_int32_T - q0)) {
q0 = MAX_int32_T;
} else {
q0 += q1;
}
/* Switch: '<S53>/Switch1' incorporates:
* Constant: '<S53>/a_elecPeriod1'
* Sum: '<S53>/Sum2'
* UnitDelay: '<S53>/UnitDelay1'
*/
if (localDW->UnitDelay1_DSTATE) {
q1 = 0;
} else {
q1 = q0;
}
/* End of Switch: '<S53>/Switch1' */
/* Sum: '<S55>/Sum1' incorporates:
* UnitDelay: '<S55>/UnitDelay'
*/
rtb_Sum1_mz = q1 + localDW->UnitDelay_DSTATE;
/* Product: '<S53>/Divide5' */
q1 = (rtu_err * rtu_P) >> 11;
if (q1 > 32767) {
q1 = 32767;
} else {
if (q1 < -32768) {
q1 = -32768;
}
}
/* Sum: '<S53>/Sum1' incorporates:
* DataTypeConversion: '<S55>/Data Type Conversion1'
* Product: '<S53>/Divide5'
*/
q1 = (((rtb_Sum1_mz >> 16) << 1) + q1) >> 1;
if (q1 > 32767) {
q1 = 32767;
} else {
if (q1 < -32768) {
q1 = -32768;
}
}
/* RelationalOperator: '<S56>/LowerRelop1' incorporates:
* Sum: '<S53>/Sum1'
*/
rtb_LowerRelop1_ge = ((int16_T)q1 > rtu_satMax);
/* RelationalOperator: '<S56>/UpperRelop' incorporates:
* Sum: '<S53>/Sum1'
*/
rtb_UpperRelop_cm = ((int16_T)q1 < rtu_satMin);
/* Switch: '<S56>/Switch1' incorporates:
* Sum: '<S53>/Sum1'
* Switch: '<S56>/Switch3'
*/
if (rtb_LowerRelop1_ge) {
rty_out_0 = rtu_satMax;
} else if (rtb_UpperRelop_cm) {
/* Switch: '<S56>/Switch3' */
rty_out_0 = rtu_satMin;
} else {
rty_out_0 = (int16_T)q1;
}
/* End of Switch: '<S56>/Switch1' */
/* Signum: '<S54>/SignDeltaU2' incorporates:
* Sum: '<S53>/Sum2'
*/
if (q0 < 0) {
q0 = -1;
} else {
q0 = (q0 > 0);
}
/* End of Signum: '<S54>/SignDeltaU2' */
/* Signum: '<S54>/SignDeltaU3' incorporates:
* Sum: '<S53>/Sum1'
*/
if ((int16_T)q1 < 0) {
tmp = -1;
} else {
tmp = (int16_T)((int16_T)q1 > 0);
}
/* End of Signum: '<S54>/SignDeltaU3' */
/* Update for UnitDelay: '<S53>/UnitDelay1' incorporates:
* DataTypeConversion: '<S54>/DataTypeConv4'
* Logic: '<S53>/AND1'
* Logic: '<S54>/AND1'
* RelationalOperator: '<S54>/Equal1'
*/
localDW->UnitDelay1_DSTATE = ((q0 == tmp) && (rtb_LowerRelop1_ge ||
rtb_UpperRelop_cm));
/* Update for UnitDelay: '<S55>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtb_Sum1_mz;
return rty_out_0;
}
/*
* System initialize for atomic system:
* '<S22>/Counter'
* '<S21>/Counter'
*/
void Counter_b_Init(DW_Counter_l *localDW, uint16_T rtp_z_cntInit)
{
/* InitializeConditions for UnitDelay: '<S27>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtp_z_cntInit;
}
/*
* Output and update for atomic system:
* '<S22>/Counter'
* '<S21>/Counter'
*/
uint16_T Counter_i(uint16_T rtu_inc, uint16_T rtu_max, boolean_T rtu_rst,
DW_Counter_l *localDW)
{
uint16_T rtu_rst_0;
uint16_T rty_cnt_0;
/* Switch: '<S27>/Switch1' incorporates:
* Constant: '<S27>/Constant23'
* UnitDelay: '<S27>/UnitDelay'
*/
if (rtu_rst) {
rtu_rst_0 = 0U;
} else {
rtu_rst_0 = localDW->UnitDelay_DSTATE;
}
/* End of Switch: '<S27>/Switch1' */
/* Sum: '<S26>/Sum1' */
rty_cnt_0 = (uint16_T)((uint32_T)rtu_inc + rtu_rst_0);
/* MinMax: '<S26>/MinMax' */
if (rty_cnt_0 < rtu_max) {
/* Update for UnitDelay: '<S27>/UnitDelay' */
localDW->UnitDelay_DSTATE = rty_cnt_0;
} else {
/* Update for UnitDelay: '<S27>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtu_max;
}
/* End of MinMax: '<S26>/MinMax' */
return rty_cnt_0;
}
/*
* System reset for atomic system:
* '<S18>/either_edge'
* '<S3>/either_edge'
*/
void either_edge_Reset(DW_either_edge *localDW)
{
/* InitializeConditions for UnitDelay: '<S23>/UnitDelay' */
localDW->UnitDelay_DSTATE = false;
}
/*
* Output and update for atomic system:
* '<S18>/either_edge'
* '<S3>/either_edge'
*/
boolean_T either_edge(boolean_T rtu_u, DW_either_edge *localDW)
{
boolean_T rty_y_0;
/* RelationalOperator: '<S23>/Relational Operator' incorporates:
* UnitDelay: '<S23>/UnitDelay'
*/
rty_y_0 = (rtu_u != localDW->UnitDelay_DSTATE);
/* Update for UnitDelay: '<S23>/UnitDelay' */
localDW->UnitDelay_DSTATE = rtu_u;
return rty_y_0;
}
/* System initialize for atomic system: '<S3>/Debounce_Filter' */
void Debounce_Filter_Init(DW_Debounce_Filter *localDW)
{
/* SystemInitialize for IfAction SubSystem: '<S18>/Qualification' */
/* SystemInitialize for Atomic SubSystem: '<S22>/Counter' */
Counter_b_Init(&localDW->Counter_i0, 0U);
/* End of SystemInitialize for SubSystem: '<S22>/Counter' */
/* End of SystemInitialize for SubSystem: '<S18>/Qualification' */
/* SystemInitialize for IfAction SubSystem: '<S18>/Dequalification' */
/* SystemInitialize for Atomic SubSystem: '<S21>/Counter' */
Counter_b_Init(&localDW->Counter_h, 0U);
/* End of SystemInitialize for SubSystem: '<S21>/Counter' */
/* End of SystemInitialize for SubSystem: '<S18>/Dequalification' */
}
/* System reset for atomic system: '<S3>/Debounce_Filter' */
void Debounce_Filter_Reset(DW_Debounce_Filter *localDW)
{
/* InitializeConditions for UnitDelay: '<S18>/UnitDelay' */
localDW->UnitDelay_DSTATE = false;
/* SystemReset for Atomic SubSystem: '<S18>/either_edge' */
either_edge_Reset(&localDW->either_edge_k);
/* End of SystemReset for SubSystem: '<S18>/either_edge' */
}
/* Output and update for atomic system: '<S3>/Debounce_Filter' */
void Debounce_Filter(boolean_T rtu_u, uint16_T rtu_tAcv, uint16_T rtu_tDeacv,
boolean_T *rty_y, DW_Debounce_Filter *localDW)
{
uint16_T rtb_Sum1_l;
boolean_T rtb_RelationalOperator_f;
/* Outputs for Atomic SubSystem: '<S18>/either_edge' */
rtb_RelationalOperator_f = either_edge(rtu_u, &localDW->either_edge_k);
/* End of Outputs for SubSystem: '<S18>/either_edge' */
/* If: '<S18>/If2' incorporates:
* Constant: '<S21>/Constant6'
* Constant: '<S22>/Constant6'
* Inport: '<S20>/yPrev'
* Logic: '<S18>/Logical Operator1'
* Logic: '<S18>/Logical Operator2'
* Logic: '<S18>/Logical Operator3'
* Logic: '<S18>/Logical Operator4'
* UnitDelay: '<S18>/UnitDelay'
*/
if (rtu_u && (!localDW->UnitDelay_DSTATE)) {
/* Outputs for IfAction SubSystem: '<S18>/Qualification' incorporates:
* ActionPort: '<S22>/Action Port'
*/
/* Outputs for Atomic SubSystem: '<S22>/Counter' */
rtb_Sum1_l = (uint16_T) Counter_i(1U, rtu_tAcv, rtb_RelationalOperator_f,
&localDW->Counter_i0);
/* End of Outputs for SubSystem: '<S22>/Counter' */
/* Switch: '<S22>/Switch2' incorporates:
* Constant: '<S22>/Constant6'
* RelationalOperator: '<S22>/Relational Operator2'
*/
*rty_y = ((rtb_Sum1_l > rtu_tAcv) || localDW->UnitDelay_DSTATE);
/* End of Outputs for SubSystem: '<S18>/Qualification' */
} else if ((!rtu_u) && localDW->UnitDelay_DSTATE) {
/* Outputs for IfAction SubSystem: '<S18>/Dequalification' incorporates:
* ActionPort: '<S21>/Action Port'
*/
/* Outputs for Atomic SubSystem: '<S21>/Counter' */
rtb_Sum1_l = (uint16_T) Counter_i(1U, rtu_tDeacv, rtb_RelationalOperator_f,
&localDW->Counter_h);
/* End of Outputs for SubSystem: '<S21>/Counter' */
/* Switch: '<S21>/Switch2' incorporates:
* Constant: '<S21>/Constant6'
* RelationalOperator: '<S21>/Relational Operator2'
*/
*rty_y = ((!(rtb_Sum1_l > rtu_tDeacv)) && localDW->UnitDelay_DSTATE);
/* End of Outputs for SubSystem: '<S18>/Dequalification' */
} else {
/* Outputs for IfAction SubSystem: '<S18>/Default' incorporates:
* ActionPort: '<S20>/Action Port'
*/
*rty_y = localDW->UnitDelay_DSTATE;
/* End of Outputs for SubSystem: '<S18>/Default' */
}
/* End of If: '<S18>/If2' */
/* Update for UnitDelay: '<S18>/UnitDelay' */
localDW->UnitDelay_DSTATE = *rty_y;
}
/* Model step function */
void BLDC_controller_step(RT_MODEL *const rtM)
{
P *rtP = ((P *) rtM->defaultParam);
DW *rtDW = ((DW *) rtM->dwork);
ExtU *rtU = (ExtU *) rtM->inputs;
ExtY *rtY = (ExtY *) rtM->outputs;
uint8_T rtb_Sum;
boolean_T rtb_LogicalOperator;
int8_T rtb_Sum2_h;
boolean_T rtb_RelationalOperator4_d;
boolean_T rtb_RelationalOperator1_m;
uint8_T rtb_Sum_l;
uint8_T rtb_r_fieldWeak_XA_o1;
int16_T rtb_Merge;
int16_T rtb_Switch2_fv;
int16_T rtb_Abs5;
int16_T rtb_Switch1_l;
int16_T rtb_Switch2_d;
uint16_T rtb_Divide2_h;
int16_T rtb_Saturation;
int16_T rtb_toNegative;
int16_T rtb_Gain4;
uint8_T rtb_r_fieldWeak_XA_o2;
int16_T rtb_Gain2_f;
int16_T rtb_id_fieldWeak_M1;
int16_T rtb_MinMax2;
int16_T rtb_TmpSignalConversionAtLow_Pa[2];
int32_T rtb_DataTypeConversion;
int32_T rtb_Switch1;
int32_T rtb_Sum1;
int32_T rtb_Gain3;
int16_T tmp[4];
int8_T UnitDelay3;
/* Outputs for Atomic SubSystem: '<Root>/BLDC_controller' */
/* Sum: '<S9>/Sum' incorporates:
* Gain: '<S9>/g_Ha'
* Gain: '<S9>/g_Hb'
* Inport: '<Root>/b_hallA '
* Inport: '<Root>/b_hallB'
* Inport: '<Root>/b_hallC'
*/
rtb_Sum = (uint8_T)((uint32_T)(uint8_T)((uint32_T)(uint8_T)(rtU->b_hallA << 2)
+ (uint8_T)(rtU->b_hallB << 1)) + rtU->b_hallC);
/* Saturate: '<S1>/Saturation2' incorporates:
* Inport: '<Root>/r_inpTgt'
*/
rtb_Gain3 = rtU->r_inpTgt << 4;
/* If: '<S7>/If1' incorporates:
* Constant: '<S1>/z_ctrlTypSel1'
* Inport: '<Root>/r_inpTgt'
* Inport: '<S13>/r_inpTgt'
* Saturate: '<S1>/Saturation2'
*/
if (rtP->z_ctrlTypSel == 1) {
/* Outputs for IfAction SubSystem: '<S7>/FOC_Control_Type' incorporates:
* ActionPort: '<S14>/Action Port'
*/
/* SignalConversion: '<S14>/TmpSignal ConversionAtSelectorInport1' incorporates:
* Constant: '<S14>/Vd_max'
* Constant: '<S14>/constant1'
* Constant: '<S14>/i_max'
* Constant: '<S14>/n_max'
*/
tmp[0] = 0;
tmp[1] = rtP->Vd_max;
tmp[2] = rtP->n_max;
tmp[3] = rtP->i_max;
/* End of Outputs for SubSystem: '<S7>/FOC_Control_Type' */
/* Saturate: '<S1>/Saturation2' incorporates:
* Inport: '<Root>/r_inpTgt'
*/
if (rtb_Gain3 >= 16000) {
rtb_toNegative = 16000;
} else if (rtb_Gain3 <= -16000) {
rtb_toNegative = -16000;
} else {
rtb_toNegative = (int16_T)(rtU->r_inpTgt << 4);
}
/* Outputs for IfAction SubSystem: '<S7>/FOC_Control_Type' incorporates:
* ActionPort: '<S14>/Action Port'
*/
/* Product: '<S14>/Divide1' incorporates:
* Inport: '<Root>/z_ctrlModReq'
* Product: '<S14>/Divide4'
* Selector: '<S14>/Selector'
*/
rtb_Merge = (int16_T)(((uint16_T)((tmp[rtU->z_ctrlModReq] << 5) / 125) *
rtb_toNegative) >> 12);
/* End of Outputs for SubSystem: '<S7>/FOC_Control_Type' */
} else if (rtb_Gain3 >= 16000) {
/* Outputs for IfAction SubSystem: '<S7>/Commutation_Control_Type' incorporates:
* ActionPort: '<S13>/Action Port'
*/
/* Saturate: '<S1>/Saturation2' incorporates:
* Inport: '<S13>/r_inpTgt'
*/
rtb_Merge = 16000;
/* End of Outputs for SubSystem: '<S7>/Commutation_Control_Type' */
} else if (rtb_Gain3 <= -16000) {
/* Outputs for IfAction SubSystem: '<S7>/Commutation_Control_Type' incorporates:
* ActionPort: '<S13>/Action Port'
*/
/* Saturate: '<S1>/Saturation2' incorporates:
* Inport: '<S13>/r_inpTgt'
*/
rtb_Merge = -16000;
/* End of Outputs for SubSystem: '<S7>/Commutation_Control_Type' */
} else {
/* Outputs for IfAction SubSystem: '<S7>/Commutation_Control_Type' incorporates:
* ActionPort: '<S13>/Action Port'
*/
rtb_Merge = (int16_T)(rtU->r_inpTgt << 4);
/* End of Outputs for SubSystem: '<S7>/Commutation_Control_Type' */
}
/* End of If: '<S7>/If1' */
/* Logic: '<S8>/Logical Operator' incorporates:
* Inport: '<Root>/b_hallA '
* Inport: '<Root>/b_hallB'
* Inport: '<Root>/b_hallC'
* UnitDelay: '<S8>/UnitDelay1'
* UnitDelay: '<S8>/UnitDelay2'
* UnitDelay: '<S8>/UnitDelay3'
*/
rtb_LogicalOperator = (boolean_T)((rtU->b_hallA != 0) ^ (rtU->b_hallB != 0) ^
(rtU->b_hallC != 0) ^ (rtDW->UnitDelay3_DSTATE_fy != 0) ^
(rtDW->UnitDelay1_DSTATE != 0)) ^ (rtDW->UnitDelay2_DSTATE_f != 0);
/* If: '<S11>/If2' incorporates:
* If: '<S2>/If2'
* Inport: '<S16>/z_counterRawPrev'
* UnitDelay: '<S11>/UnitDelay3'
*/
if (rtb_LogicalOperator) {
/* Outputs for IfAction SubSystem: '<S2>/F01_04_Direction_Detection' incorporates:
* ActionPort: '<S10>/Action Port'
*/
/* UnitDelay: '<S10>/UnitDelay3' */
UnitDelay3 = rtDW->Switch2;
/* Sum: '<S10>/Sum2' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
* UnitDelay: '<S10>/UnitDelay2'
*/
rtb_Sum2_h = (int8_T)(rtConstP.vec_hallToPos_Value[rtb_Sum] -
rtDW->UnitDelay2_DSTATE_b);
/* Switch: '<S10>/Switch2' incorporates:
* Constant: '<S10>/Constant20'
* Constant: '<S10>/Constant23'
* Constant: '<S10>/Constant24'
* Constant: '<S10>/Constant8'
* Logic: '<S10>/Logical Operator3'
* RelationalOperator: '<S10>/Relational Operator1'
* RelationalOperator: '<S10>/Relational Operator6'
*/
if ((rtb_Sum2_h == 1) || (rtb_Sum2_h == -5)) {
rtDW->Switch2 = 1;
} else {
rtDW->Switch2 = -1;
}
/* End of Switch: '<S10>/Switch2' */
/* Update for UnitDelay: '<S10>/UnitDelay2' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
*/
rtDW->UnitDelay2_DSTATE_b = rtConstP.vec_hallToPos_Value[rtb_Sum];
/* End of Outputs for SubSystem: '<S2>/F01_04_Direction_Detection' */
/* Outputs for IfAction SubSystem: '<S11>/Raw_Motor_Speed_Estimation' incorporates:
* ActionPort: '<S16>/Action Port'
*/
rtDW->z_counterRawPrev = rtDW->UnitDelay3_DSTATE;
/* Sum: '<S16>/Sum7' incorporates:
* Inport: '<S16>/z_counterRawPrev'
* UnitDelay: '<S11>/UnitDelay3'
* UnitDelay: '<S16>/UnitDelay4'
*/
rtb_Switch2_fv = (int16_T)(rtDW->z_counterRawPrev -
rtDW->UnitDelay4_DSTATE_p);
/* Abs: '<S16>/Abs2' */
if (rtb_Switch2_fv < 0) {
rtb_Switch1_l = (int16_T)-rtb_Switch2_fv;
} else {
rtb_Switch1_l = rtb_Switch2_fv;
}
/* End of Abs: '<S16>/Abs2' */
/* Relay: '<S16>/dz_cntTrnsDet' */
if (rtb_Switch1_l >= rtP->dz_cntTrnsDetHi) {
rtDW->dz_cntTrnsDet_Mode = true;
} else {
if (rtb_Switch1_l <= rtP->dz_cntTrnsDetLo) {
rtDW->dz_cntTrnsDet_Mode = false;
}
}
rtDW->dz_cntTrnsDet = rtDW->dz_cntTrnsDet_Mode;
/* End of Relay: '<S16>/dz_cntTrnsDet' */
/* RelationalOperator: '<S16>/Relational Operator4' */
rtb_RelationalOperator4_d = (rtDW->Switch2 != UnitDelay3);
/* Switch: '<S16>/Switch3' incorporates:
* Constant: '<S16>/Constant4'
* Logic: '<S16>/Logical Operator1'
* Switch: '<S16>/Switch1'
* Switch: '<S16>/Switch2'
* UnitDelay: '<S16>/UnitDelay1'
*/
if (rtb_RelationalOperator4_d && rtDW->UnitDelay1_DSTATE_n) {
rtb_Switch1_l = 0;
} else if (rtb_RelationalOperator4_d) {
/* Switch: '<S16>/Switch2' incorporates:
* UnitDelay: '<S11>/UnitDelay4'
*/
rtb_Switch1_l = rtDW->UnitDelay4_DSTATE_e;
} else if (rtDW->dz_cntTrnsDet) {
/* Switch: '<S16>/Switch1' incorporates:
* Constant: '<S16>/cf_speedCoef'
* Product: '<S16>/Divide14'
* Switch: '<S16>/Switch2'
*/
rtb_Switch1_l = (int16_T)((rtP->cf_speedCoef << 4) /
rtDW->z_counterRawPrev);
} else {
/* Switch: '<S16>/Switch1' incorporates:
* Constant: '<S16>/cf_speedCoef'
* Gain: '<S16>/g_Ha'
* Product: '<S16>/Divide13'
* Sum: '<S16>/Sum13'
* Switch: '<S16>/Switch2'
* UnitDelay: '<S16>/UnitDelay2'
* UnitDelay: '<S16>/UnitDelay3'
* UnitDelay: '<S16>/UnitDelay5'
*/
rtb_Switch1_l = (int16_T)(((uint16_T)(rtP->cf_speedCoef << 2) << 4) /
(int16_T)(((rtDW->UnitDelay2_DSTATE + rtDW->UnitDelay3_DSTATE_o) +
rtDW->UnitDelay5_DSTATE) + rtDW->z_counterRawPrev));
}
/* End of Switch: '<S16>/Switch3' */
/* Product: '<S16>/Divide11' */
rtDW->Divide11 = (int16_T)(rtb_Switch1_l * rtDW->Switch2);
/* Update for UnitDelay: '<S16>/UnitDelay4' */
rtDW->UnitDelay4_DSTATE_p = rtDW->z_counterRawPrev;
/* Update for UnitDelay: '<S16>/UnitDelay2' incorporates:
* UnitDelay: '<S16>/UnitDelay3'
*/
rtDW->UnitDelay2_DSTATE = rtDW->UnitDelay3_DSTATE_o;
/* Update for UnitDelay: '<S16>/UnitDelay3' incorporates:
* UnitDelay: '<S16>/UnitDelay5'
*/
rtDW->UnitDelay3_DSTATE_o = rtDW->UnitDelay5_DSTATE;
/* Update for UnitDelay: '<S16>/UnitDelay5' */
rtDW->UnitDelay5_DSTATE = rtDW->z_counterRawPrev;
/* Update for UnitDelay: '<S16>/UnitDelay1' */
rtDW->UnitDelay1_DSTATE_n = rtb_RelationalOperator4_d;
/* End of Outputs for SubSystem: '<S11>/Raw_Motor_Speed_Estimation' */
}
/* End of If: '<S11>/If2' */
/* Outputs for Atomic SubSystem: '<S11>/Counter' */
/* Constant: '<S11>/Constant6' incorporates:
* Constant: '<S11>/z_maxCntRst2'
*/
rtb_Switch1_l = (int16_T) Counter(1, rtP->z_maxCntRst, rtb_LogicalOperator,
&rtDW->Counter_e);
/* End of Outputs for SubSystem: '<S11>/Counter' */
/* Switch: '<S11>/Switch2' incorporates:
* Constant: '<S11>/Constant4'
* Constant: '<S11>/z_maxCntRst'
* RelationalOperator: '<S11>/Relational Operator2'
*/
if (rtb_Switch1_l > rtP->z_maxCntRst) {
rtb_Switch2_fv = 0;
} else {
rtb_Switch2_fv = rtDW->Divide11;
}
/* End of Switch: '<S11>/Switch2' */
/* Abs: '<S11>/Abs5' */
if (rtb_Switch2_fv < 0) {
rtb_Abs5 = (int16_T)-rtb_Switch2_fv;
} else {
rtb_Abs5 = rtb_Switch2_fv;
}
/* End of Abs: '<S11>/Abs5' */
/* Relay: '<S11>/n_commDeacv' */
if (rtb_Abs5 >= rtP->n_commDeacvHi) {
rtDW->n_commDeacv_Mode = true;
} else {
if (rtb_Abs5 <= rtP->n_commAcvLo) {
rtDW->n_commDeacv_Mode = false;
}
}
/* Logic: '<S11>/Logical Operator2' incorporates:
* Constant: '<S11>/CTRL_COMM'
* Constant: '<S1>/z_ctrlTypSel1'
* Logic: '<S11>/Logical Operator1'
* RelationalOperator: '<S11>/Relational Operator3'
* Relay: '<S11>/n_commDeacv'
*/
rtb_LogicalOperator = ((rtP->z_ctrlTypSel == 1) && rtDW->n_commDeacv_Mode && (
!rtDW->dz_cntTrnsDet));
/* RelationalOperator: '<S11>/Relational Operator9' incorporates:
* Constant: '<S11>/n_stdStillDet'
*/
rtb_RelationalOperator4_d = (rtb_Abs5 < rtP->n_stdStillDet);
/* If: '<S1>/If2' incorporates:
* Constant: '<S1>/b_diagEna'
* Constant: '<S3>/CTRL_COMM2'
* Constant: '<S3>/t_errDequal'
* Constant: '<S3>/t_errQual'
* RelationalOperator: '<S3>/Relational Operator2'
*/
rtb_Sum2_h = rtDW->If2_ActiveSubsystem;
UnitDelay3 = -1;
if (rtP->b_diagEna) {
UnitDelay3 = 0;
}
rtDW->If2_ActiveSubsystem = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for Outport: '<Root>/z_errCode' incorporates:
* Outport: '<S3>/z_errCode '
*/
rtY->z_errCode = 0U;
/* Disable for Outport: '<S3>/b_errFlag' */
rtDW->Merge_n = false;
}
if (UnitDelay3 == 0) {
if (0 != rtb_Sum2_h) {
/* InitializeConditions for IfAction SubSystem: '<S1>/F02_Diagnostics' incorporates:
* ActionPort: '<S3>/Action Port'
*/
/* InitializeConditions for If: '<S1>/If2' incorporates:
* UnitDelay: '<S3>/UnitDelay'
*/
rtDW->UnitDelay_DSTATE_c = 0U;
/* End of InitializeConditions for SubSystem: '<S1>/F02_Diagnostics' */
/* SystemReset for IfAction SubSystem: '<S1>/F02_Diagnostics' incorporates:
* ActionPort: '<S3>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S3>/Debounce_Filter' */
/* SystemReset for If: '<S1>/If2' */
Debounce_Filter_Reset(&rtDW->Debounce_Filter_f);
/* End of SystemReset for SubSystem: '<S3>/Debounce_Filter' */
/* SystemReset for Atomic SubSystem: '<S3>/either_edge' */
either_edge_Reset(&rtDW->either_edge_a);
/* End of SystemReset for SubSystem: '<S3>/either_edge' */
/* End of SystemReset for SubSystem: '<S1>/F02_Diagnostics' */
}
/* Outputs for IfAction SubSystem: '<S1>/F02_Diagnostics' incorporates:
* ActionPort: '<S3>/Action Port'
*/
/* Switch: '<S3>/Switch3' incorporates:
* Abs: '<S3>/Abs4'
* Constant: '<S3>/CTRL_COMM4'
* Constant: '<S3>/r_errInpTgtThres'
* Logic: '<S3>/Logical Operator1'
* RelationalOperator: '<S3>/Relational Operator7'
* S-Function (sfix_bitop): '<S3>/Bitwise Operator1'
* UnitDelay: '<S3>/UnitDelay'
* UnitDelay: '<S6>/UnitDelay4'
*/
if ((rtDW->UnitDelay_DSTATE_c & 4) != 0) {
rtb_RelationalOperator1_m = true;
} else {
if (rtDW->UnitDelay4_DSTATE < 0) {
/* Abs: '<S3>/Abs4' incorporates:
* UnitDelay: '<S6>/UnitDelay4'
*/
rtb_toNegative = (int16_T)-rtDW->UnitDelay4_DSTATE;
} else {
/* Abs: '<S3>/Abs4' incorporates:
* UnitDelay: '<S6>/UnitDelay4'
*/
rtb_toNegative = rtDW->UnitDelay4_DSTATE;
}
rtb_RelationalOperator1_m = ((rtb_toNegative > rtP->r_errInpTgtThres) &&
rtb_RelationalOperator4_d);
}
/* End of Switch: '<S3>/Switch3' */
/* Sum: '<S3>/Sum' incorporates:
* Constant: '<S3>/CTRL_COMM'
* Constant: '<S3>/CTRL_COMM1'
* DataTypeConversion: '<S3>/Data Type Conversion3'
* Gain: '<S3>/g_Hb'
* Gain: '<S3>/g_Hb1'
* RelationalOperator: '<S3>/Relational Operator1'
* RelationalOperator: '<S3>/Relational Operator3'
*/
rtb_Sum_l = (uint8_T)(((uint32_T)((rtb_Sum == 7) << 1) + (rtb_Sum == 0)) +
(rtb_RelationalOperator1_m << 2));
/* Outputs for Atomic SubSystem: '<S3>/Debounce_Filter' */
Debounce_Filter(rtb_Sum_l != 0, rtP->t_errQual, rtP->t_errDequal,
&rtDW->Merge_n, &rtDW->Debounce_Filter_f);
/* End of Outputs for SubSystem: '<S3>/Debounce_Filter' */
/* Outputs for Atomic SubSystem: '<S3>/either_edge' */
rtb_RelationalOperator1_m = either_edge(rtDW->Merge_n, &rtDW->either_edge_a);
/* End of Outputs for SubSystem: '<S3>/either_edge' */
/* Switch: '<S3>/Switch1' incorporates:
* Constant: '<S3>/CTRL_COMM2'
* Constant: '<S3>/t_errDequal'
* Constant: '<S3>/t_errQual'
* RelationalOperator: '<S3>/Relational Operator2'
*/
if (rtb_RelationalOperator1_m) {
/* Outport: '<Root>/z_errCode' */
rtY->z_errCode = rtb_Sum_l;
} else {
/* Outport: '<Root>/z_errCode' incorporates:
* UnitDelay: '<S3>/UnitDelay'
*/
rtY->z_errCode = rtDW->UnitDelay_DSTATE_c;
}
/* End of Switch: '<S3>/Switch1' */
/* Update for UnitDelay: '<S3>/UnitDelay' incorporates:
* Outport: '<Root>/z_errCode'
*/
rtDW->UnitDelay_DSTATE_c = rtY->z_errCode;
/* End of Outputs for SubSystem: '<S1>/F02_Diagnostics' */
}
/* End of If: '<S1>/If2' */
/* Logic: '<S28>/Logical Operator4' incorporates:
* Constant: '<S28>/constant2'
* Constant: '<S28>/constant8'
* Inport: '<Root>/b_motEna'
* Inport: '<Root>/z_ctrlModReq'
* Logic: '<S28>/Logical Operator1'
* Logic: '<S28>/Logical Operator7'
* RelationalOperator: '<S28>/Relational Operator10'
* RelationalOperator: '<S28>/Relational Operator11'
* RelationalOperator: '<S28>/Relational Operator2'
* UnitDelay: '<S4>/UnitDelay1'
*/
rtb_RelationalOperator1_m = ((!rtU->b_motEna) || rtDW->Merge_n ||
(rtU->z_ctrlModReq == 0) || ((rtU->z_ctrlModReq != rtDW->UnitDelay1_DSTATE_p)
&& (rtDW->UnitDelay1_DSTATE_p != 0)));
/* Chart: '<S4>/F03_02_Control_Mode_Manager' incorporates:
* Constant: '<S28>/constant'
* Constant: '<S28>/constant1'
* Constant: '<S28>/constant5'
* Constant: '<S28>/constant6'
* Constant: '<S28>/constant7'
* Inport: '<Root>/z_ctrlModReq'
* Logic: '<S28>/Logical Operator3'
* Logic: '<S28>/Logical Operator6'
* Logic: '<S28>/Logical Operator9'
* RelationalOperator: '<S28>/Relational Operator1'
* RelationalOperator: '<S28>/Relational Operator3'
* RelationalOperator: '<S28>/Relational Operator4'
* RelationalOperator: '<S28>/Relational Operator5'
* RelationalOperator: '<S28>/Relational Operator6'
*/
if (rtDW->is_active_c1_BLDC_controller == 0U) {
rtDW->is_active_c1_BLDC_controller = 1U;
rtDW->is_c1_BLDC_controller = IN_OPEN;
rtb_Sum_l = OPEN_MODE;
} else if (rtDW->is_c1_BLDC_controller == IN_ACTIVE) {
if (rtb_RelationalOperator1_m) {
rtDW->is_ACTIVE = IN_NO_ACTIVE_CHILD;
rtDW->is_c1_BLDC_controller = IN_OPEN;
rtb_Sum_l = OPEN_MODE;
} else {
switch (rtDW->is_ACTIVE) {
case IN_SPEED_MODE:
rtb_Sum_l = SPD_MODE;
break;
case IN_TORQUE_MODE:
rtb_Sum_l = TRQ_MODE;
break;
default:
rtb_Sum_l = VLT_MODE;
break;
}
}
} else {
rtb_Sum_l = OPEN_MODE;
if ((!rtb_RelationalOperator1_m) && ((rtU->z_ctrlModReq == 1) ||
(rtU->z_ctrlModReq == 2) || (rtU->z_ctrlModReq == 3)) &&
rtb_RelationalOperator4_d) {
rtDW->is_c1_BLDC_controller = IN_ACTIVE;
if (rtU->z_ctrlModReq == 3) {
rtDW->is_ACTIVE = IN_TORQUE_MODE;
rtb_Sum_l = TRQ_MODE;
} else if (rtU->z_ctrlModReq == 2) {
rtDW->is_ACTIVE = IN_SPEED_MODE;
rtb_Sum_l = SPD_MODE;
} else {
rtDW->is_ACTIVE = IN_VOLTAGE_MODE;
rtb_Sum_l = VLT_MODE;
}
}
}
/* End of Chart: '<S4>/F03_02_Control_Mode_Manager' */
/* Switch: '<S12>/Switch2' incorporates:
* Constant: '<S12>/Constant16'
* Product: '<S12>/Divide1'
* Product: '<S12>/Divide3'
* RelationalOperator: '<S12>/Relational Operator7'
* Sum: '<S12>/Sum3'
* Switch: '<S12>/Switch3'
*/
if (rtb_LogicalOperator) {
/* MinMax: '<S12>/MinMax' */
rtb_Switch2_d = rtb_Switch1_l;
if (!(rtb_Switch2_d < rtDW->z_counterRawPrev)) {
rtb_Switch2_d = rtDW->z_counterRawPrev;
}
/* End of MinMax: '<S12>/MinMax' */
/* Switch: '<S12>/Switch3' incorporates:
* Constant: '<S12>/Constant16'
* Constant: '<S9>/vec_hallToPos'
* RelationalOperator: '<S12>/Relational Operator7'
* Selector: '<S9>/Selector'
* Sum: '<S12>/Sum1'
*/
if (rtDW->Switch2 == 1) {
rtb_Sum2_h = rtConstP.vec_hallToPos_Value[rtb_Sum];
} else {
rtb_Sum2_h = (int8_T)(rtConstP.vec_hallToPos_Value[rtb_Sum] + 1);
}
rtb_Switch2_d = (int16_T)(((int16_T)((int16_T)((rtb_Switch2_d << 14) /
rtDW->z_counterRawPrev) * rtDW->Switch2) + (rtb_Sum2_h << 14)) >> 2);
} else {
if (rtDW->Switch2 == 1) {
/* Switch: '<S12>/Switch3' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
*/
rtb_Sum2_h = rtConstP.vec_hallToPos_Value[rtb_Sum];
} else {
/* Switch: '<S12>/Switch3' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
* Sum: '<S12>/Sum1'
*/
rtb_Sum2_h = (int8_T)(rtConstP.vec_hallToPos_Value[rtb_Sum] + 1);
}
rtb_Switch2_d = (int16_T)(rtb_Sum2_h << 12);
}
/* End of Switch: '<S12>/Switch2' */
/* MinMax: '<S12>/MinMax1' incorporates:
* Constant: '<S12>/Constant1'
*/
if (!(rtb_Switch2_d > 0)) {
rtb_Switch2_d = 0;
}
/* End of MinMax: '<S12>/MinMax1' */
/* Product: '<S12>/Divide2' */
rtb_Divide2_h = (uint16_T)((15 * rtb_Switch2_d) >> 4);
/* Saturate: '<S1>/Saturation' incorporates:
* Inport: '<Root>/i_phaAB'
*/
rtb_Gain3 = rtU->i_phaAB << 4;
if (rtb_Gain3 >= 32000) {
rtb_Saturation = 32000;
} else if (rtb_Gain3 <= -32000) {
rtb_Saturation = -32000;
} else {
rtb_Saturation = (int16_T)(rtU->i_phaAB << 4);
}
/* End of Saturate: '<S1>/Saturation' */
/* Saturate: '<S1>/Saturation1' incorporates:
* Inport: '<Root>/i_phaBC'
*/
rtb_Gain3 = rtU->i_phaBC << 4;
if (rtb_Gain3 >= 32000) {
rtb_Switch2_d = 32000;
} else if (rtb_Gain3 <= -32000) {
rtb_Switch2_d = -32000;
} else {
rtb_Switch2_d = (int16_T)(rtU->i_phaBC << 4);
}
/* End of Saturate: '<S1>/Saturation1' */
/* If: '<S1>/If1' incorporates:
* Constant: '<S1>/z_ctrlTypSel1'
*/
rtb_Sum2_h = rtDW->If1_ActiveSubsystem;
UnitDelay3 = -1;
if (rtP->z_ctrlTypSel == 1) {
UnitDelay3 = 0;
}
rtDW->If1_ActiveSubsystem = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for If: '<S5>/If2' */
if (rtDW->If2_ActiveSubsystem_a == 0) {
/* Disable for Outport: '<S31>/iq' */
rtDW->Sum1[0] = 0;
/* Disable for Outport: '<S31>/id' */
rtDW->Sum1[1] = 0;
}
rtDW->If2_ActiveSubsystem_a = -1;
/* End of Disable for If: '<S5>/If2' */
/* Disable for If: '<S5>/If1' */
if (rtDW->If1_ActiveSubsystem_e == 0) {
/* Disable for Outport: '<S40>/Vd' */
rtDW->Switch1 = 0;
}
rtDW->If1_ActiveSubsystem_e = -1;
/* End of Disable for If: '<S5>/If1' */
/* Disable for If: '<S35>/If1' */
if (rtDW->If1_ActiveSubsystem_f == 0) {
/* Disable for Outport: '<S45>/iq_limProt' */
rtDW->Divide4 = 0;
}
rtDW->If1_ActiveSubsystem_f = -1;
/* End of Disable for If: '<S35>/If1' */
/* Disable for If: '<S35>/If2' */
if (rtDW->If2_ActiveSubsystem_c == 0) {
/* Disable for Outport: '<S46>/n_limProt' */
rtDW->Divide1 = 0;
}
rtDW->If2_ActiveSubsystem_c = -1;
/* End of Disable for If: '<S35>/If2' */
/* Disable for SwitchCase: '<S5>/Switch Case' */
rtDW->SwitchCase_ActiveSubsystem = -1;
/* Disable for Outport: '<S5>/r_phaA' */
rtDW->Gain4[0] = 0;
/* Disable for Outport: '<S5>/r_phaB' */
rtDW->Gain4[1] = 0;
/* Disable for Outport: '<S5>/r_phaC ' */
rtDW->Gain4[2] = 0;
/* Disable for Outport: '<S5>/Vq' */
rtDW->Merge = 0;
/* Disable for Outport: '<S5>/r_devSignal1' */
rtDW->Sum1[0] = 0;
/* Disable for Outport: '<S5>/r_devSignal2' */
rtDW->Sum1[1] = 0;
}
if (UnitDelay3 == 0) {
if (0 != rtb_Sum2_h) {
/* InitializeConditions for IfAction SubSystem: '<S1>/F04_Field_Oriented_Control' incorporates:
* ActionPort: '<S5>/Action Port'
*/
/* InitializeConditions for If: '<S1>/If1' incorporates:
* UnitDelay: '<S5>/UnitDelay4'
*/
rtDW->UnitDelay4_DSTATE_er = 0;
/* End of InitializeConditions for SubSystem: '<S1>/F04_Field_Oriented_Control' */
}
/* Outputs for IfAction SubSystem: '<S1>/F04_Field_Oriented_Control' incorporates:
* ActionPort: '<S5>/Action Port'
*/
/* Relay: '<S32>/n_fieldWeakAuth' */
if (rtb_Abs5 >= rtP->n_fieldWeakAuthHi) {
rtDW->n_fieldWeakAuth_Mode = true;
} else {
if (rtb_Abs5 <= rtP->n_fieldWeakAuthLo) {
rtDW->n_fieldWeakAuth_Mode = false;
}
}
/* Switch: '<S32>/Switch1' incorporates:
* Constant: '<S32>/a_elecPeriod1'
* Constant: '<S32>/b_fieldWeakEna'
* Logic: '<S32>/Logical Operator2'
* Relay: '<S32>/n_fieldWeakAuth'
*/
if (rtP->b_fieldWeakEna && rtDW->n_fieldWeakAuth_Mode) {
/* Abs: '<S32>/Abs5' */
if (rtb_Merge < 0) {
rtb_id_fieldWeak_M1 = (int16_T)-rtb_Merge;
} else {
rtb_id_fieldWeak_M1 = rtb_Merge;
}
/* End of Abs: '<S32>/Abs5' */
/* PreLookup: '<S32>/r_fieldWeak_XA' */
rtb_r_fieldWeak_XA_o1 = plook_u8s16u8n6_evenc_s(rtb_id_fieldWeak_M1,
rtP->r_fieldWeak_XA[0], (uint16_T)(rtP->r_fieldWeak_XA[1] -
rtP->r_fieldWeak_XA[0]), 11U, &rtb_r_fieldWeak_XA_o2);
/* Interpolation_n-D: '<S32>/id_fieldWeak_M1' */
rtb_id_fieldWeak_M1 = intrp1d_s16s32s32u8u8n6l_s(rtb_r_fieldWeak_XA_o1,
rtb_r_fieldWeak_XA_o2, rtP->id_fieldWeak_M1);
} else {
rtb_id_fieldWeak_M1 = 0;
}
/* End of Switch: '<S32>/Switch1' */
/* Gain: '<S32>/toNegative' */
rtb_toNegative = (int16_T)-rtb_id_fieldWeak_M1;
/* Gain: '<S35>/Gain4' incorporates:
* Constant: '<S35>/i_max'
*/
rtb_Gain4 = (int16_T)-rtP->i_max;
/* If: '<S30>/If1' incorporates:
* Constant: '<S30>/b_selPhaABCurrMeas'
*/
if (rtP->b_selPhaABCurrMeas) {
/* Outputs for IfAction SubSystem: '<S30>/Clarke_PhasesAB' incorporates:
* ActionPort: '<S42>/Action Port'
*/
/* Gain: '<S42>/Gain4' */
rtb_Gain3 = 18919 * rtb_Saturation;
/* Gain: '<S42>/Gain2' */
rtb_DataTypeConversion = 18919 * rtb_Switch2_d;
/* Sum: '<S42>/Sum1' incorporates:
* Gain: '<S42>/Gain2'
* Gain: '<S42>/Gain4'
*/
rtb_Gain3 = (((rtb_Gain3 < 0 ? 32767 : 0) + rtb_Gain3) >> 15) + (int16_T)
(((rtb_DataTypeConversion < 0 ? 16383 : 0) + rtb_DataTypeConversion) >>
14);
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
rtb_Gain2_f = (int16_T)rtb_Gain3;
/* End of Sum: '<S42>/Sum1' */
/* End of Outputs for SubSystem: '<S30>/Clarke_PhasesAB' */
} else {
/* Outputs for IfAction SubSystem: '<S30>/Clarke_PhasesBC' incorporates:
* ActionPort: '<S43>/Action Port'
*/
/* Sum: '<S43>/Sum3' */
rtb_Gain3 = rtb_Saturation - rtb_Switch2_d;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Gain: '<S43>/Gain2' incorporates:
* Sum: '<S43>/Sum3'
*/
rtb_Gain3 *= 18919;
rtb_Gain2_f = (int16_T)(((rtb_Gain3 < 0 ? 32767 : 0) + rtb_Gain3) >> 15);
/* Sum: '<S43>/Sum1' */
rtb_Gain3 = -rtb_Saturation - rtb_Switch2_d;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
rtb_Saturation = (int16_T)rtb_Gain3;
/* End of Sum: '<S43>/Sum1' */
/* End of Outputs for SubSystem: '<S30>/Clarke_PhasesBC' */
}
/* End of If: '<S30>/If1' */
/* PreLookup: '<S32>/a_elecAngle_XA' */
rtb_r_fieldWeak_XA_o1 = plook_u8u16_evencka(rtb_Divide2_h, 0U, 128U, 180U);
/* Interpolation_n-D: '<S32>/r_sin_M1' */
rtb_MinMax2 = rtConstP.r_sin_M1_Table[rtb_r_fieldWeak_XA_o1];
/* Interpolation_n-D: '<S32>/r_cos_M1' */
rtb_Switch2_d = rtConstP.r_cos_M1_Table[rtb_r_fieldWeak_XA_o1];
/* If: '<S5>/If2' incorporates:
* Constant: '<S31>/cf_currFilt'
* Inport: '<Root>/b_motEna'
*/
rtb_Sum2_h = rtDW->If2_ActiveSubsystem_a;
UnitDelay3 = -1;
if (rtU->b_motEna) {
UnitDelay3 = 0;
}
rtDW->If2_ActiveSubsystem_a = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for Outport: '<S31>/iq' */
rtDW->Sum1[0] = 0;
/* Disable for Outport: '<S31>/id' */
rtDW->Sum1[1] = 0;
}
if (UnitDelay3 == 0) {
if (0 != rtb_Sum2_h) {
/* SystemReset for IfAction SubSystem: '<S5>/Current_Filtering' incorporates:
* ActionPort: '<S31>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S31>/Low_Pass_Filter' */
/* SystemReset for If: '<S5>/If2' */
Low_Pass_Filter_Reset(&rtDW->Low_Pass_Filter_m);
/* End of SystemReset for SubSystem: '<S31>/Low_Pass_Filter' */
/* End of SystemReset for SubSystem: '<S5>/Current_Filtering' */
}
/* Sum: '<S37>/Sum6' incorporates:
* Interpolation_n-D: '<S32>/r_cos_M1'
* Interpolation_n-D: '<S32>/r_sin_M1'
* Product: '<S37>/Divide1'
* Product: '<S37>/Divide4'
*/
rtb_Gain3 = (int16_T)((rtb_Gain2_f *
rtConstP.r_cos_M1_Table[rtb_r_fieldWeak_XA_o1]) >> 14) - (int16_T)
((rtb_Saturation * rtConstP.r_sin_M1_Table[rtb_r_fieldWeak_XA_o1]) >> 14);
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Outputs for IfAction SubSystem: '<S5>/Current_Filtering' incorporates:
* ActionPort: '<S31>/Action Port'
*/
/* SignalConversion: '<S31>/TmpSignal ConversionAtLow_Pass_FilterInport1' incorporates:
* Sum: '<S37>/Sum6'
*/
rtb_TmpSignalConversionAtLow_Pa[0] = (int16_T)rtb_Gain3;
/* End of Outputs for SubSystem: '<S5>/Current_Filtering' */
/* Sum: '<S37>/Sum1' incorporates:
* Interpolation_n-D: '<S32>/r_cos_M1'
* Interpolation_n-D: '<S32>/r_sin_M1'
* Product: '<S37>/Divide2'
* Product: '<S37>/Divide3'
*/
rtb_Gain3 = (int16_T)((rtb_Saturation *
rtConstP.r_cos_M1_Table[rtb_r_fieldWeak_XA_o1]) >> 14) + (int16_T)
((rtb_Gain2_f * rtConstP.r_sin_M1_Table[rtb_r_fieldWeak_XA_o1]) >> 14);
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Outputs for IfAction SubSystem: '<S5>/Current_Filtering' incorporates:
* ActionPort: '<S31>/Action Port'
*/
/* SignalConversion: '<S31>/TmpSignal ConversionAtLow_Pass_FilterInport1' incorporates:
* Sum: '<S37>/Sum1'
*/
rtb_TmpSignalConversionAtLow_Pa[1] = (int16_T)rtb_Gain3;
/* Outputs for Atomic SubSystem: '<S31>/Low_Pass_Filter' */
Low_Pass_Filter(rtb_TmpSignalConversionAtLow_Pa, rtP->cf_currFilt,
rtDW->Sum1, &rtDW->Low_Pass_Filter_m);
/* End of Outputs for SubSystem: '<S31>/Low_Pass_Filter' */
/* End of Outputs for SubSystem: '<S5>/Current_Filtering' */
}
/* End of If: '<S5>/If2' */
/* If: '<S5>/If1' incorporates:
* Constant: '<S35>/Vd_max1'
* Constant: '<S40>/cf_idKi1'
* Constant: '<S40>/cf_idKp1'
* Constant: '<S40>/constant1'
* Gain: '<S35>/Gain3'
* Sum: '<S40>/Sum3'
*/
rtb_Sum2_h = rtDW->If1_ActiveSubsystem_e;
UnitDelay3 = -1;
if (rtb_LogicalOperator) {
UnitDelay3 = 0;
}
rtDW->If1_ActiveSubsystem_e = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for Outport: '<S40>/Vd' */
rtDW->Switch1 = 0;
}
if (UnitDelay3 == 0) {
if (0 != rtb_Sum2_h) {
/* SystemReset for IfAction SubSystem: '<S5>/Vd_Calculation' incorporates:
* ActionPort: '<S40>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S40>/PI_clamp_fixdt_id' */
/* SystemReset for If: '<S5>/If1' */
PI_clamp_fixdt_Reset(&rtDW->PI_clamp_fixdt_id);
/* End of SystemReset for SubSystem: '<S40>/PI_clamp_fixdt_id' */
/* End of SystemReset for SubSystem: '<S5>/Vd_Calculation' */
}
/* Outputs for IfAction SubSystem: '<S5>/Vd_Calculation' incorporates:
* ActionPort: '<S40>/Action Port'
*/
/* Switch: '<S63>/Switch2' incorporates:
* Constant: '<S35>/i_max'
* RelationalOperator: '<S63>/LowerRelop1'
* RelationalOperator: '<S63>/UpperRelop'
* Switch: '<S63>/Switch'
*/
if (rtb_toNegative > rtP->i_max) {
rtb_toNegative = rtP->i_max;
} else {
if (rtb_toNegative < rtb_Gain4) {
/* Switch: '<S63>/Switch' */
rtb_toNegative = rtb_Gain4;
}
}
/* End of Switch: '<S63>/Switch2' */
/* Sum: '<S40>/Sum3' */
rtb_Gain3 = rtb_toNegative - rtDW->Sum1[1];
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Outputs for Atomic SubSystem: '<S40>/PI_clamp_fixdt_id' */
PI_clamp_fixdt((int16_T)rtb_Gain3, rtP->cf_idKp, rtP->cf_idKi, rtP->Vd_max,
(int16_T)-rtP->Vd_max, 0, &rtDW->Switch1,
&rtDW->PI_clamp_fixdt_id);
/* End of Outputs for SubSystem: '<S40>/PI_clamp_fixdt_id' */
/* End of Outputs for SubSystem: '<S5>/Vd_Calculation' */
}
/* End of If: '<S5>/If1' */
/* Abs: '<S35>/Abs5' */
if (rtDW->Switch1 < 0) {
rtb_toNegative = (int16_T)-rtDW->Switch1;
} else {
rtb_toNegative = rtDW->Switch1;
}
/* End of Abs: '<S35>/Abs5' */
/* PreLookup: '<S35>/Vq_max_XA' */
rtb_r_fieldWeak_XA_o1 = plook_u8s16_evencka(rtb_toNegative, rtP->Vq_max_XA[0],
(uint16_T)(rtP->Vq_max_XA[1] - rtP->Vq_max_XA[0]), 45U);
/* Gain: '<S35>/Gain5' incorporates:
* Interpolation_n-D: '<S35>/Vq_max_M1'
*/
rtb_Gain2_f = (int16_T)-rtP->Vq_max_M1[rtb_r_fieldWeak_XA_o1];
/* Interpolation_n-D: '<S35>/iq_maxSca_M1' incorporates:
* Constant: '<S35>/i_max'
* Product: '<S35>/Divide4'
*/
rtb_Gain3 = rtb_id_fieldWeak_M1 << 16;
rtb_Gain3 = (rtb_Gain3 == MIN_int32_T) && (rtP->i_max == -1) ? MAX_int32_T :
rtb_Gain3 / rtP->i_max;
if (rtb_Gain3 < 0) {
rtb_Gain3 = 0;
} else {
if (rtb_Gain3 > 65535) {
rtb_Gain3 = 65535;
}
}
/* Product: '<S35>/Divide1' incorporates:
* Constant: '<S35>/i_max'
* Interpolation_n-D: '<S35>/iq_maxSca_M1'
* PreLookup: '<S35>/iq_maxSca_XA'
* Product: '<S35>/Divide4'
*/
rtb_id_fieldWeak_M1 = (int16_T)
((rtConstP.iq_maxSca_M1_Table[plook_u8u16_evencka((uint16_T)rtb_Gain3, 0U,
1311U, 49U)] * rtP->i_max) >> 16);
/* Gain: '<S35>/Gain1' */
rtb_Saturation = (int16_T)-rtb_id_fieldWeak_M1;
/* If: '<S35>/If1' incorporates:
* Constant: '<S35>/CTRL_COMM'
* Constant: '<S35>/CTRL_COMM1'
* Logic: '<S35>/Logical Operator2'
* RelationalOperator: '<S35>/Relational Operator1'
* RelationalOperator: '<S35>/Relational Operator2'
*/
rtb_Sum2_h = rtDW->If1_ActiveSubsystem_f;
UnitDelay3 = -1;
if ((rtb_Sum_l == 1) || (rtb_Sum_l == 2)) {
UnitDelay3 = 0;
}
rtDW->If1_ActiveSubsystem_f = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for Outport: '<S45>/iq_limProt' */
rtDW->Divide4 = 0;
}
if (UnitDelay3 == 0) {
/* Outputs for IfAction SubSystem: '<S35>/Current_Limit_Protection' incorporates:
* ActionPort: '<S45>/Action Port'
*/
/* Switch: '<S47>/Switch2' incorporates:
* RelationalOperator: '<S47>/LowerRelop1'
* RelationalOperator: '<S47>/UpperRelop'
* Switch: '<S47>/Switch'
*/
if (rtDW->Sum1[0] > rtb_id_fieldWeak_M1) {
rtb_toNegative = rtb_id_fieldWeak_M1;
} else if (rtDW->Sum1[0] < rtb_Saturation) {
/* Switch: '<S47>/Switch' */
rtb_toNegative = rtb_Saturation;
} else {
rtb_toNegative = rtDW->Sum1[0];
}
/* End of Switch: '<S47>/Switch2' */
/* Product: '<S45>/Divide4' incorporates:
* Constant: '<S45>/cf_iqKpLimProt'
* Sum: '<S45>/Sum3'
*/
rtb_Gain3 = ((int16_T)(rtb_toNegative - rtDW->Sum1[0]) *
rtP->cf_iqKpLimProt) >> 8;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
rtDW->Divide4 = (int16_T)rtb_Gain3;
/* End of Product: '<S45>/Divide4' */
/* End of Outputs for SubSystem: '<S35>/Current_Limit_Protection' */
}
/* End of If: '<S35>/If1' */
/* Gain: '<S35>/Gain6' incorporates:
* Constant: '<S35>/n_max1'
*/
rtb_toNegative = (int16_T)-rtP->n_max;
/* If: '<S35>/If2' incorporates:
* Constant: '<S35>/CTRL_COMM2'
* Constant: '<S35>/CTRL_COMM3'
* Logic: '<S35>/Logical Operator1'
* RelationalOperator: '<S35>/Relational Operator3'
* RelationalOperator: '<S35>/Relational Operator4'
*/
rtb_Sum2_h = rtDW->If2_ActiveSubsystem_c;
UnitDelay3 = -1;
if ((rtb_Sum_l == 1) || (rtb_Sum_l == 3)) {
UnitDelay3 = 0;
}
rtDW->If2_ActiveSubsystem_c = UnitDelay3;
if ((rtb_Sum2_h != UnitDelay3) && (rtb_Sum2_h == 0)) {
/* Disable for Outport: '<S46>/n_limProt' */
rtDW->Divide1 = 0;
}
if (UnitDelay3 == 0) {
/* Outputs for IfAction SubSystem: '<S35>/Speed_Limit_Protection' incorporates:
* ActionPort: '<S46>/Action Port'
*/
/* Switch: '<S48>/Switch2' incorporates:
* Constant: '<S35>/n_max1'
* RelationalOperator: '<S48>/LowerRelop1'
* RelationalOperator: '<S48>/UpperRelop'
* Switch: '<S48>/Switch'
*/
if (rtb_Switch2_fv > rtP->n_max) {
rtb_toNegative = rtP->n_max;
} else {
if (!(rtb_Switch2_fv < rtb_toNegative)) {
rtb_toNegative = rtb_Switch2_fv;
}
}
/* End of Switch: '<S48>/Switch2' */
/* Product: '<S46>/Divide1' incorporates:
* Constant: '<S46>/cf_nKpLimProt'
* Sum: '<S46>/Sum1'
*/
rtb_Gain3 = ((int16_T)(rtb_toNegative - rtb_Switch2_fv) *
rtP->cf_nKpLimProt) >> 8;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
rtDW->Divide1 = (int16_T)rtb_Gain3;
/* End of Product: '<S46>/Divide1' */
/* End of Outputs for SubSystem: '<S35>/Speed_Limit_Protection' */
}
/* End of If: '<S35>/If2' */
/* SwitchCase: '<S5>/Switch Case' incorporates:
* Constant: '<S38>/cf_iqKiLimProt'
* Constant: '<S38>/cf_nKi'
* Constant: '<S38>/cf_nKp'
* Interpolation_n-D: '<S35>/Vq_max_M1'
* Product: '<S38>/Divide1'
* SignalConversion: '<S38>/Signal Conversion2'
* Sum: '<S38>/Sum3'
*/
rtb_Sum2_h = rtDW->SwitchCase_ActiveSubsystem;
switch (rtb_Sum_l) {
case 1:
UnitDelay3 = 0;
break;
case 2:
UnitDelay3 = 1;
break;
case 3:
UnitDelay3 = 2;
break;
default:
UnitDelay3 = 3;
break;
}
rtDW->SwitchCase_ActiveSubsystem = UnitDelay3;
switch (UnitDelay3) {
case 0:
/* Outputs for IfAction SubSystem: '<S5>/Voltage_Mode' incorporates:
* ActionPort: '<S41>/Action Port'
*/
/* Sum: '<S41>/Sum3' */
rtb_Gain3 = (rtb_Merge + rtDW->Divide4) + rtDW->Divide1;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Switch: '<S67>/Switch2' incorporates:
* Interpolation_n-D: '<S35>/Vq_max_M1'
* RelationalOperator: '<S67>/LowerRelop1'
* RelationalOperator: '<S67>/UpperRelop'
* Sum: '<S41>/Sum3'
* Switch: '<S67>/Switch'
*/
if ((int16_T)rtb_Gain3 > rtP->Vq_max_M1[rtb_r_fieldWeak_XA_o1]) {
/* SignalConversion: '<S41>/Signal Conversion2' */
rtDW->Merge = rtP->Vq_max_M1[rtb_r_fieldWeak_XA_o1];
} else if ((int16_T)rtb_Gain3 < rtb_Gain2_f) {
/* Switch: '<S67>/Switch' incorporates:
* SignalConversion: '<S41>/Signal Conversion2'
*/
rtDW->Merge = rtb_Gain2_f;
} else {
/* SignalConversion: '<S41>/Signal Conversion2' */
rtDW->Merge = (int16_T)rtb_Gain3;
}
/* End of Switch: '<S67>/Switch2' */
/* End of Outputs for SubSystem: '<S5>/Voltage_Mode' */
break;
case 1:
if (UnitDelay3 != rtb_Sum2_h) {
/* SystemReset for IfAction SubSystem: '<S5>/Speed_Mode' incorporates:
* ActionPort: '<S38>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S38>/PI_clamp_fixdt_n' */
/* SystemReset for SwitchCase: '<S5>/Switch Case' */
PI_clamp_fixdt_n_Reset(&rtDW->PI_clamp_fixdt_n_o);
/* End of SystemReset for SubSystem: '<S38>/PI_clamp_fixdt_n' */
/* End of SystemReset for SubSystem: '<S5>/Speed_Mode' */
}
/* Outputs for IfAction SubSystem: '<S5>/Speed_Mode' incorporates:
* ActionPort: '<S38>/Action Port'
*/
/* Sum: '<S38>/Sum3' */
rtb_Gain3 = rtb_Merge - rtb_Switch2_fv;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Outputs for Atomic SubSystem: '<S38>/PI_clamp_fixdt_n' */
rtDW->Merge = (int16_T) PI_clamp_fixdt_n((int16_T)rtb_Gain3, rtP->cf_nKp,
rtP->cf_nKi, rtP->Vq_max_M1[rtb_r_fieldWeak_XA_o1], rtb_Gain2_f,
(int16_T)((rtDW->Divide4 * rtP->cf_iqKiLimProt) >> 10),
&rtDW->PI_clamp_fixdt_n_o);
/* End of Outputs for SubSystem: '<S38>/PI_clamp_fixdt_n' */
/* End of Outputs for SubSystem: '<S5>/Speed_Mode' */
break;
case 2:
if (UnitDelay3 != rtb_Sum2_h) {
/* SystemReset for IfAction SubSystem: '<S5>/Torque_Mode' incorporates:
* ActionPort: '<S39>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S39>/PI_clamp_fixdt_iq' */
/* SystemReset for SwitchCase: '<S5>/Switch Case' */
PI_clamp_fixdt_Reset(&rtDW->PI_clamp_fixdt_iq);
/* End of SystemReset for SubSystem: '<S39>/PI_clamp_fixdt_iq' */
/* End of SystemReset for SubSystem: '<S5>/Torque_Mode' */
}
/* Outputs for IfAction SubSystem: '<S5>/Torque_Mode' incorporates:
* ActionPort: '<S39>/Action Port'
*/
/* Sum: '<S39>/Sum2' */
rtb_Gain3 = rtb_Merge + rtDW->Divide1;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Switch: '<S58>/Switch2' incorporates:
* RelationalOperator: '<S58>/LowerRelop1'
* Sum: '<S39>/Sum2'
*/
if (!((int16_T)rtb_Gain3 > rtb_id_fieldWeak_M1)) {
/* Switch: '<S58>/Switch' incorporates:
* RelationalOperator: '<S58>/UpperRelop'
*/
if ((int16_T)rtb_Gain3 < rtb_Saturation) {
rtb_id_fieldWeak_M1 = rtb_Saturation;
} else {
rtb_id_fieldWeak_M1 = (int16_T)rtb_Gain3;
}
/* End of Switch: '<S58>/Switch' */
}
/* End of Switch: '<S58>/Switch2' */
/* Sum: '<S39>/Sum1' */
rtb_Gain3 = rtb_id_fieldWeak_M1 - rtDW->Sum1[0];
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Outputs for Atomic SubSystem: '<S39>/PI_clamp_fixdt_iq' */
/* SignalConversion: '<S39>/Signal Conversion2' incorporates:
* Constant: '<S39>/cf_iqKi'
* Constant: '<S39>/cf_iqKp'
* Constant: '<S39>/constant'
* Interpolation_n-D: '<S35>/Vq_max_M1'
* Sum: '<S39>/Sum1'
*/
PI_clamp_fixdt((int16_T)rtb_Gain3, rtP->cf_iqKp, rtP->cf_iqKi,
rtP->Vq_max_M1[rtb_r_fieldWeak_XA_o1], rtb_Gain2_f, 0,
&rtDW->Merge, &rtDW->PI_clamp_fixdt_iq);
/* End of Outputs for SubSystem: '<S39>/PI_clamp_fixdt_iq' */
/* End of Outputs for SubSystem: '<S5>/Torque_Mode' */
break;
case 3:
if (UnitDelay3 != rtb_Sum2_h) {
/* SystemReset for IfAction SubSystem: '<S5>/Open_Mode' incorporates:
* ActionPort: '<S36>/Action Port'
*/
/* SystemReset for Atomic SubSystem: '<S36>/rising_edge_init' */
/* SystemReset for SwitchCase: '<S5>/Switch Case' incorporates:
* UnitDelay: '<S50>/UnitDelay'
* UnitDelay: '<S51>/UnitDelay'
*/
rtDW->UnitDelay_DSTATE_g = true;
/* End of SystemReset for SubSystem: '<S36>/rising_edge_init' */
/* SystemReset for Atomic SubSystem: '<S36>/Rate_Limiter' */
rtDW->UnitDelay_DSTATE = 0;
/* End of SystemReset for SubSystem: '<S36>/Rate_Limiter' */
/* End of SystemReset for SubSystem: '<S5>/Open_Mode' */
}
/* Outputs for IfAction SubSystem: '<S5>/Open_Mode' incorporates:
* ActionPort: '<S36>/Action Port'
*/
/* DataTypeConversion: '<S36>/Data Type Conversion' incorporates:
* UnitDelay: '<S5>/UnitDelay4'
*/
rtb_Gain3 = rtDW->UnitDelay4_DSTATE_er << 12;
rtb_DataTypeConversion = (rtb_Gain3 & 134217728) != 0 ? rtb_Gain3 |
-134217728 : rtb_Gain3 & 134217727;
/* Outputs for Atomic SubSystem: '<S36>/rising_edge_init' */
/* UnitDelay: '<S50>/UnitDelay' */
rtb_RelationalOperator4_d = rtDW->UnitDelay_DSTATE_g;
/* Update for UnitDelay: '<S50>/UnitDelay' incorporates:
* Constant: '<S50>/Constant'
*/
rtDW->UnitDelay_DSTATE_g = false;
/* End of Outputs for SubSystem: '<S36>/rising_edge_init' */
/* Outputs for Atomic SubSystem: '<S36>/Rate_Limiter' */
/* Switch: '<S51>/Switch1' incorporates:
* UnitDelay: '<S51>/UnitDelay'
*/
if (rtb_RelationalOperator4_d) {
rtb_Switch1 = rtb_DataTypeConversion;
} else {
rtb_Switch1 = rtDW->UnitDelay_DSTATE;
}
/* End of Switch: '<S51>/Switch1' */
/* Sum: '<S49>/Sum1' */
rtb_Gain3 = -rtb_Switch1;
rtb_Sum1 = (rtb_Gain3 & 134217728) != 0 ? rtb_Gain3 | -134217728 :
rtb_Gain3 & 134217727;
/* Switch: '<S52>/Switch2' incorporates:
* Constant: '<S36>/dV_openRate'
* RelationalOperator: '<S52>/LowerRelop1'
*/
if (rtb_Sum1 > rtP->dV_openRate) {
rtb_Sum1 = rtP->dV_openRate;
} else {
/* Gain: '<S36>/Gain3' */
rtb_Gain3 = -rtP->dV_openRate;
rtb_Gain3 = (rtb_Gain3 & 134217728) != 0 ? rtb_Gain3 | -134217728 :
rtb_Gain3 & 134217727;
/* Switch: '<S52>/Switch' incorporates:
* RelationalOperator: '<S52>/UpperRelop'
*/
if (rtb_Sum1 < rtb_Gain3) {
rtb_Sum1 = rtb_Gain3;
}
/* End of Switch: '<S52>/Switch' */
}
/* End of Switch: '<S52>/Switch2' */
/* Sum: '<S49>/Sum2' */
rtb_Gain3 = rtb_Sum1 + rtb_Switch1;
rtb_Switch1 = (rtb_Gain3 & 134217728) != 0 ? rtb_Gain3 | -134217728 :
rtb_Gain3 & 134217727;
/* Switch: '<S51>/Switch2' */
if (rtb_RelationalOperator4_d) {
/* Update for UnitDelay: '<S51>/UnitDelay' */
rtDW->UnitDelay_DSTATE = rtb_DataTypeConversion;
} else {
/* Update for UnitDelay: '<S51>/UnitDelay' */
rtDW->UnitDelay_DSTATE = rtb_Switch1;
}
/* End of Switch: '<S51>/Switch2' */
/* End of Outputs for SubSystem: '<S36>/Rate_Limiter' */
/* DataTypeConversion: '<S36>/Data Type Conversion1' */
rtDW->Merge = (int16_T)(rtb_Switch1 >> 12);
/* End of Outputs for SubSystem: '<S5>/Open_Mode' */
break;
}
/* End of SwitchCase: '<S5>/Switch Case' */
/* Sum: '<S34>/Sum6' incorporates:
* Product: '<S34>/Divide1'
* Product: '<S34>/Divide4'
*/
rtb_Gain3 = (int16_T)((rtDW->Switch1 * rtb_Switch2_d) >> 14) - (int16_T)
((rtDW->Merge * rtb_MinMax2) >> 14);
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Sum: '<S34>/Sum1' incorporates:
* Product: '<S34>/Divide2'
* Product: '<S34>/Divide3'
*/
rtb_DataTypeConversion = (int16_T)((rtDW->Switch1 * rtb_MinMax2) >> 14) +
(int16_T)((rtDW->Merge * rtb_Switch2_d) >> 14);
if (rtb_DataTypeConversion > 32767) {
rtb_DataTypeConversion = 32767;
} else {
if (rtb_DataTypeConversion < -32768) {
rtb_DataTypeConversion = -32768;
}
}
/* Gain: '<S33>/Gain1' incorporates:
* Sum: '<S34>/Sum1'
*/
rtb_DataTypeConversion = 14189 * (int16_T)rtb_DataTypeConversion;
/* Sum: '<S33>/Sum6' incorporates:
* Gain: '<S33>/Gain1'
* Gain: '<S33>/Gain3'
* Sum: '<S34>/Sum6'
*/
rtb_DataTypeConversion = (((rtb_DataTypeConversion < 0 ? 16383 : 0) +
rtb_DataTypeConversion) >> 14) - ((int16_T)(((int16_T)rtb_Gain3 < 0) +
(int16_T)rtb_Gain3) >> 1);
if (rtb_DataTypeConversion > 32767) {
rtb_DataTypeConversion = 32767;
} else {
if (rtb_DataTypeConversion < -32768) {
rtb_DataTypeConversion = -32768;
}
}
/* Sum: '<S33>/Sum2' incorporates:
* Sum: '<S33>/Sum6'
* Sum: '<S34>/Sum6'
*/
rtb_Switch1 = -(int16_T)rtb_Gain3 - (int16_T)rtb_DataTypeConversion;
if (rtb_Switch1 > 32767) {
rtb_Switch1 = 32767;
} else {
if (rtb_Switch1 < -32768) {
rtb_Switch1 = -32768;
}
}
/* MinMax: '<S33>/MinMax1' incorporates:
* Sum: '<S33>/Sum2'
* Sum: '<S33>/Sum6'
* Sum: '<S34>/Sum6'
*/
rtb_Switch2_d = (int16_T)rtb_Gain3;
if (!((int16_T)rtb_Gain3 < (int16_T)rtb_DataTypeConversion)) {
rtb_Switch2_d = (int16_T)rtb_DataTypeConversion;
}
if (!(rtb_Switch2_d < (int16_T)rtb_Switch1)) {
rtb_Switch2_d = (int16_T)rtb_Switch1;
}
/* MinMax: '<S33>/MinMax2' incorporates:
* Sum: '<S33>/Sum2'
* Sum: '<S33>/Sum6'
* Sum: '<S34>/Sum6'
*/
rtb_Saturation = (int16_T)rtb_Gain3;
if (!((int16_T)rtb_Gain3 > (int16_T)rtb_DataTypeConversion)) {
rtb_Saturation = (int16_T)rtb_DataTypeConversion;
}
if (!(rtb_Saturation > (int16_T)rtb_Switch1)) {
rtb_Saturation = (int16_T)rtb_Switch1;
}
/* Sum: '<S33>/Add' incorporates:
* MinMax: '<S33>/MinMax1'
* MinMax: '<S33>/MinMax2'
*/
rtb_Sum1 = rtb_Switch2_d + rtb_Saturation;
if (rtb_Sum1 > 32767) {
rtb_Sum1 = 32767;
} else {
if (rtb_Sum1 < -32768) {
rtb_Sum1 = -32768;
}
}
/* Gain: '<S33>/Gain2' incorporates:
* Sum: '<S33>/Add'
*/
rtb_Gain2_f = (int16_T)(rtb_Sum1 >> 1);
/* Sum: '<S33>/Add1' incorporates:
* Sum: '<S34>/Sum6'
*/
rtb_Gain3 = (int16_T)rtb_Gain3 - rtb_Gain2_f;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Gain: '<S33>/Gain4' incorporates:
* Sum: '<S33>/Add1'
*/
rtDW->Gain4[0] = (int16_T)((18919 * rtb_Gain3) >> 18);
/* Sum: '<S33>/Add1' incorporates:
* Sum: '<S33>/Sum6'
*/
rtb_Gain3 = (int16_T)rtb_DataTypeConversion - rtb_Gain2_f;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Gain: '<S33>/Gain4' incorporates:
* Sum: '<S33>/Add1'
*/
rtDW->Gain4[1] = (int16_T)((18919 * rtb_Gain3) >> 18);
/* Sum: '<S33>/Add1' incorporates:
* Sum: '<S33>/Sum2'
*/
rtb_Gain3 = (int16_T)rtb_Switch1 - rtb_Gain2_f;
if (rtb_Gain3 > 32767) {
rtb_Gain3 = 32767;
} else {
if (rtb_Gain3 < -32768) {
rtb_Gain3 = -32768;
}
}
/* Gain: '<S33>/Gain4' incorporates:
* Sum: '<S33>/Add1'
*/
rtDW->Gain4[2] = (int16_T)((18919 * rtb_Gain3) >> 18);
/* Update for UnitDelay: '<S5>/UnitDelay4' */
rtDW->UnitDelay4_DSTATE_er = rtDW->Merge;
/* End of Outputs for SubSystem: '<S1>/F04_Field_Oriented_Control' */
}
/* End of If: '<S1>/If1' */
/* Switch: '<S6>/Switch2' incorporates:
* Constant: '<S1>/z_ctrlTypSel1'
* Constant: '<S6>/CTRL_COMM1'
* DataTypeConversion: '<S1>/Data Type Conversion10'
* DataTypeConversion: '<S1>/Data Type Conversion8'
* RelationalOperator: '<S6>/Relational Operator6'
*/
if (rtP->z_ctrlTypSel == 1) {
rtb_Merge = (int16_T)(rtDW->Merge >> 4);
} else {
rtb_Merge = (int16_T)(rtb_Merge >> 4);
}
/* End of Switch: '<S6>/Switch2' */
/* Switch: '<S6>/Switch1' incorporates:
* Constant: '<S9>/vec_hallToPos'
* LookupNDDirect: '<S6>/z_commutMap_M1'
* Product: '<S6>/Divide2'
* Selector: '<S9>/Selector'
*
* About '<S6>/z_commutMap_M1':
* 2-dimensional Direct Look-Up returning a Column
*/
if (rtb_LogicalOperator) {
rtb_Switch2_d = rtDW->Gain4[0];
rtb_Saturation = rtDW->Gain4[1];
rtb_id_fieldWeak_M1 = rtDW->Gain4[2];
} else {
if (rtConstP.vec_hallToPos_Value[rtb_Sum] > 5) {
/* LookupNDDirect: '<S6>/z_commutMap_M1'
*
* About '<S6>/z_commutMap_M1':
* 2-dimensional Direct Look-Up returning a Column
*/
rtb_Sum2_h = 5;
} else if (rtConstP.vec_hallToPos_Value[rtb_Sum] < 0) {
/* LookupNDDirect: '<S6>/z_commutMap_M1'
*
* About '<S6>/z_commutMap_M1':
* 2-dimensional Direct Look-Up returning a Column
*/
rtb_Sum2_h = 0;
} else {
/* LookupNDDirect: '<S6>/z_commutMap_M1' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
*
* About '<S6>/z_commutMap_M1':
* 2-dimensional Direct Look-Up returning a Column
*/
rtb_Sum2_h = rtConstP.vec_hallToPos_Value[rtb_Sum];
}
/* LookupNDDirect: '<S6>/z_commutMap_M1' incorporates:
* Constant: '<S9>/vec_hallToPos'
* Selector: '<S9>/Selector'
*
* About '<S6>/z_commutMap_M1':
* 2-dimensional Direct Look-Up returning a Column
*/
rtb_DataTypeConversion = rtb_Sum2_h * 3;
rtb_Switch2_d = (int16_T)(rtb_Merge *
rtConstP.z_commutMap_M1_table[rtb_DataTypeConversion]);
rtb_Saturation = (int16_T)(rtConstP.z_commutMap_M1_table[1 +
rtb_DataTypeConversion] * rtb_Merge);
rtb_id_fieldWeak_M1 = (int16_T)(rtConstP.z_commutMap_M1_table[2 +
rtb_DataTypeConversion] * rtb_Merge);
}
/* End of Switch: '<S6>/Switch1' */
/* Update for UnitDelay: '<S8>/UnitDelay3' incorporates:
* Inport: '<Root>/b_hallA '
*/
rtDW->UnitDelay3_DSTATE_fy = rtU->b_hallA;
/* Update for UnitDelay: '<S8>/UnitDelay1' incorporates:
* Inport: '<Root>/b_hallB'
*/
rtDW->UnitDelay1_DSTATE = rtU->b_hallB;
/* Update for UnitDelay: '<S8>/UnitDelay2' incorporates:
* Inport: '<Root>/b_hallC'
*/
rtDW->UnitDelay2_DSTATE_f = rtU->b_hallC;
/* Update for UnitDelay: '<S11>/UnitDelay3' */
rtDW->UnitDelay3_DSTATE = rtb_Switch1_l;
/* Update for UnitDelay: '<S11>/UnitDelay4' */
rtDW->UnitDelay4_DSTATE_e = rtb_Abs5;
/* Update for UnitDelay: '<S6>/UnitDelay4' */
rtDW->UnitDelay4_DSTATE = rtb_Merge;
/* Update for UnitDelay: '<S4>/UnitDelay1' */
rtDW->UnitDelay1_DSTATE_p = rtb_Sum_l;
/* End of Outputs for SubSystem: '<Root>/BLDC_controller' */
/* Outport: '<Root>/DC_phaA' */
rtY->DC_phaA = rtb_Switch2_d;
/* Outport: '<Root>/DC_phaB' */
rtY->DC_phaB = rtb_Saturation;
/* Outport: '<Root>/DC_phaC' */
rtY->DC_phaC = rtb_id_fieldWeak_M1;
/* Outputs for Atomic SubSystem: '<Root>/BLDC_controller' */
/* Outport: '<Root>/n_mot' incorporates:
* DataTypeConversion: '<S1>/Data Type Conversion1'
*/
rtY->n_mot = (int16_T)(rtb_Switch2_fv >> 4);
/* Outport: '<Root>/a_elecAngle' incorporates:
* DataTypeConversion: '<S1>/Data Type Conversion7'
*/
rtY->a_elecAngle = (int16_T)((uint32_T)rtb_Divide2_h >> 6);
/* Outport: '<Root>/r_devSignal1' incorporates:
* DataTypeConversion: '<S1>/Data Type Conversion4'
*/
rtY->r_devSignal1 = (int16_T)(rtDW->Sum1[0] >> 4);
/* Outport: '<Root>/r_devSignal2' incorporates:
* DataTypeConversion: '<S1>/Data Type Conversion5'
*/
rtY->r_devSignal2 = (int16_T)(rtDW->Sum1[1] >> 4);
/* End of Outputs for SubSystem: '<Root>/BLDC_controller' */
}
/* Model initialize function */
void BLDC_controller_initialize(RT_MODEL *const rtM)
{
P *rtP = ((P *) rtM->defaultParam);
DW *rtDW = ((DW *) rtM->dwork);
/* Start for Atomic SubSystem: '<Root>/BLDC_controller' */
/* Start for If: '<S1>/If2' */
rtDW->If2_ActiveSubsystem = -1;
/* Start for If: '<S1>/If1' */
rtDW->If1_ActiveSubsystem = -1;
/* Start for IfAction SubSystem: '<S1>/F04_Field_Oriented_Control' */
/* Start for If: '<S5>/If2' */
rtDW->If2_ActiveSubsystem_a = -1;
/* Start for If: '<S5>/If1' */
rtDW->If1_ActiveSubsystem_e = -1;
/* Start for If: '<S35>/If1' */
rtDW->If1_ActiveSubsystem_f = -1;
/* Start for If: '<S35>/If2' */
rtDW->If2_ActiveSubsystem_c = -1;
/* Start for SwitchCase: '<S5>/Switch Case' */
rtDW->SwitchCase_ActiveSubsystem = -1;
/* End of Start for SubSystem: '<S1>/F04_Field_Oriented_Control' */
/* End of Start for SubSystem: '<Root>/BLDC_controller' */
/* SystemInitialize for Atomic SubSystem: '<Root>/BLDC_controller' */
/* InitializeConditions for UnitDelay: '<S11>/UnitDelay3' */
rtDW->UnitDelay3_DSTATE = rtP->z_maxCntRst;
/* SystemInitialize for IfAction SubSystem: '<S11>/Raw_Motor_Speed_Estimation' */
/* SystemInitialize for Outport: '<S16>/z_counter' */
rtDW->z_counterRawPrev = rtP->z_maxCntRst;
/* End of SystemInitialize for SubSystem: '<S11>/Raw_Motor_Speed_Estimation' */
/* SystemInitialize for Atomic SubSystem: '<S11>/Counter' */
Counter_Init(&rtDW->Counter_e, rtP->z_maxCntRst);
/* End of SystemInitialize for SubSystem: '<S11>/Counter' */
/* SystemInitialize for IfAction SubSystem: '<S1>/F02_Diagnostics' */
/* SystemInitialize for Atomic SubSystem: '<S3>/Debounce_Filter' */
Debounce_Filter_Init(&rtDW->Debounce_Filter_f);
/* End of SystemInitialize for SubSystem: '<S3>/Debounce_Filter' */
/* End of SystemInitialize for SubSystem: '<S1>/F02_Diagnostics' */
/* SystemInitialize for IfAction SubSystem: '<S1>/F04_Field_Oriented_Control' */
/* SystemInitialize for IfAction SubSystem: '<S5>/Open_Mode' */
/* SystemInitialize for Atomic SubSystem: '<S36>/rising_edge_init' */
/* InitializeConditions for UnitDelay: '<S50>/UnitDelay' */
rtDW->UnitDelay_DSTATE_g = true;
/* End of SystemInitialize for SubSystem: '<S36>/rising_edge_init' */
/* End of SystemInitialize for SubSystem: '<S5>/Open_Mode' */
/* End of SystemInitialize for SubSystem: '<S1>/F04_Field_Oriented_Control' */
/* End of SystemInitialize for SubSystem: '<Root>/BLDC_controller' */
}
/*
* File trailer for generated code.
*
* [EOF]
*/