HRPWM Example Not Working

Other Parts Discussed in Thread: CONTROLSUITE

Hello. I am running HRPWM example code for the F28335 Delfino controller, but I am not getting any results. Here is the code. Any assistance would be much appreciated.

#include "DSP28x_Project.h" // Device Headerfile and Examples Include File
#include "DSP2833x_EPwm_defines.h" // useful defines for initialization

// Declare your function prototypes here
//---------------------------------------------------------------

void HRPWM1_Config(int);
void HRPWM2_Config(int);
void HRPWM3_Config(int);
void HRPWM4_Config(int);

// General System nets - Useful for debug
Uint16 i,j, DutyFine, n,update;
int vsamps[10]={0.1,0.3,0.5, 1.1, 1.7, 2.1, 3, 2 ,1.5, 0.1};
Uint32 temp;

void main(void)
{

// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the DSP2833x_SysCtrl.c file.
InitSysCtrl();

// Step 2. Initialize GPIO:
// This example function is found in the DSP2833x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example
// For this case, just init GPIO for ePWM1-ePWM4

// For this case just init GPIO pins for ePWM1, ePWM2, ePWM3, ePWM4
// These functions are in the DSP2833x_EPwm.c file
InitEPwm1Gpio();
InitEPwm2Gpio();
InitEPwm3Gpio();
InitEPwm4Gpio();

// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
DINT;

// Initialize the PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the DSP2833x_PieCtrl.c file.
InitPieCtrl();

// Disable CPU interrupts and clear all CPU interrupt flags:
IER = 0x0000;
IFR = 0x0000;

// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in DSP2833x_DefaultIsr.c.
// This function is found in DSP2833x_PieVect.c.
InitPieVectTable();

// Step 4. Initialize all the Device Peripherals:
// This function is found in DSP2833x_InitPeripherals.c
// InitPeripherals(); // Not required for this example

// For this example, only initialize the ePWM
// Step 5. User specific code, enable interrupts:

update =1;
DutyFine =0;

EALLOW;
SysCtrlRegs.PCLKCR0.bit.TBCLKSYNC = 0;
EDIS;

// Some useful Period vs Frequency values
// SYSCLKOUT = 150MHz 100 MHz
// -----------------------------------------
// Period Frequency Frequency
// 1000 150 kHz 100 KHz
// 800 187 kHz 125 KHz
// 600 250 kHz 167 KHz
// 500 300 kHz 200 KHz
// 250 600 kHz 400 KHz
// 200 750 kHz 500 KHz
// 100 1.5 MHz 1.0 MHz
// 50 3.0 MHz 2.0 MHz
// 25 6.0 MHz 4.0 MHz
// 20 7.5 MHz 5.0 MHz
// 12 12.5 MHz 8.33 MHz
// 10 15.0 MHz 10.0 MHz
// 9 16.7 MHz 11.1 MHz
// 8 18.8 MHz 12.5 MHz
// 7 21.4 MHz 14.3 MHz
// 6 25.0 MHz 16.7 MHz
// 5 30.0 MHz 20.0 MHz

//====================================================================
// ePWM and HRPWM register initializaition
//====================================================================
HRPWM1_Config(110); // ePWM1 target, 15 MHz PWM (SYSCLK=150MHz) or 10 MHz PWM (SYSCLK=100MHz)
HRPWM2_Config(20); // ePWM2 target, 7.5 MHz PWM (SYSCLK=150MHz) or 5 MHz PWM (SYSCLK=100MHz)
HRPWM3_Config(10); // ePWM3 target, 15 MHz PWM (SYSCLK=150MHz) or 10 MHz PWM (SYSCLK=100MHz)
HRPWM4_Config(20); // ePWM4 target, 7.5 MHz PWM (SYSCLK=150MHz) or 5 MHz PWM (SYSCLK=100MHz)

while (update ==1)

{

for(DutyFine =1; DutyFine <256 ;DutyFine ++)
{

// Example, write to the HRPWM extension of CMPA
EPwm1Regs.CMPA.half.CMPAHR = DutyFine << 8; // Left shift by 8 to write into MSB bits
EPwm2Regs.CMPA.half.CMPAHR = DutyFine << 8; // Left shift by 8 to write into MSB bits

// Example, 32-bit write to CMPA:CMPAHR
EPwm3Regs.CMPA.all = ((Uint32)EPwm3Regs.CMPA.half.CMPA << 16) + (DutyFine << 8);
EPwm4Regs.CMPA.all = ((Uint32)EPwm4Regs.CMPA.half.CMPA << 16) + (DutyFine << 8);

for (i=0;i<10000;i++){} // Dummy delay between MEP changes
}
}

}

void HRPWM1_Config(period)
{int x;
int p;
// ePWM1 register configuration with HRPWM
// ePWM1A toggle low/high with MEP control on Rising edge

for(p=0;p<=9;p++)
{x=vsamps[p]/3;
EPwm1Regs.TBCTL.bit.PRDLD = TB_IMMEDIATE; // set Immediate load
EPwm1Regs.TBPRD = period-1; // PWM frequency = 1 / period
EPwm1Regs.CMPA.half.CMPA = period / 2; // set duty 50% initially
EPwm1Regs.CMPA.half.CMPAHR = (1 << 8); // initialize HRPWM extension
EPwm1Regs.CMPB = period *x; // set duty 50% initially
EPwm1Regs.TBPHS.all = 0;
EPwm1Regs.TBCTR = 0;

EPwm1Regs.TBCTL.bit.CTRMODE = TB_COUNT_UP;
EPwm1Regs.TBCTL.bit.PHSEN = TB_DISABLE; // EPWM1 is the Master
EPwm1Regs.TBCTL.bit.SYNCOSEL = TB_SYNC_DISABLE;
EPwm1Regs.TBCTL.bit.HSPCLKDIV = TB_DIV1;
EPwm1Regs.TBCTL.bit.CLKDIV = TB_DIV1;

EPwm1Regs.CMPCTL.bit.LOADAMODE = CC_CTR_ZERO;
EPwm1Regs.CMPCTL.bit.LOADBMODE = CC_CTR_ZERO;
EPwm1Regs.CMPCTL.bit.SHDWAMODE = CC_SHADOW;
EPwm1Regs.CMPCTL.bit.SHDWBMODE = CC_SHADOW;

EPwm1Regs.AQCTLA.bit.ZRO = AQ_CLEAR; // PWM toggle low/high
EPwm1Regs.AQCTLA.bit.CAU = AQ_SET;
EPwm1Regs.AQCTLB.bit.ZRO = AQ_CLEAR;
EPwm1Regs.AQCTLB.bit.CBU = AQ_SET;

EALLOW;
EPwm1Regs.HRCNFG.all = 0x0;
EPwm1Regs.HRCNFG.bit.EDGMODE = HR_REP; //MEP control on Rising edge
EPwm1Regs.HRCNFG.bit.CTLMODE = HR_CMP;
EPwm1Regs.HRCNFG.bit.HRLOAD = HR_CTR_ZERO;
EDIS;
}
}

void HRPWM2_Config(period)
{
// ePWM2 register configuration with HRPWM
// ePWM2A toggle low/high with MEP control on Rising edge

EPwm2Regs.TBCTL.bit.PRDLD = TB_IMMEDIATE; // set Immediate load
EPwm2Regs.TBPRD = period-1; // PWM frequency = 1 / period
EPwm2Regs.CMPA.half.CMPA = period / 2; // set duty 50% initially
EPwm2Regs.CMPA.half.CMPAHR = (1 << 8); // initialize HRPWM extension
EPwm2Regs.CMPB = period / 2; // set duty 50% initially
EPwm2Regs.TBPHS.all = 0;
EPwm2Regs.TBCTR = 0;

EPwm2Regs.TBCTL.bit.CTRMODE = TB_COUNT_UP;
EPwm2Regs.TBCTL.bit.PHSEN = TB_DISABLE; // ePWM2 is the Master
EPwm2Regs.TBCTL.bit.SYNCOSEL = TB_SYNC_DISABLE;
EPwm2Regs.TBCTL.bit.HSPCLKDIV = TB_DIV1;
EPwm2Regs.TBCTL.bit.CLKDIV = TB_DIV1;

EPwm2Regs.CMPCTL.bit.LOADAMODE = CC_CTR_ZERO;
EPwm2Regs.CMPCTL.bit.LOADBMODE = CC_CTR_ZERO;
EPwm2Regs.CMPCTL.bit.SHDWAMODE = CC_SHADOW;
EPwm2Regs.CMPCTL.bit.SHDWBMODE = CC_SHADOW;

EPwm2Regs.AQCTLA.bit.ZRO = AQ_CLEAR; // PWM toggle low/high
EPwm2Regs.AQCTLA.bit.CAU = AQ_SET;
EPwm2Regs.AQCTLB.bit.ZRO = AQ_CLEAR;
EPwm2Regs.AQCTLB.bit.CBU = AQ_SET;

EALLOW;
EPwm2Regs.HRCNFG.all = 0x0;
EPwm2Regs.HRCNFG.bit.EDGMODE = HR_REP; //MEP control on Rising edge
EPwm2Regs.HRCNFG.bit.CTLMODE = HR_CMP;
EPwm2Regs.HRCNFG.bit.HRLOAD = HR_CTR_ZERO;

EDIS;

}
void HRPWM3_Config(period)
{
// ePWM3 register configuration with HRPWM
// ePWM3A toggle high/low with MEP control on falling edge

EPwm3Regs.TBCTL.bit.PRDLD = TB_IMMEDIATE; // set Immediate load
EPwm3Regs.TBPRD = period-1; // PWM frequency = 1 / period
EPwm3Regs.CMPA.half.CMPA = period / 2; // set duty 50% initially
EPwm3Regs.CMPA.half.CMPAHR = (1 << 8); // initialize HRPWM extension
EPwm3Regs.CMPB = period / 2; // set duty 50% initially
EPwm3Regs.TBPHS.all = 0;
EPwm3Regs.TBCTR = 0;

EPwm3Regs.TBCTL.bit.CTRMODE = TB_COUNT_UP;
EPwm3Regs.TBCTL.bit.PHSEN = TB_DISABLE; // ePWM3 is the Master
EPwm3Regs.TBCTL.bit.SYNCOSEL = TB_SYNC_DISABLE;
EPwm3Regs.TBCTL.bit.HSPCLKDIV = TB_DIV1;
EPwm3Regs.TBCTL.bit.CLKDIV = TB_DIV1;

EPwm3Regs.CMPCTL.bit.LOADAMODE = CC_CTR_ZERO;
EPwm3Regs.CMPCTL.bit.LOADBMODE = CC_CTR_ZERO;
EPwm3Regs.CMPCTL.bit.SHDWAMODE = CC_SHADOW;
EPwm3Regs.CMPCTL.bit.SHDWBMODE = CC_SHADOW;

EPwm3Regs.AQCTLA.bit.ZRO = AQ_SET; // PWM toggle high/low
EPwm3Regs.AQCTLA.bit.CAU = AQ_CLEAR;
EPwm3Regs.AQCTLB.bit.ZRO = AQ_SET;
EPwm3Regs.AQCTLB.bit.CBU = AQ_CLEAR;

EALLOW;
EPwm3Regs.HRCNFG.all = 0x0;
EPwm3Regs.HRCNFG.bit.EDGMODE = HR_FEP; //MEP control on falling edge
EPwm3Regs.HRCNFG.bit.CTLMODE = HR_CMP;
EPwm3Regs.HRCNFG.bit.HRLOAD = HR_CTR_ZERO;
EDIS;
}

void HRPWM4_Config(period)
{
// ePWM4 register configuration with HRPWM
// ePWM4A toggle high/low with MEP control on falling edge

EPwm4Regs.TBCTL.bit.PRDLD = TB_IMMEDIATE; // set Immediate load
EPwm4Regs.TBPRD = period-1; // PWM frequency = 1 / period
EPwm4Regs.CMPA.half.CMPA = period / 2; // set duty 50% initially
EPwm4Regs.CMPA.half.CMPAHR = (1 << 8); // initialize HRPWM extension
EPwm4Regs.CMPB = period / 2; // set duty 50% initially
EPwm4Regs.TBPHS.all = 0;
EPwm4Regs.TBCTR = 0;

EPwm4Regs.TBCTL.bit.CTRMODE = TB_COUNT_UP;
EPwm4Regs.TBCTL.bit.PHSEN = TB_DISABLE; // ePWM4 is the Master
EPwm4Regs.TBCTL.bit.SYNCOSEL = TB_SYNC_DISABLE;
EPwm4Regs.TBCTL.bit.HSPCLKDIV = TB_DIV1;
EPwm4Regs.TBCTL.bit.CLKDIV = TB_DIV1;

EPwm4Regs.CMPCTL.bit.LOADAMODE = CC_CTR_ZERO;
EPwm4Regs.CMPCTL.bit.LOADBMODE = CC_CTR_ZERO;
EPwm4Regs.CMPCTL.bit.SHDWAMODE = CC_SHADOW;
EPwm4Regs.CMPCTL.bit.SHDWBMODE = CC_SHADOW;

EPwm4Regs.AQCTLA.bit.ZRO = AQ_SET; // PWM toggle high/low
EPwm4Regs.AQCTLA.bit.CAU = AQ_CLEAR;
EPwm4Regs.AQCTLB.bit.ZRO = AQ_SET;
EPwm4Regs.AQCTLB.bit.CBU = AQ_CLEAR;

EALLOW;
EPwm4Regs.HRCNFG.all = 0x0;
EPwm4Regs.HRCNFG.bit.EDGMODE = HR_FEP; // MEP control on falling edge
EPwm4Regs.HRCNFG.bit.CTLMODE = HR_CMP;
EPwm4Regs.HRCNFG.bit.HRLOAD = HR_CTR_ZERO;
EDIS;
}

Thanks. 

Julius