ADC.rar_28027 adc_28027 adc 12864_tms320f28027_tms320f28027 adc

// TI File $Revision: /main/3 $ // Checkin $Date: July 6, 2009 14:02:51 $ //########################################################################### // // FILE: Example_2802xAdcSoc.c // // TITLE: DSP2802x ADC Start-Of-Conversion (SOC) Example Program. // // ASSUMPTIONS: // // This program requires the DSP2802x header files. // // Make sure the CPU clock speed is properly defined in // DSP2802x_Examples.h before compiling this example. // // Connect signals to be converted to A2 and A3. // // As supplied, this project is configured for "boot to SARAM" // operation. The 2802x Boot Mode table is shown below. // For information on configuring the boot mode of an eZdsp, // please refer to the documentation included with the eZdsp, // // $Boot_Table // While an emulator is connected to your device, the TRSTn pin = 1, // which sets the device into EMU_BOOT boot mode. In this mode, the // peripheral boot modes are as follows: // // Boot Mode: EMU_KEY EMU_BMODE // (0xD00) (0xD01) // --------------------------------------- // Wait !=0x55AA X // I/O 0x55AA 0x0000 // SCI 0x55AA 0x0001 // Wait 0x55AA 0x0002 // Get_Mode 0x55AA 0x0003 // SPI 0x55AA 0x0004 // I2C 0x55AA 0x0005 // OTP 0x55AA 0x0006 // Wait 0x55AA 0x0007 // Wait 0x55AA 0x0008 // SARAM 0x55AA 0x000A <-- "Boot to SARAM" // Flash 0x55AA 0x000B // Wait 0x55AA Other // // Write EMU_KEY to 0xD00 and EMU_BMODE to 0xD01 via the debugger // according to the Boot Mode Table above. Build/Load project, // Reset the device, and Run example // // $End_Boot_Table // // // DESCRIPTION: // // This example sets up the PLL in x12/2 mode. // // For 60 MHz devices (default) // (assuming a 10Mhz input clock). // // Interrupts are enabled and the ePWM1 is setup to generate a periodic // ADC SOC - ADCINT1. Two channels are converted, ADCINA4 and ADCINA2. // // Watch Variables: // // Voltage1[10] Last 10 ADCRESULT0 values // Voltage2[10] Last 10 ADCRESULT1 values // ConversionCount Current result number 0-9 // LoopCount Idle loop counter // // //########################################################################### // $TI Release: 2802x C/C++ Header Files V1.26 $ // $Release Date: February 2, 2010 $ //########################################################################### #include "DSP28x_Project.h" // Device Headerfile and Examples Include File // Prototype statements for functions found within this file. interrupt void adc_isr(void); void Adc_Config(void); // Global variables used in this example: Uint16 LoopCount; Uint16 ConversionCount; Uint16 Voltage1[10]; Uint16 Voltage2[10]; main() { // Step 1. Initialize System Control: // PLL, WatchDog, enable Peripheral Clocks // This example function is found in the DSP2803x_SysCtrl.c file. InitSysCtrl(); // Step 2. Initialize GPIO: // This example function is found in the DSP2802x_Gpio.c file and // illustrates how to set the GPIO to it's default state. // InitGpio(); // Skipped for this example // 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 DSP2802x_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 DSP2802x_DefaultIsr.c. // This function is found in DSP2802x_PieVect.c. InitPieVectTable(); // Interrupts that are used in this example are re-mapped to // ISR functions found within this file. EALLOW; // This is needed to write to EALLOW protected register PieVectTable.ADCINT1 = &adc_isr; EDIS; // This is needed to disable write to EALLOW protected registers // Step 4. Initialize all the Device Peripherals: // This function is found in DSP2802x_InitPeripherals.c // InitPeripherals(); // Not required for this example InitAdc(); // For this example, init the ADC // Step 5. User specific code, enable interrupts: // Enable ADCINT1 in PIE PieCtrlRegs.PIEIER1.bit.INTx1 = 1; // Enable INT 1.1 in the PIE IER |= M_INT1; // Enable CPU Interrupt 1 EINT; // Enable Global interrupt INTM ERTM; // Enable Global realtime interrupt DBGM LoopCount = 0; ConversionCount = 0; // Configure ADC EALLOW; AdcRegs.ADCCTL1.bit.INTPULSEPOS = 1; //ADCINT1 trips after AdcResults latch AdcRegs.INTSEL1N2.bit.INT1E = 1; //Enabled ADCINT1 AdcRegs.INTSEL1N2.bit.INT1CONT = 0; //Disable ADCINT1 Continuous mode AdcRegs.INTSEL1N2.bit.INT1SEL = 1; //setup EOC1 to trigger ADCINT1 to fire AdcRegs.ADCSOC0CTL.bit.CHSEL = 4; //set SOC0 channel select to ADCINA4 AdcRegs.ADCSOC1CTL.bit.CHSEL = 2; //set SOC1 channel select to ADCINA2 AdcRegs.ADCSOC0CTL.bit.TRIGSEL = 5; //set SOC0 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1 AdcRegs.ADCSOC1CTL.bit.TRIGSEL = 5; //set SOC1 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1 AdcRegs.ADCSOC0CTL.bit.ACQPS = 6; //set SOC0 S/H Window to 7 ADC Clock Cycles, (6 ACQPS plus 1) AdcRegs.ADCSOC1CTL.bit.ACQPS = 6; //set SOC1 S/H Window to 7 ADC Clock Cycles, (6 ACQPS plus 1) EDIS; // Assumes ePWM1 clock is already enabled in InitSysCtrl(); EPwm1Regs.ETSEL.bit.SOCAEN = 1; // Enable SOC on A group EPwm1Regs.ETSEL.bit.SOCASEL = 4; // Select SOC from from CPMA on upcount EPwm1Regs.ETPS.bit.SOCAPRD = 1; // Generate pulse on 1st event EPwm1Regs.CMPA.half.CMPA = 0x0080; // Set compare A value EPwm1Regs.TBPRD = 0xFFFF; // Set period for ePWM1 EPwm1Regs.TBCTL.bit.CTRMODE = 0; // count up and start // Wait for ADC interrupt for(;;) { LoopCount++; } } interrupt void adc_isr(void) { Voltage1[ConversionCount] = AdcResult.ADCRESULT0; Voltage2[ConversionCount] = AdcResult.ADCRESULT1; // If 20 conversions have been logged, start over if(ConversionCount == 9) { ConversionCount = 0; } else ConversionCount++; AdcRegs.ADCINTFLGCLR.bit.ADCINT1 = 1; //Clear ADCINT1 flag reinitialize for next SOC PieCtrlRegs.PIEACK.all = PIEACK_GROUP1; // Acknowledge interrupt to PIE return; }