Clare Coleman
/
UTCSBootcamp
Wrapped Freescale Cup code for the UT CS summer boot camp.
Includes/TFC.cpp
- Committer:
- ccoleman
- Date:
- 2013-08-23
- Revision:
- 6:4b101f051a1f
- Parent:
- TFC.cpp@ 4:4233d072b5af
File content as of revision 6:4b101f051a1f:
#include "mbed.h" #include "TFC.h" #define FTM1_CLK_PRESCALE 6// Prescale Selector value - see comments in Status Control (SC) section for more details #define SERVO_DEFAULT_PERIOD (float)(.020) // Desired Frequency of PWM Signal - Here 50Hz => 20ms period // use these to dial in servo steering to your particular servo #define SERVO_MIN_PULSE_WIDTH_DEFAULT (float)(.0005) // The number here should be be *pulse width* in seconds to move servo to its left limit #define SERVO_MAX_PULSE_WIDTH_DEFAULT (float)(.002) // The number here should be be *pulse width* in seconds to move servo to its left limit #define FTM0_CLOCK (SystemCoreClock/2) #define FTM0_CLK_PRESCALE (0) // Prescale Selector value - see comments in Status Control (SC) section for more details #define FTM0_DEFAULT_SWITCHING_FREQUENCY (4000.0) #define ADC_MAX_CODE (255) #define TAOS_CLK_HIGH PTE->PSOR = (1<<1) #define TAOS_CLK_LOW PTE->PCOR = (1<<1) #define TAOS_SI_HIGH PTD->PSOR = (1<<7) #define TAOS_SI_LOW PTD->PCOR = (1<<7) #define ADC_STATE_INIT 0 #define ADC_STATE_CAPTURE_POT_0 1 #define ADC_STATE_CAPTURE_POT_1 2 #define ADC_STATE_CAPTURE_BATTERY_LEVEL 3 #define ADC_STATE_CAPTURE_LINE_SCAN 4 #define TFC_POT_0_ADC_CHANNEL 13 #define TFC_POT_1_ADC_CHANNEL 12 #define TFC_BAT_SENSE_CHANNEL 4 #define TFC_LINESCAN0_ADC_CHANNEL 6 #define TFC_LINESCAN1_ADC_CHANNEL 7 #define ADC0_irq_no 57 #define ADC1_irq_no 58 #define ADC0_CHANA 19 // set to desired ADC0 channel trigger A #define ADC0_CHANB 20 // set to desired ADC0 channel trigger B #define ADC1_CHANA 20 // set to desired ADC1 channel trigger A 20 defaults to potentiometer in TWRK60 #define ADC1_CHANB 20 // set to desired ADC1 channel trigger B #define ADC0_DLYA 0x2000 // ADC0 trigger A delay #define ADC0_DLYB 0x4000 // ADC0 trigger B delay #define ADC1_DLYA 0x6000 // ADC1 trigger A delay #define ADC1_DLYB 0x7fff // ADC1 trigger B delay #define ADC0A_DONE 0x01 #define ADC0B_DONE 0x02 #define ADC1A_DONE 0x04 #define ADC1B_DONE 0x08 // Bit shifting of bitfiled is already taken into account so // bitfiled values are always represented as relative to their position. /************************* #Defines ******************************************/ #define A 0x0 #define B 0x1 /////// NOTE: the following defines relate to the ADC register definitions /////// and the content follows the reference manual, using the same symbols. //// ADCSC1 (register) // Conversion Complete (COCO) mask #define COCO_COMPLETE ADC_SC1_COCO_MASK #define COCO_NOT 0x00 // ADC interrupts: enabled, or disabled. #define AIEN_ON ADC_SC1_AIEN_MASK #define AIEN_OFF 0x00 // Differential or Single ended ADC input #define DIFF_SINGLE 0x00 #define DIFF_DIFFERENTIAL ADC_SC1_DIFF_MASK //// ADCCFG1 // Power setting of ADC #define ADLPC_LOW ADC_CFG1_ADLPC_MASK #define ADLPC_NORMAL 0x00 // Clock divisor #define ADIV_1 0x00 #define ADIV_2 0x01 #define ADIV_4 0x02 #define ADIV_8 0x03 // Long samle time, or Short sample time #define ADLSMP_LONG ADC_CFG1_ADLSMP_MASK #define ADLSMP_SHORT 0x00 // How many bits for the conversion? 8, 12, 10, or 16 (single ended). #define MODE_8 0x00 #define MODE_12 0x01 #define MODE_10 0x02 #define MODE_16 0x03 // ADC Input Clock Source choice? Bus clock, Bus clock/2, "altclk", or the // ADC's own asynchronous clock for less noise #define ADICLK_BUS 0x00 #define ADICLK_BUS_2 0x01 #define ADICLK_ALTCLK 0x02 #define ADICLK_ADACK 0x03 //// ADCCFG2 // Select between B or A channels #define MUXSEL_ADCB ADC_CFG2_MUXSEL_MASK #define MUXSEL_ADCA 0x00 // Ansync clock output enable: enable, or disable the output of it #define ADACKEN_ENABLED ADC_CFG2_ADACKEN_MASK #define ADACKEN_DISABLED 0x00 // High speed or low speed conversion mode #define ADHSC_HISPEED ADC_CFG2_ADHSC_MASK #define ADHSC_NORMAL 0x00 // Long Sample Time selector: 20, 12, 6, or 2 extra clocks for a longer sample time #define ADLSTS_20 0x00 #define ADLSTS_12 0x01 #define ADLSTS_6 0x02 #define ADLSTS_2 0x03 ////ADCSC2 // Read-only status bit indicating conversion status #define ADACT_ACTIVE ADC_SC2_ADACT_MASK #define ADACT_INACTIVE 0x00 // Trigger for starting conversion: Hardware trigger, or software trigger. // For using PDB, the Hardware trigger option is selected. #define ADTRG_HW ADC_SC2_ADTRG_MASK #define ADTRG_SW 0x00 // ADC Compare Function Enable: Disabled, or Enabled. #define ACFE_DISABLED 0x00 #define ACFE_ENABLED ADC_SC2_ACFE_MASK // Compare Function Greater Than Enable: Greater, or Less. #define ACFGT_GREATER ADC_SC2_ACFGT_MASK #define ACFGT_LESS 0x00 // Compare Function Range Enable: Enabled or Disabled. #define ACREN_ENABLED ADC_SC2_ACREN_MASK #define ACREN_DISABLED 0x00 // DMA enable: enabled or disabled. #define DMAEN_ENABLED ADC_SC2_DMAEN_MASK #define DMAEN_DISABLED 0x00 // Voltage Reference selection for the ADC conversions // (***not*** the PGA which uses VREFO only). // VREFH and VREFL (0) , or VREFO (1). #define REFSEL_EXT 0x00 #define REFSEL_ALT 0x01 #define REFSEL_RES 0x02 /* reserved */ #define REFSEL_RES_EXT 0x03 /* reserved but defaults to Vref */ ////ADCSC3 // Calibration begin or off #define CAL_BEGIN ADC_SC3_CAL_MASK #define CAL_OFF 0x00 // Status indicating Calibration failed, or normal success #define CALF_FAIL ADC_SC3_CALF_MASK #define CALF_NORMAL 0x00 // ADC to continously convert, or do a sinle conversion #define ADCO_CONTINUOUS ADC_SC3_ADCO_MASK #define ADCO_SINGLE 0x00 // Averaging enabled in the ADC, or not. #define AVGE_ENABLED ADC_SC3_AVGE_MASK #define AVGE_DISABLED 0x00 // How many to average prior to "interrupting" the MCU? 4, 8, 16, or 32 #define AVGS_4 0x00 #define AVGS_8 0x01 #define AVGS_16 0x02 #define AVGS_32 0x03 ////PGA // PGA enabled or not? #define PGAEN_ENABLED ADC_PGA_PGAEN_MASK #define PGAEN_DISABLED 0x00 // Chopper stabilization of the amplifier, or not. #define PGACHP_CHOP ADC_PGA_PGACHP_MASK #define PGACHP_NOCHOP 0x00 // PGA in low power mode, or normal mode. #define PGALP_LOW ADC_PGA_PGALP_MASK #define PGALP_NORMAL 0x00 // Gain of PGA. Selectable from 1 to 64. #define PGAG_1 0x00 #define PGAG_2 0x01 #define PGAG_4 0x02 #define PGAG_8 0x03 #define PGAG_16 0x04 #define PGAG_32 0x05 #define PGAG_64 0x06 #define ADC_STATE_INIT 0 #define ADC_STATE_CAPTURE_POT_0 1 #define ADC_STATE_CAPTURE_POT_1 2 #define ADC_STATE_CAPTURE_BATTERY_LEVEL 3 #define ADC_STATE_CAPTURE_LINE_SCAN 4 /////////// The above values fit into the structure below to select ADC/PGA /////////// configuration desired: typedef struct adc_cfg { uint8_t CONFIG1; uint8_t CONFIG2; uint16_t COMPARE1; uint16_t COMPARE2; uint8_t STATUS2; uint8_t STATUS3; uint8_t STATUS1A; uint8_t STATUS1B; uint32_t PGA; } *tADC_ConfigPtr, tADC_Config ; #define CAL_BLK_NUMREC 18 typedef struct adc_cal { uint16_t OFS; uint16_t PG; uint16_t MG; uint8_t CLPD; uint8_t CLPS; uint16_t CLP4; uint16_t CLP3; uint8_t CLP2; uint8_t CLP1; uint8_t CLP0; uint8_t dummy; uint8_t CLMD; uint8_t CLMS; uint16_t CLM4; uint16_t CLM3; uint8_t CLM2; uint8_t CLM1; uint8_t CLM0; } tADC_Cal_Blk ; typedef struct ADC_MemMap { uint32_t SC1[2]; /**< ADC Status and Control Registers 1, array offset: 0x0, array step: 0x4 */ uint32_t CFG1; /**< ADC Configuration Register 1, offset: 0x8 */ uint32_t CFG2; /**< ADC Configuration Register 2, offset: 0xC */ uint32_t R[2]; /**< ADC Data Result Register, array offset: 0x10, array step: 0x4 */ uint32_t CV1; /**< Compare Value Registers, offset: 0x18 */ uint32_t CV2; /**< Compare Value Registers, offset: 0x1C */ uint32_t SC2; /**< Status and Control Register 2, offset: 0x20 */ uint32_t SC3; /**< Status and Control Register 3, offset: 0x24 */ uint32_t OFS; /**< ADC Offset Correction Register, offset: 0x28 */ uint32_t PG; /**< ADC Plus-Side Gain Register, offset: 0x2C */ uint32_t MG; /**< ADC Minus-Side Gain Register, offset: 0x30 */ uint32_t CLPD; /**< ADC Plus-Side General Calibration Value Register, offset: 0x34 */ uint32_t CLPS; /**< ADC Plus-Side General Calibration Value Register, offset: 0x38 */ uint32_t CLP4; /**< ADC Plus-Side General Calibration Value Register, offset: 0x3C */ uint32_t CLP3; /**< ADC Plus-Side General Calibration Value Register, offset: 0x40 */ uint32_t CLP2; /**< ADC Plus-Side General Calibration Value Register, offset: 0x44 */ uint32_t CLP1; /**< ADC Plus-Side General Calibration Value Register, offset: 0x48 */ uint32_t CLP0; /**< ADC Plus-Side General Calibration Value Register, offset: 0x4C */ uint8_t RESERVED_0[4]; uint32_t CLMD; /**< ADC Minus-Side General Calibration Value Register, offset: 0x54 */ uint32_t CLMS; /**< ADC Minus-Side General Calibration Value Register, offset: 0x58 */ uint32_t CLM4; /**< ADC Minus-Side General Calibration Value Register, offset: 0x5C */ uint32_t CLM3; /**< ADC Minus-Side General Calibration Value Register, offset: 0x60 */ uint32_t CLM2; /**< ADC Minus-Side General Calibration Value Register, offset: 0x64 */ uint32_t CLM1; /**< ADC Minus-Side General Calibration Value Register, offset: 0x68 */ uint32_t CLM0; /**< ADC Minus-Side General Calibration Value Register, offset: 0x6C */ } volatile *ADC_MemMapPtr; /* ADC - Register accessors */ #define ADC_SC1_REG(base,index) ((base)->SC1[index]) #define ADC_CFG1_REG(base) ((base)->CFG1) #define ADC_CFG2_REG(base) ((base)->CFG2) #define ADC_R_REG(base,index) ((base)->R[index]) #define ADC_CV1_REG(base) ((base)->CV1) #define ADC_CV2_REG(base) ((base)->CV2) #define ADC_SC2_REG(base) ((base)->SC2) #define ADC_SC3_REG(base) ((base)->SC3) #define ADC_OFS_REG(base) ((base)->OFS) #define ADC_PG_REG(base) ((base)->PG) #define ADC_MG_REG(base) ((base)->MG) #define ADC_CLPD_REG(base) ((base)->CLPD) #define ADC_CLPS_REG(base) ((base)->CLPS) #define ADC_CLP4_REG(base) ((base)->CLP4) #define ADC_CLP3_REG(base) ((base)->CLP3) #define ADC_CLP2_REG(base) ((base)->CLP2) #define ADC_CLP1_REG(base) ((base)->CLP1) #define ADC_CLP0_REG(base) ((base)->CLP0) #define ADC_CLMD_REG(base) ((base)->CLMD) #define ADC_CLMS_REG(base) ((base)->CLMS) #define ADC_CLM4_REG(base) ((base)->CLM4) #define ADC_CLM3_REG(base) ((base)->CLM3) #define ADC_CLM2_REG(base) ((base)->CLM2) #define ADC_CLM1_REG(base) ((base)->CLM1) #define ADC_CLM0_REG(base) ((base)->CLM0) #define ADC0_BASE_PTR ((ADC_MemMapPtr)0x4003B000u) /** Array initializer of ADC peripheral base pointers */ #define ADC_BASE_PTRS { ADC0_BASE_PTR } float _ServoDutyCycleMin; float _ServoDutyCycleMax; float _ServoPeriod; volatile uint16_t QueuedServo0Val; volatile uint16_t QueuedServo1Val; volatile uint8_t TFC_LineScanDataReady; volatile uint8_t *LineScanImage0WorkingBuffer; volatile uint8_t *LineScanImage1WorkingBuffer; volatile uint8_t LineScanImage0Buffer[2][128]; volatile uint8_t LineScanImage1Buffer[2][128]; volatile uint8_t LineScanWorkingBuffer; volatile uint8_t PotADC_Value[2]; volatile uint8_t BatSenseADC_Value; volatile uint8_t CurrentADC_State; volatile uint8_t CurrentLineScanPixel; volatile uint8_t CurrentLineScanChannel; volatile uint32_t TFC_ServoTicker; volatile uint8_t * TFC_LineScanCameraData[2]; void TFC_SetServoDutyCycle(uint8_t ServoNumber, float DutyCycle); void TFC_InitLineScanCamera(); uint8_t ADC_Cal(ADC_MemMapPtr adcmap); void ADC_Config_Alt(ADC_MemMapPtr adcmap, tADC_ConfigPtr ADC_CfgPtr); void ADC_Read_Cal(ADC_MemMapPtr adcmap, tADC_Cal_Blk *blk); void TFC_InitADC0(); void TFC_InitADC_System(); void TFC_GPIO_Init(); void ADC0_Handler(); void TPM1_Handler(); void TFC_Init() { TFC_GPIO_Init(); TFC_InitADC_System(); // Always call this before the Servo init function.... The IRQ for the Servo code modifies ADC registers and the clocks need enable to the ADC peripherals 1st! TFC_InitLineScanCamera(); TFC_InitServos(SERVO_MIN_PULSE_WIDTH_DEFAULT , SERVO_MAX_PULSE_WIDTH_DEFAULT, SERVO_DEFAULT_PERIOD); TFC_ServoTicker = 0; TFC_InitMotorPWM(FTM0_DEFAULT_SWITCHING_FREQUENCY); } void TFC_GPIO_Init() { //enable Clocks to all ports SIM->SCGC5 |= SIM_SCGC5_PORTA_MASK | SIM_SCGC5_PORTB_MASK | SIM_SCGC5_PORTC_MASK | SIM_SCGC5_PORTD_MASK | SIM_SCGC5_PORTE_MASK; //Setup Pins as GPIO PORTE->PCR[21] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; PORTE->PCR[20] = PORT_PCR_MUX(1); //Port for Pushbuttons PORTC->PCR[13] = PORT_PCR_MUX(1); PORTC->PCR[17] = PORT_PCR_MUX(1); //Ports for DIP Switches PORTE->PCR[2] = PORT_PCR_MUX(1); PORTE->PCR[3] = PORT_PCR_MUX(1); PORTE->PCR[4] = PORT_PCR_MUX(1); PORTE->PCR[5] = PORT_PCR_MUX(1); //Ports for LEDs PORTB->PCR[8] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; PORTB->PCR[9] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; PORTB->PCR[10] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; PORTB->PCR[11] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; //Setup the output pins PTE->PDDR = TFC_HBRIDGE_EN_LOC; PTB->PDDR = TFC_BAT_LED0_LOC | TFC_BAT_LED1_LOC | TFC_BAT_LED2_LOC | TFC_BAT_LED3_LOC; TFC_SetBatteryLED(0); TFC_HBRIDGE_DISABLE; } void TFC_SetBatteryLED(uint8_t Value) { if(Value & 0x01) TFC_BAT_LED0_ON; else TFC_BAT_LED0_OFF; if(Value & 0x02) TFC_BAT_LED1_ON; else TFC_BAT_LED1_OFF; if(Value & 0x04) TFC_BAT_LED2_ON; else TFC_BAT_LED2_OFF; if(Value & 0x08) TFC_BAT_LED3_ON; else TFC_BAT_LED3_OFF; } uint8_t TFC_GetDIP_Switch() { uint8_t DIP_Val=0; DIP_Val = (PTE->PDIR>>2) & 0xF; return DIP_Val; } uint8_t TFC_ReadPushButton(uint8_t Index) { if(Index == 0) { return TFC_PUSH_BUTTON_0_PRESSED; } else { return TFC_PUSH_BUTTON_1_PRESSED; } } extern "C" void TPM1_IRQHandler() { //Clear the overflow mask if set. According to the reference manual, we clear by writing a logic one! if(TPM1->SC & TPM_SC_TOF_MASK) TPM1->SC |= TPM_SC_TOF_MASK; //Dump the queued values to the timer channels TPM1->CONTROLS[0].CnV = QueuedServo0Val; TPM1->CONTROLS[1].CnV = QueuedServo1Val; //Prime the next ADC capture cycle TAOS_SI_HIGH; //Prime the ADC pump and start capturing POT 0 CurrentADC_State = ADC_STATE_CAPTURE_POT_0; ADC0->CFG2 &= ~ADC_CFG2_MUXSEL_MASK; //Select the A side of the mux ADC0->SC1[0] = TFC_POT_0_ADC_CHANNEL | ADC_SC1_AIEN_MASK; //Start the State machine at POT0 //Flag that a new cervo cycle will start if (TFC_ServoTicker < 0xffffffff)//if servo tick less than max value, count up... TFC_ServoTicker++; } void TFC_InitServos(float PulseWidthMin, float PulseWidthMax, float ServoPeriod) { _ServoPeriod = ServoPeriod; _ServoDutyCycleMin = PulseWidthMin/ServoPeriod; _ServoDutyCycleMax = PulseWidthMax/ServoPeriod; //Clock Setup for the TPM requires a couple steps. SIM->SCGC6 &= ~SIM_SCGC6_TPM1_MASK; //1st, set the clock mux //See Page 124 of f the KL25 Sub-Family Reference Manual, Rev. 3, September 2012 SIM->SOPT2 |= SIM_SOPT2_PLLFLLSEL_MASK;// We Want MCGPLLCLK/2 (See Page 196 of the KL25 Sub-Family Reference Manual, Rev. 3, September 2012) SIM->SOPT2 &= ~(SIM_SOPT2_TPMSRC_MASK); SIM->SOPT2 |= SIM_SOPT2_TPMSRC(1); //Enable the Clock to the FTM0 Module //See Page 207 of f the KL25 Sub-Family Reference Manual, Rev. 3, September 2012 SIM->SCGC6 |= SIM_SCGC6_TPM1_MASK; //The TPM Module has Clock. Now set up the peripheral //Blow away the control registers to ensure that the counter is not running TPM1->SC = 0; TPM1->CONF = 0; //While the counter is disabled we can setup the prescaler TPM1->SC = TPM_SC_PS(FTM1_CLK_PRESCALE); TPM1->SC |= TPM_SC_TOIE_MASK; //Enable Interrupts for the Timer Overflow //Setup the mod register to get the correct PWM Period TPM1->MOD = (SystemCoreClock/(1<<(FTM1_CLK_PRESCALE))) * _ServoPeriod; //Setup Channels 0 and 1 TPM1->CONTROLS[0].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSB_MASK; TPM1->CONTROLS[1].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSB_MASK; //Set the Default duty cycle to servo neutral TFC_SetServo(0, 0.0); TFC_SetServo(1, 0.0); //Enable the TPM COunter TPM1->SC |= TPM_SC_CMOD(1); //Enable TPM1 IRQ on the NVIC //NVIC_SetVector(TPM1_IRQn,(uint32_t)TPM1_Handler); NVIC_EnableIRQ(TPM1_IRQn); //Enable the FTM functions on the the port PORTB->PCR[0] = PORT_PCR_MUX(3); PORTB->PCR[1] = PORT_PCR_MUX(3); } void TFC_SetServoDutyCycle(uint8_t ServoNumber, float DutyCycle) { switch(ServoNumber) { default: case 0: QueuedServo0Val = TPM1->MOD * DutyCycle; break; case 1: QueuedServo1Val = TPM1->MOD * DutyCycle; break; } } void TFC_SetServo(uint8_t ServoNumber, float Position) { TFC_SetServoDutyCycle(ServoNumber , ((Position + 1.0)/2) * ((_ServoDutyCycleMax - _ServoDutyCycleMin)+_ServoDutyCycleMin) ); } //******************************************************************************************************** //******************************************************************************************************** //******************************************************************************************************** // _____ _____ ______ _ _ _ _ _____ _______ _____ ____ _ _ _____ // /\ | __ \ / ____| | ____| | | | \ | |/ ____|__ __|_ _/ __ \| \ | |/ ____| // / \ | | | | | | |__ | | | | \| | | | | | || | | | \| | (___ // / /\ \ | | | | | | __| | | | | . ` | | | | | || | | | . ` |\___ \ // / ____ \| |__| | |____ | | | |__| | |\ | |____ | | _| || |__| | |\ |____) | // /_/ \_\_____/ \_____| |_| \____/|_| \_|\_____| |_| |_____\____/|_| \_|_____/ // ******************************************************************************************************** // ******************************************************************************************************** // ******************************************************************************************************** uint8_t ADC_Cal(ADC_MemMapPtr adcmap) { uint16_t cal_var; ADC_SC2_REG(adcmap) &= ~ADC_SC2_ADTRG_MASK ; // Enable Software Conversion Trigger for Calibration Process - ADC0_SC2 = ADC0_SC2 | ADC_SC2_ADTRGW(0); ADC_SC3_REG(adcmap) &= ( ~ADC_SC3_ADCO_MASK & ~ADC_SC3_AVGS_MASK ); // set single conversion, clear avgs bitfield for next writing ADC_SC3_REG(adcmap) |= ( ADC_SC3_AVGE_MASK | ADC_SC3_AVGS(AVGS_32) ); // Turn averaging ON and set at max value ( 32 ) ADC_SC3_REG(adcmap) |= ADC_SC3_CAL_MASK ; // Start CAL while ( (ADC_SC1_REG(adcmap,A) & ADC_SC1_COCO_MASK ) == COCO_NOT ); // Wait calibration end if ((ADC_SC3_REG(adcmap)& ADC_SC3_CALF_MASK) == CALF_FAIL ) { return(1); // Check for Calibration fail error and return } // Calculate plus-side calibration cal_var = 0x00; cal_var = ADC_CLP0_REG(adcmap); cal_var += ADC_CLP1_REG(adcmap); cal_var += ADC_CLP2_REG(adcmap); cal_var += ADC_CLP3_REG(adcmap); cal_var += ADC_CLP4_REG(adcmap); cal_var += ADC_CLPS_REG(adcmap); cal_var = cal_var/2; cal_var |= 0x8000; // Set MSB ADC_PG_REG(adcmap) = ADC_PG_PG(cal_var); // Calculate minus-side calibration cal_var = 0x00; cal_var = ADC_CLM0_REG(adcmap); cal_var += ADC_CLM1_REG(adcmap); cal_var += ADC_CLM2_REG(adcmap); cal_var += ADC_CLM3_REG(adcmap); cal_var += ADC_CLM4_REG(adcmap); cal_var += ADC_CLMS_REG(adcmap); cal_var = cal_var/2; cal_var |= 0x8000; // Set MSB ADC_MG_REG(adcmap) = ADC_MG_MG(cal_var); ADC_SC3_REG(adcmap) &= ~ADC_SC3_CAL_MASK ; /* Clear CAL bit */ return(0); } void ADC_Config_Alt(ADC_MemMapPtr adcmap, tADC_ConfigPtr ADC_CfgPtr) { ADC_CFG1_REG(adcmap) = ADC_CfgPtr->CONFIG1; ADC_CFG2_REG(adcmap) = ADC_CfgPtr->CONFIG2; ADC_CV1_REG(adcmap) = ADC_CfgPtr->COMPARE1; ADC_CV2_REG(adcmap) = ADC_CfgPtr->COMPARE2; ADC_SC2_REG(adcmap) = ADC_CfgPtr->STATUS2; ADC_SC3_REG(adcmap) = ADC_CfgPtr->STATUS3; //ADC_PGA_REG(adcmap) = ADC_CfgPtr->PGA; ADC_SC1_REG(adcmap,A)= ADC_CfgPtr->STATUS1A; ADC_SC1_REG(adcmap,B)= ADC_CfgPtr->STATUS1B; } void ADC_Read_Cal(ADC_MemMapPtr adcmap, tADC_Cal_Blk *blk) { blk->OFS = ADC_OFS_REG(adcmap); blk->PG = ADC_PG_REG(adcmap); blk->MG = ADC_MG_REG(adcmap); blk->CLPD = ADC_CLPD_REG(adcmap); blk->CLPS = ADC_CLPS_REG(adcmap); blk->CLP4 = ADC_CLP4_REG(adcmap); blk->CLP3 = ADC_CLP3_REG(adcmap); blk->CLP2 = ADC_CLP2_REG(adcmap); blk->CLP1 = ADC_CLP1_REG(adcmap); blk->CLP0 = ADC_CLP0_REG(adcmap); blk->CLMD = ADC_CLMD_REG(adcmap); blk->CLMS = ADC_CLMS_REG(adcmap); blk->CLM4 = ADC_CLM4_REG(adcmap); blk->CLM3 = ADC_CLM3_REG(adcmap); blk->CLM2 = ADC_CLM2_REG(adcmap); blk->CLM1 = ADC_CLM1_REG(adcmap); blk->CLM0 = ADC_CLM0_REG(adcmap); } void TFC_InitADC0() { tADC_Config Master_Adc0_Config; SIM->SCGC6 |= (SIM_SCGC6_ADC0_MASK); //Lets calibrate the ADC. 1st setup how the channel will be used. Master_Adc0_Config.CONFIG1 = ADLPC_NORMAL //No low power mode | ADC_CFG1_ADIV(ADIV_4) //divide input by 4 | ADLSMP_LONG //long sample time | ADC_CFG1_MODE(MODE_8)//single ended 8-bit conversion | ADC_CFG1_ADICLK(ADICLK_BUS); Master_Adc0_Config.CONFIG2 = MUXSEL_ADCA // select the A side of the ADC channel. | ADACKEN_DISABLED | ADHSC_HISPEED | ADC_CFG2_ADLSTS(ADLSTS_2);//Extra long sample Time (20 extra clocks) Master_Adc0_Config.COMPARE1 = 00000; // Comparators don't matter for calibration Master_Adc0_Config.COMPARE1 = 0xFFFF; Master_Adc0_Config.STATUS2 = ADTRG_HW //hardware triggers for calibration | ACFE_DISABLED //disable comparator | ACFGT_GREATER | ACREN_ENABLED | DMAEN_DISABLED //Disable DMA | ADC_SC2_REFSEL(REFSEL_EXT); //External Reference Master_Adc0_Config.STATUS3 = CAL_OFF | ADCO_SINGLE | AVGE_ENABLED | ADC_SC3_AVGS(AVGS_4); Master_Adc0_Config.PGA = 0; // Disable the PGA // Configure ADC as it will be used, but because ADC_SC1_ADCH is 31, // the ADC will be inactive. Channel 31 is just disable function. // There really is no channel 31. Master_Adc0_Config.STATUS1A = AIEN_ON | DIFF_SINGLE | ADC_SC1_ADCH(31); ADC_Config_Alt(ADC0_BASE_PTR, &Master_Adc0_Config); // config ADC // Calibrate the ADC in the configuration in which it will be used: ADC_Cal(ADC0_BASE_PTR); // do the calibration Master_Adc0_Config.STATUS2 = ACFE_DISABLED //disable comparator | ACFGT_GREATER | ACREN_ENABLED | DMAEN_DISABLED //Disable DMA | ADC_SC2_REFSEL(REFSEL_EXT); //External Reference Master_Adc0_Config.STATUS3 = CAL_OFF | ADCO_SINGLE; ADC_Config_Alt(ADC0_BASE_PTR, &Master_Adc0_Config); } void TFC_InitADC_System() { TFC_InitADC0(); //All Adc processing of the Pots and linescan will be done in the ADC0 IRQ! //A state machine will scan through the channels. //This is done to automate the linescan capture on Channel 0 to ensure that timing is very even CurrentADC_State = ADC_STATE_INIT; //The pump will be primed with the TPM1 interrupt. upon timeout/interrupt it will set the SI signal high //for the camera and then start the conversions for the pots. // NVIC_SetVector(ADC0_IRQn,(uint32_t)ADC0_Handler); NVIC_EnableIRQ(ADC0_IRQn); } extern "C" void ADC0_IRQHandler() { uint8_t Junk; switch(CurrentADC_State) { default: Junk = ADC0->R[0]; break; case ADC_STATE_CAPTURE_POT_0: PotADC_Value[0] = ADC0->R[0]; ADC0->CFG2 &= ~ADC_CFG2_MUXSEL_MASK; //Select the A side of the mux ADC0->SC1[0] = TFC_POT_1_ADC_CHANNEL | ADC_SC1_AIEN_MASK; CurrentADC_State = ADC_STATE_CAPTURE_POT_1; break; case ADC_STATE_CAPTURE_POT_1: PotADC_Value[1] = ADC0->R[0]; ADC0->CFG2 |= ADC_CFG2_MUXSEL_MASK; //Select the B side of the mux ADC0->SC1[0] = TFC_BAT_SENSE_CHANNEL| ADC_SC1_AIEN_MASK; CurrentADC_State = ADC_STATE_CAPTURE_BATTERY_LEVEL; break; case ADC_STATE_CAPTURE_BATTERY_LEVEL: BatSenseADC_Value = ADC0->R[0]; //Now we will start the sequence for the Linescan camera TAOS_CLK_HIGH; for(Junk = 0; Junk<50; Junk++) { } TAOS_SI_LOW; CurrentLineScanPixel = 0; CurrentLineScanChannel = 0; CurrentADC_State = ADC_STATE_CAPTURE_LINE_SCAN; ADC0->CFG2 |= ADC_CFG2_MUXSEL_MASK; //Select the B side of the mux ADC0->SC1[0] = TFC_LINESCAN0_ADC_CHANNEL | ADC_SC1_AIEN_MASK; break; case ADC_STATE_CAPTURE_LINE_SCAN: if(CurrentLineScanPixel<129) { if(CurrentLineScanChannel == 0) { LineScanImage0WorkingBuffer[CurrentLineScanPixel] = ADC0->R[0]; ADC0->SC1[0] = TFC_LINESCAN1_ADC_CHANNEL | ADC_SC1_AIEN_MASK; CurrentLineScanChannel = 1; } else { LineScanImage1WorkingBuffer[CurrentLineScanPixel] = ADC0->R[0]; ADC0->SC1[0] = TFC_LINESCAN0_ADC_CHANNEL | ADC_SC1_AIEN_MASK; CurrentLineScanChannel = 0; CurrentLineScanPixel++; TAOS_CLK_LOW; for(Junk = 0; Junk<50; Junk++) { } TAOS_CLK_HIGH; } } else { // done with the capture sequence. we can wait for the PIT0 IRQ to restart TAOS_CLK_HIGH; for(Junk = 0; Junk<50; Junk++) { } TAOS_CLK_LOW; CurrentADC_State = ADC_STATE_INIT; //swap the buffer if(LineScanWorkingBuffer == 0) { LineScanWorkingBuffer = 1; LineScanImage0WorkingBuffer = &LineScanImage0Buffer[1][0]; LineScanImage1WorkingBuffer = &LineScanImage1Buffer[1][0]; TFC_LineScanCameraData[0] = &LineScanImage0Buffer[0][0]; TFC_LineScanCameraData[1] = &LineScanImage1Buffer[0][0]; } else { LineScanWorkingBuffer = 0; LineScanImage0WorkingBuffer = &LineScanImage0Buffer[0][0]; LineScanImage1WorkingBuffer = &LineScanImage1Buffer[0][0]; TFC_LineScanCameraData[0] = &LineScanImage0Buffer[1][0]; TFC_LineScanCameraData[1] = &LineScanImage1Buffer[1][0]; } TFC_LineScanDataReady++; } break; } } void TFC_InitLineScanCamera() { SIM->SCGC5 |= SIM_SCGC5_PORTE_MASK | SIM_SCGC5_PORTD_MASK; //Make sure the clock is enabled for PORTE; PORTE->PCR[1] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; //Enable GPIO on on the pin for the CLOCK Signal PORTD->PCR[7] = PORT_PCR_MUX(1) | PORT_PCR_DSE_MASK; //Enable GPIO on on the pin for SI signal PORTD->PCR[5] = PORT_PCR_MUX(0); //Make sure AO signal goes to an analog input PORTD->PCR[6] = PORT_PCR_MUX(0); //Make sure AO signal goes to an analog input //Make sure the Clock and SI pins are outputs PTD->PDDR |= (1<<7); PTE->PDDR |= (1<<1); TAOS_CLK_LOW; TAOS_SI_LOW; LineScanWorkingBuffer = 0; LineScanImage0WorkingBuffer = &LineScanImage0Buffer[LineScanWorkingBuffer][0]; LineScanImage1WorkingBuffer = &LineScanImage1Buffer[LineScanWorkingBuffer][0]; TFC_LineScanCameraData[0] = &LineScanImage0Buffer[1][0]; TFC_LineScanCameraData[1] = &LineScanImage1Buffer[1][0]; } /** Initialized TPM0 to be used for generating PWM signals for the the dual drive motors. This method is called in the TFC constructor with a default value of 4000.0Hz * * @param SwitchingFrequency PWM Switching Frequency in floating point format. Pick something between 1000 and 9000. Maybe you can modulate it and make a tune. */ void TFC_InitMotorPWM(float SwitchingFrequency) { //Clock Setup for the TPM requires a couple steps. //1st, set the clock mux //See Page 124 of f the KL25 Sub-Family Reference Manual, Rev. 3, September 2012 // SIM->SOPT2 |= SIM_SOPT2_PLLFLLSEL_MASK;// We Want MCGPLLCLK/2 (See Page 196 of the KL25 Sub-Family Reference Manual, Rev. 3, September 2012) // SIM->SOPT2 &= ~(SIM_SOPT2_TPMSRC_MASK); // SIM->SOPT2 |= SIM_SOPT2_TPMSRC(1); //We want the MCGPLLCLK/2 (See Page 196 of the KL25 Sub-Family Reference Manual, Rev. 3, September 2012) //Enable the Clock to the FTM0 Module //See Page 207 of f the KL25 Sub-Family Reference Manual, Rev. 3, September 2012 SIM->SCGC6 |= SIM_SCGC6_TPM0_MASK; //The TPM Module has Clock. Now set up the peripheral //Blow away the control registers to ensure that the counter is not running TPM0->SC = 0; TPM0->CONF = 0; //While the counter is disabled we can setup the prescaler TPM0->SC = TPM_SC_PS(FTM0_CLK_PRESCALE); //Setup the mod register to get the correct PWM Period TPM0->MOD = (uint32_t)((float)(FTM0_CLOCK/(1<<FTM0_CLK_PRESCALE))/SwitchingFrequency); //Setup Channels 0,1,2,3 TPM0->CONTROLS[0].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSB_MASK; TPM0->CONTROLS[1].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSA_MASK; // invert the second PWM signal for a complimentary output; TPM0->CONTROLS[2].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSB_MASK; TPM0->CONTROLS[3].CnSC = TPM_CnSC_MSB_MASK | TPM_CnSC_ELSA_MASK; // invert the second PWM signal for a complimentary output; //Enable the Counter //Set the Default duty cycle to 50% duty cycle TFC_SetMotorPWM(0.0,0.0); //Enable the TPM COunter TPM0->SC |= TPM_SC_CMOD(1); //Enable the FTM functions on the the port PORTC->PCR[1] = PORT_PCR_MUX(4); PORTC->PCR[2] = PORT_PCR_MUX(4); PORTC->PCR[3] = PORT_PCR_MUX(4); PORTC->PCR[4] = PORT_PCR_MUX(4); } void TFC_SetMotorPWM(float MotorA , float MotorB) { if(MotorA>1.0) MotorA = 1.0; else if(MotorA<-1.0) MotorA = -1.0; if(MotorB>1.0) MotorB = 1.0; else if(MotorB<-1.0) MotorB = -1.0; TPM0->CONTROLS[2].CnV = (uint16_t) ((float)TPM0->MOD * (float)((MotorA + 1.0)/2.0)); TPM0->CONTROLS[3].CnV = TPM0->CONTROLS[2].CnV; TPM0->CONTROLS[0].CnV = (uint16_t) ((float)TPM0->MOD * (float)((MotorB + 1.0)/2.0)); TPM0->CONTROLS[1].CnV = TPM0->CONTROLS[0].CnV; } //Pot Reading is Scaled to return a value of -1.0 to 1.0 float TFC_ReadPot(uint8_t Channel) { if(Channel == 0) return ((float)PotADC_Value[0]/-127.5)+1.0; else return ((float)PotADC_Value[1]/-127.5)+1.0;; } float TFC_ReadBatteryVoltage() { return (((float)BatSenseADC_Value/(float)(ADC_MAX_CODE)) * 3.0);// * ((47000.0+10000.0)/10000.0); } extern volatile uint8_t TFC_LineScanCameraDataReady; Serial pc2(USBTX,USBRX); float init2() { pc2.baud(38400); return 0; } float getLine() { // if (TFC_LineScanCameraDataReady != 0) // return -1; static int count = 0; // count++; int channel = TFC_PUSH_BUTTON_0_PRESSED ? 1 : 0; int flip = TFC_PUSH_BUTTON_1_PRESSED ? 1 : 0; // uint8_t* parray = TFC_LineScanCameraData(array); for (int i=0; i<128; i++) { uint8_t n = TFC_LineScanCameraData[0][i]; if (n==2) pc2.printf(" ") ; else pc2.printf("%d",n) ; } pc2.printf("\r\n"); for (int i=0; i<128; i++) { uint8_t n = TFC_LineScanCameraData[0][i]; if (n==2) pc2.printf(" ") ; else pc2.printf("%d",n) ; } pc2.printf("\r\n"); return 0; }