ti提供的触摸板的程序

1万 · 2012-6-4 10:46

#include  "msp430g2231.h"
#define    LED1                BIT0
#define    LED2                BIT6
#define    LED_DIR             P1DIR
#define    LED_OUT             P1OUT

#define    BUTTON             BIT3
#define    BUTTON_OUT          P1OUT
#define    BUTTON_DIR          P1DIR
#define    BUTTON_IN          P1IN
#define    BUTTON_IE          P1IE
#define    BUTTON_IES          P1IES
#define    BUTTON_IFG          P1IFG
#define    BUTTON_REN          P1REN
#define    TXD                BIT1                   // TXD on P1.1
#define    RXD                BIT2                   // RXD on P1.2
#define    APP_STANDBY_MODE    0
#define    APP_APPLICATION_MODE  1
#define    TIMER_PWM_MODE       0
#define    TIMER_UART_MODE    1
#define    TIMER_PWM_PERIOD    2000
#define    TIMER_PWM_OFFSET    20
#define    TEMP_SAME          0
#define    TEMP_HOT             1
#define    TEMP_COLD          2
#define    TEMP_THRESHOLD       5
// Conditions for 9600/4=2400 Baud SW UART, SMCLK = 1MHz
#define    Bitime_5             0x05*4                   // ~ 0.5 bit length + small adjustment
#define    Bitime             13*4//0x0D

#define    UART_UPDATE_INTERVAL  1000

unsigned char BitCnt;

unsigned char applicationMode = APP_STANDBY_MODE;
unsigned char timerMode = TIMER_PWM_MODE;
unsigned char tempMode;
unsigned char calibrateUpdate = 0;
unsigned char tempPolarity = TEMP_SAME;
unsigned int TXByte;

/* Using an 8-value moving average filter on sampled ADC values */
long tempMeasured[8];
unsigned char tempMeasuredPosition=0;
long tempAverage;
long tempCalibrated, tempDifference;


void InitializeLeds(void);
void InitializeButton(void);
void PreApplicationMode(void);                   // Blinks LED, waits for button press
void ConfigureAdcTempSensor(void);
void ConfigureTimerPwm(void);
void ConfigureTimerUart(void);
void Transmit(void);
void InitializeClocks(void);

void main(void)
{
  unsigned int uartUpdateTimer = UART_UPDATE_INTERVAL;
  unsigned char i;
  WDTCTL = WDTPW + WDTHOLD;                // Stop WDT
  InitializeClocks();
  InitializeButton();
  InitializeLeds();
  PreApplicationMode();                   // Blinks LEDs, waits for button press

  /* Application Mode begins */
  applicationMode = APP_APPLICATION_MODE;
  ConfigureAdcTempSensor();
  ConfigureTimerPwm();

  __enable_interrupt();                   // Enable interrupts.

  /* Main Application Loop */
  while(1)
  {
ADC10CTL0 |= ENC + ADC10SC;          // Sampling and conversion start
__bis_SR_register(CPUOFF + GIE);       // LPM0 with interrupts enabled

/* Moving average filter out of 8 values to somewhat stabilize sampled ADC */
tempMeasured[tempMeasuredPosition++] = ADC10MEM;
if (tempMeasuredPosition == 8)
   tempMeasuredPosition = 0;
tempAverage = 0;
for (i = 0; i < 8; i++)
   tempAverage += tempMeasured[i];
tempAverage >>= 3;                   // Divide by 8 to get average

if ((--uartUpdateTimer == 0) || calibrateUpdate )
{
   ConfigureTimerUart();
   if (calibrateUpdate)
   {
      TXByte = 248;                      // A character with high value, outside of temp range
      Transmit();
      calibrateUpdate = 0;
   }
   TXByte = (unsigned char)( ((tempAverage - 630) * 761) / 1024 );

   Transmit();

   uartUpdateTimer = UART_UPDATE_INTERVAL;
   ConfigureTimerPwm();
}

tempDifference = tempAverage - tempCalibrated;
if (tempDifference < -TEMP_THRESHOLD)
{
   tempDifference = -tempDifference;
   tempPolarity = TEMP_COLD;
   LED_OUT &= ~ LED1;
}
else
if (tempDifference > TEMP_THRESHOLD)
{
   tempPolarity = TEMP_HOT;
   LED_OUT &= ~ LED2;
}
else
{
   tempPolarity = TEMP_SAME;
   TACCTL0 &= ~CCIE;
   TACCTL1 &= ~CCIE;
   LED_OUT &= ~(LED1 + LED2);
}

if (tempPolarity != TEMP_SAME)
{
   tempDifference <<= 3;
   tempDifference += TIMER_PWM_OFFSET;
   TACCR1 = ( (tempDifference) < (TIMER_PWM_PERIOD-1) ? (tempDifference) : (TIMER_PWM_PERIOD-1) );
   TACCTL0 |= CCIE;
   TACCTL1 |= CCIE;
}
  }
}
void PreApplicationMode(void)
{
  LED_DIR |= LED1 + LED2;
  LED_OUT |= LED1;                         // To enable the LED toggling effect
  LED_OUT &= ~LED2;

  BCSCTL1 |= DIVA_1;                      // ACLK/2
  BCSCTL3 |= LFXT1S_2;                   // ACLK = VLO

  TACCR0 = 1200;                            //
  TACTL = TASSEL_1 | MC_1;                // TACLK = SMCLK, Up mode.
  TACCTL1 = CCIE + OUTMOD_3;             // TACCTL1 Capture Compare
  TACCR1 = 600;
  __bis_SR_register(LPM3_bits + GIE);       // LPM0 with interrupts enabled
}
void ConfigureAdcTempSensor(void)
{
  unsigned char i;
  /* Configure ADC Temp Sensor Channel */
  ADC10CTL1 = INCH_10 + ADC10DIV_3;       // Temp Sensor ADC10CLK/4
  ADC10CTL0 = SREF_1 + ADC10SHT_3 + REFON + ADC10ON + ADC10IE;
  __delay_cycles(1000);                   // Wait for ADC Ref to settle
  ADC10CTL0 |= ENC + ADC10SC;             // Sampling and conversion start
  __bis_SR_register(CPUOFF + GIE);       // LPM0 with interrupts enabled
  tempCalibrated = ADC10MEM;
  for (i=0; i < 8; i++)
tempMeasured[i] = tempCalibrated;
  tempAverage = tempCalibrated;
}

void ConfigureTimerPwm(void)
{
  timerMode = TIMER_PWM_MODE;

  TACCR0 = TIMER_PWM_PERIOD;                            //
  TACTL = TASSEL_2 | MC_1;                // TACLK = SMCLK, Up mode.
  TACCTL0 = CCIE;
  TACCTL1 = CCIE + OUTMOD_3;             // TACCTL1 Capture Compare
  TACCR1 = 1;
}
void ConfigureTimerUart(void)
{
  timerMode = TIMER_UART_MODE;             // Configure TimerA0 UART TX

  CCTL0 = OUT;                            // TXD Idle as Mark
  TACTL = TASSEL_2 + MC_2 + ID_3;          // SMCLK/8, continuous mode
  P1SEL |= TXD + RXD;                      //
  P1DIR |= TXD;                            //
}
// Function Transmits Character from TXByte
void Transmit()
{
  BitCnt = 0xA;                            // Load Bit counter, 8data + ST/SP
  while (CCR0 != TAR)                      // Prevent async capture
CCR0 = TAR;                            // Current state of TA counter
  CCR0 += Bitime;                         // Some time till first bit
  TXByte |= 0x100;                         // Add mark stop bit to TXByte
  TXByte = TXByte << 1;                   // Add space start bit
  CCTL0 =  CCIS0 + OUTMOD0 + CCIE;       // TXD = mark = idle
  while ( CCTL0 & CCIE );                // Wait for TX completion
}

// Timer A0 interrupt service routine
#pragma vector=TIMERA0_VECTOR
__interrupt void Timer_A (void)
{
  if (timerMode == TIMER_UART_MODE)
  {
CCR0 += Bitime;                      // Add Offset to CCR0
if (CCTL0 & CCIS0)                   // TX on CCI0B?
{
   if ( BitCnt == 0)
   {
      P1SEL &= ~(TXD+RXD);
      CCTL0 &= ~ CCIE ;                // All bits TXed, disable interrupt
   }

   else
   {
      CCTL0 |=  OUTMOD2;                // TX Space
      if (TXByte & 0x01)
      CCTL0 &= ~ OUTMOD2;                // TX Mark
      TXByte = TXByte >> 1;
      BitCnt --;
   }
}
  }
  else
  {
if (tempPolarity == TEMP_HOT)
   LED_OUT |= LED1;
if (tempPolarity == TEMP_COLD)
   LED_OUT |= LED2;
TACCTL0 &= ~CCIFG;
  }
}
#pragma vector=TIMERA1_VECTOR
__interrupt void ta1_isr(void)
{
  TACCTL1 &= ~CCIFG;
  if (applicationMode == APP_APPLICATION_MODE)
LED_OUT &= ~(LED1 + LED2);
  else
LED_OUT ^= (LED1 + LED2);

}
void InitializeClocks(void)
{
  BCSCTL1 = CALBC1_1MHZ;                   // Set range
  DCOCTL = CALDCO_1MHZ;
  BCSCTL2 &= ~(DIVS_3);                   // SMCLK = DCO = 1MHz
}
void InitializeButton(void)                // Configure Push Button
{
  BUTTON_DIR &= ~BUTTON;
  BUTTON_OUT |= BUTTON;
  BUTTON_REN |= BUTTON;
  BUTTON_IES |= BUTTON;
  BUTTON_IFG &= ~BUTTON;
  BUTTON_IE |= BUTTON;
}

void InitializeLeds(void)
{
  LED_DIR |= LED1 + LED2;
  LED_OUT &= ~(LED1 + LED2);
}
/* *************************************************************
* Port Interrupt for Button Press
* 1. During standby mode: to exit and enter application mode
* 2. During application mode: to recalibrate temp sensor
* *********************************************************** */
#pragma vector=PORT1_VECTOR
__interrupt void PORT1_ISR(void)
{
  BUTTON_IFG = 0;
  BUTTON_IE &= ~BUTTON;          /* Debounce */
  WDTCTL = WDT_ADLY_250;
  IFG1 &= ~WDTIFG;                /* clear interrupt flag */
  IE1 |= WDTIE;

  if (applicationMode == APP_APPLICATION_MODE)
  {
tempCalibrated = tempAverage;
calibrateUpdate  = 1;
  }
  else
  {
applicationMode = APP_APPLICATION_MODE; // Switch from STANDBY to APPLICATION MODE
__bic_SR_register_on_exit(LPM3_bits);
  }
}
#pragma vector=WDT_VECTOR
__interrupt void WDT_ISR(void)
{
IE1 &= ~WDTIE;                /* disable interrupt */
IFG1 &= ~WDTIFG;                /* clear interrupt flag */
WDTCTL = WDTPW + WDTHOLD;       /* put WDT back in hold state */
BUTTON_IE |= BUTTON;          /* Debouncing complete */
}
// ADC10 interrupt service routine
#pragma vector=ADC10_VECTOR
__interrupt void ADC10_ISR (void)
{
  __bic_SR_register_on_exit(CPUOFF);       // Return to active mode
}

ti提供的触摸板的程序

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