📄 fet110_ta_uart9600_04.c
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//******************************************************************************
// MSP-FET430x110 Demo - Timer_A UART Ultra-low Power 9600 Echo, No XTAL ROSC
//
// Description: This program demonstrates a half-duplex 9600-baud UART using
// Timer_A3 using no XTAL and an external resistor for DCO ROSC. DCO used for
// TACLK UART baud generation. The program will wait in LPM4, echoing back
// a received character using 8N1 protocol. On valid RX character, the
// character is echoed back.
// Using a 100k resistor on ROSC, with default DCO setting, set DCOCLK ~ 2MHz.
// ACLK = n/a, MCLK = SMCLK ~ 2MHz DCOCLK
// //*Use of external resistor reduces temperature sensitivity of DCOCLK*//
//
// MSP430F1121
// -----------------
// /|\ /|\| XIN|-
// | | | |
// 100k --|RST XOUT|-
// | | |
// +-------|P2.5/ROSC |
// | CCI0A/TXD/P1.1|-------->
// | | 9600 8N1
// | CCI0B/RXD/P2.2|<--------
//
#define RXD 0x04 // RXD on P2.2
#define TXD 0x02 // TXD on P1.1
// Conditions for 9600 Baud SW UART, DCO ~ 2MHz
#define Bitime_5 104 // ~ 0.5 bit length
#define Bitime 208 // ~ 9615 baud
unsigned int RXTXData;
unsigned char BitCnt;
void TX_Byte (void);
void RX_Ready (void);
// M.Buccini
// Texas Instruments, Inc
// January 2004
// Updated for IAR Embedded Workbench Version: 2.21B
//******************************************************************************
#include <msp430x11x1.h>
void main (void)
{
WDTCTL = WDTPW + WDTHOLD; // Stop watchdog timer
BCSCTL2 |= DCOR; // Rosc
_BIS_SR(OSCOFF); // XTAL not used
CCTL0 = OUT; // TXD Idle as Mark
TACTL = TASSEL_2 + MC_2; // SMCLK, continuous mode
P1SEL = TXD; // P1.1/TA0 for TXD function
P1DIR = TXD; // TXD output on P1
P2SEL = RXD; // P2.2/TA0 as RXD input
// Mainloop
for (;;)
{
RX_Ready(); // UART ready to RX one Byte
_BIS_SR(LPM4_bits + GIE); // Enter LPM0 w/ interr until char RXed
TX_Byte(); // TX Back RXed Byte Received
}
}
// Function Transmits Character from RXTXData Buffer
void TX_Byte (void)
{
BitCnt = 0xA; // Load Bit counter, 8data + ST/SP
CCR0 = TAR; // Current state of TA counter
CCR0 += Bitime; // Some time till first bit
RXTXData |= 0x100; // Add mark stop bit to RXTXData
RXTXData = RXTXData << 1; // Add space start bit
CCTL0 = OUTMOD0 + CCIE; // TXD = mark = idle
while ( CCTL0 & CCIE ); // Wait for TX completion
}
// Function Readies UART to Receive Character into RXTXData Buffer
// Sync capture not possible as DCO=TACLK=SMCLK can be off !!
void RX_Ready (void)
{
BitCnt = 0x8; // Load Bit counter
CCTL0 = CM1 + CCIS0 + OUTMOD0 + CAP + CCIE; // Neg Edge, Cap
}
// Timer A0 interrupt service routine
#pragma vector=TIMERA0_VECTOR
__interrupt void Timer_A0 (void)
{
CCR0 += Bitime; // Add Offset to CCR0
// RX
if (CCTL0 & CCIS0) // RX on CCI0B?
{
if( CCTL0 & CAP ) // Capture mode = start bit edge
{
CCTL0 &= ~ CAP; // Switch from capture to compare mode
CCR0 += Bitime_5;
_BIC_SR_IRQ(SCG1 + SCG0); // DCO reamins on after reti
}
else
{
RXTXData = RXTXData >> 1;
if (CCTL0 & SCCI) // Get bit waiting in receive latch
RXTXData |= 0x80;
BitCnt --; // All bits RXed?
if ( BitCnt == 0)
//>>>>>>>>>> Decode of Received Byte Here <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
{
CCTL0 &= ~ CCIE; // All bits RXed, disable interrupt
_BIC_SR_IRQ(CPUOFF); // Active mode on reti 0(SR)
}
//>>>>>>>>>> Decode of Received Byte Here <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
}
}
// TX
else
{
if ( BitCnt == 0)
CCTL0 &= ~ CCIE; // All bits TXed, disable interrupt
else
{
CCTL0 |= OUTMOD2; // TX Space
if (RXTXData & 0x01)
CCTL0 &= ~ OUTMOD2; // TX Mark
RXTXData = RXTXData >> 1;
BitCnt --;
}
}
}
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