Tarkoituksena liittää SCA3100 kiihtyvyysanturi EM430F6137RF900 kehitysalustaan SPI-väylää hyväksi käyttäen ja tehdä myös ohjelma anturin lukemista varten.
SCA3100-D04 kiihtyvyysanturi:
- mittausakseleita 3 (x,y ja z)
- mittausalue +-2g
- mittaustarkuus +-30mg
- lämpötilan mittausalue -40...+125 C
- SPI väylä
- Liitännät
- Datasheet
Ohjelma:
CCS4:lla tehdyllä ohjelmalla voidaan lukea SCA3100 anturin kaikki 3 akselia. Laiteiston puuttellisuuden vuoksi akselien arvojen tarkkailu ei tällä hetkellä onnistu realiaikaisesti, esim. tulostaminen suoraan sarjaväylälle. Akselien arvoja voidaan myös tarkkailla CCS4:n sisällä, mutta tällöinkin vain pysäyttämällä ohjelma (ohjeet ).
Koodi:
/*************************************************************************** * EM430F6137 Demo USCI_A0 SPI Interface to SCA3100 Accelerometer * * Uses TI EM430F6137 Development Tool * * Reads all 3 (x,y,z) axes */ #define XTAL 16000000L #define TICKSPERMS (XTAL / 1000 / 5 - 1) #define TICKSPERUS (TICKSPERMS / 1000) #define SPICLOCK 500 // SPI clock = 500kHz #define SPIFRAMEDELAY ((1000 / SPICLOCK) * 6) // SPI interframe delay [us] = 6 * Tsck #define SPICSBDELAY ((1000 / SPICLOCK) / 2) // SCK -> CSB delay [us] = 0.5 * Tsck // LIBRARIES #include "cc430x613x.h" #include "math.h" // PORT DEFINITIONS #define PORT_CSB_OUT P2OUT #define PORT_CSB_DIR P2DIR #define TX_BUFFER UCA0TXBUF #define RX_BUFFER UCA0RXBUF // PIN DEFINITIONS #define PIN_CSB BIT7 //AXIS REG #define X_LSB 0x04 #define X_MSB 0x05 #define Y_LSB 0x06 #define Y_MSB 0x07 #define Z_LSB 0x08 #define Z_MSB 0x09 // FUNCTION PROTOTYPES unsigned char ReadRegister(unsigned char Address); unsigned short realValues(unsigned short values); void wait_ms(unsigned short ms); void wait_us(unsigned short us); unsigned short x_msb; unsigned short x_lsb; short x_value; unsigned short y_msb; unsigned short y_lsb; short y_value; unsigned short z_msb; unsigned short z_lsb; short z_value; void main(void) { WDTCTL = WDTPW+WDTHOLD; // Stop watchdog timer PMAPPWD = 0x02D52; // Get write-access to port mapping regs P1MAP6 = PM_UCA0SIMO; // Map UCA0SIMO output to P1.6 P1MAP5 = PM_UCA0SOMI; // Map UCA0SOMI output to P1.5 P1MAP7 = PM_UCA0CLK; // Map UCA0CLK output to P1.7 PMAPPWD = 0; // Lock port mapping registers PORT_CSB_DIR |= PIN_CSB; PORT_CSB_OUT |= PIN_CSB; // Unselect gyro sensor P1DIR |= BIT5 + BIT6 + BIT7; // ACLK, MCLK, SMCLK set out to pins P1SEL |= BIT5 + BIT6 + BIT7; // P1.5,6,7 for debugging purposes. UCA0CTL1 |= UCSWRST; // **Put state machine in reset** UCA0CTL0 |= UCMST+UCSYNC+UCCKPH+UCMSB; // 3-pin, 8-bit SPI master // Clock polarity high, MSB UCA0CTL1 |= UCSSEL0; // SMCLK UCA0BR0 = 0x02; // /2 UCA0BR1 = 0; // UCA0MCTL = 0; // No modulation UCA0CTL1 &= ~UCSWRST; // **Initialize USCI state machine** UCA0IE |= UCRXIE; // Enable USCI_A0 RX interrupt while(1) { x_lsb = ReadRegister(X_LSB); x_msb = ReadRegister(X_MSB); x_value = (x_msb<<8) | x_lsb; x_value = realValues(x_value); y_lsb = ReadRegister(Y_LSB); y_msb = ReadRegister(Y_MSB); y_value = (y_msb<<8) | y_lsb; y_value=realValues(y_value); z_lsb = ReadRegister(Z_LSB); z_msb = ReadRegister(Z_MSB); z_value = (z_msb<<8) | z_lsb; z_value=realValues(z_value); wait_ms(10); } } // Read a byte from the gyro sensor unsigned char ReadRegister(unsigned char Address) { unsigned char Result; Address <<= 2; // Address to be shifted left by 2 and RW bit to be reset PORT_CSB_OUT &= ~PIN_CSB; // Select gyro sensor Result = RX_BUFFER; // Read RX buffer just to clear interrupt flag TX_BUFFER = Address; // Write address to TX buffer while (!(UCA0IFG&UCRXIFG)); // Wait until new data was written into RX buffer Result = RX_BUFFER; // Read RX buffer just to clear interrupt flag TX_BUFFER = 0; // Write dummy data to TX buffer while (!(UCA0IFG&UCRXIFG)); // Wait until new data was written into RX buffer Result = RX_BUFFER; // Read RX buffer wait_us(SPICSBDELAY); // Delay to satisfy 1/2 clk period delay from // falling edge of clk to CSB PORT_CSB_OUT |= PIN_CSB; // Deselect gyro sensor wait_us(SPIFRAMEDELAY); // Delay to satisfy 6x clk period for CS high state return Result; // Return new data from RX buffer } void wait_ms(unsigned short ms) { unsigned short a, b; for (a = ms; a > 0; a--) // outer loop takes 5 ck per round for (b = TICKSPERMS; b > 0; b--) // inner loop takes 5 ck per round asm(" nop"); } // wait us void wait_us(unsigned short us) { unsigned short a; us *= TICKSPERUS; for (a = us; a > 0; a--) // loop takes 5 ck per round asm(" nop"); } unsigned int shift(unsigned short thisData, int thisBit) { unsigned short data; data=thisData>>(thisBit-1); data=data&0x01; return data; } unsigned short realValues(unsigned short values) { short table[14]; int i; int bitti=3; unsigned short rdy; for(i=0;i<14;i++) { table[i]= shift(values,bitti); bitti++; } rdy=(10/9)*(-table[13]*pow(2,13)+table[12]*pow(2,12)+table[11]*pow(2,11)+table[10]*pow(2,10)+table[9]*pow(2,9)+table[8]*pow(2,8)+table[7]*pow(2,7)+table[6]*pow(2,6)+table[5]*pow(2,5)+table[4]*pow(2,4)+table[3]*pow(2,3)+table[2]*pow(2,2)+table[1]*2+table[0]); return rdy; }