Joe Knapp
Moved pl_status to public
Fork of
lib_mma8451q
by 
wayne roberts
mma8451q.cpp
- Committer:
- jknapp_smtc
- Date:
- 2015-11-17
- Revision:
- 3:6d0d5c53d825
- Parent:
- 2:4bc96749141e
File content as of revision 3:6d0d5c53d825:
#include "mma8451q.h"
/* turn on: CTRL_REG1 active_bit = 1
* back to standby: CTRL_REG1 active_bit = 0
*/
/* STANDBY: SYSMOD = 00 */
/*
* MMA8451 I2C address
*/
#define MMA8451_I2C_ADDRESS 0x38 //0x1C
MMA8451Q::MMA8451Q(I2C& r, DigitalIn& int_pin) : m_i2c(r), m_int_pin(int_pin)
{
/* INT pins on this chip default to push-pull output */
write(MMA8451_CTRL_REG3, 0x01); // set PP_OD
/* INT1 and INT2 are tied together */
}
MMA8451Q::~MMA8451Q()
{
}
void MMA8451Q::read(uint8_t addr, uint8_t *dst_buf, int length)
{
char cmd[2];
cmd[0] = addr;
if (m_i2c.write(MMA8451_I2C_ADDRESS, cmd, 1, true))
printf("MMA write-fail %02x\n", addr);
if (m_i2c.read(MMA8451_I2C_ADDRESS, (char *)dst_buf, length))
printf("MMA read-fail\n");
}
uint8_t MMA8451Q::read_single(uint8_t addr)
{
char cmd[2];
cmd[0] = addr;
if (m_i2c.write(MMA8451_I2C_ADDRESS, cmd, 1, true))
printf("MMA write-fail %02x\n", addr);
if (m_i2c.read(MMA8451_I2C_ADDRESS, cmd, 1))
printf("MMA read-fail\n");
return cmd[0];
}
void MMA8451Q::print_regs()
{
printf("ID: %02x\n", read_single(MMA8451_ID));
printf("sysmod:%02x\n", read_single(MMA8451_SYSMOD));
ctrl_reg1.octet = read_single(MMA8451_CTRL_REG1);
printf("ctrl_reg1:%02x\n", ctrl_reg1.octet);
printf("ctrl_reg2:%02x\n", read_single(MMA8451_CTRL_REG2));
printf("ctrl_reg3:%02x\n", read_single(MMA8451_CTRL_REG3)); /* TODO: PP_OD is bit 0 (1=open drain) */
printf("(int en) ctrl_reg4:%02x\n", read_single(MMA8451_CTRL_REG4));
printf("(int cfg) ctrl_reg5:%02x\n", read_single(MMA8451_CTRL_REG5));
printf("status:%02x\n", read_single(MMA8451_STATUS));
/* (interrupt status) int src at 0x0c (MMA8451_INT_SOURCE): data ready, motion/freefall, pulse, orientation, transient, auto sleep */
printf("INT_SOURCE:%02x\n", read_single(MMA8451_INT_SOURCE));
}
void MMA8451Q::write(uint8_t addr, uint8_t data)
{
uint8_t cmd[2];
cmd[0] = addr;
cmd[1] = data;
if (m_i2c.write(MMA8451_I2C_ADDRESS, (char *)cmd, 2))
printf("MMA write-fail %02x\n", addr);
}
void MMA8451Q::set_active(char arg)
{
char cmd[2];
cmd[0] = MMA8451_CTRL_REG1;
cmd[1] = arg;
if (m_i2c.write(MMA8451_I2C_ADDRESS, cmd, 2))
printf("MMA write-fail %02x\n", cmd[0]);
}
bool MMA8451Q::get_active(void)
{
uint8_t ret = read_single(MMA8451_CTRL_REG1);
//printf("CTRL_REG1: %x\n", ret);
if (ret & 1)
return true;
else
return false;
}
void MMA8451Q::orient_detect()
{
uint8_t v;
ctrl_reg1.octet = read_single(MMA8451_CTRL_REG1);
/* AN4068 Sensors Freescale Semiconductor, Inc.
* 4.1 Example Steps for Implementing the Embedded Orientation Detection */
/* Step 1: Put the part into Standby Mode */
ctrl_reg1.bits.ACTIVE = 0;
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
/* Step 2: Set the data rate to 50 Hz (for example, but can choose any sample rate). */
ctrl_reg1.bits.DR = 4;
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
/* Step 3: Set the PL_EN bit in Register 0x11 PL_CFG. This will enable the orientation detection. */
v = read_single(MMA8451_PL_CFG);
v |= 0x40;
write(MMA8451_PL_CFG, v);
/* Step 4: Set the Back/Front Angle trip points in register 0x13 following the table in the data sheet. */
v = read_single(MMA8451_PL_BF_ZCOMP);
/*v &= 0x3f;
v |= 0xX0;
write(MMA8451_PL_BF_ZCOMP, v);*/
/* Step 5: Set the Z-Lockout angle trip point in register 0x13 following the table in the data sheet. */
/* v &= 0xf8;
v |= 0x0X;
*/
/* Step 6: Set the Trip Threshold Angle */
v = read_single(MMA8451_PL_THS_REG);
/*v &= 0x07;
v |= 0x0X << 3;
write(MMA8451_PL_THS_REG. v);*/
/* Step 7: Set the Hysteresis Angle */
v = read_single(MMA8451_PL_THS_REG);
/*v &= 0xf8;
v |= 0x0X;
write(MMA8451_PL_THS_REG. v);*/
/* Step 8: Register 0x2D, Control Register 4 configures all embedded features for interrupt */
ctrl_reg4.octet = 0;
ctrl_reg4.bits.INT_EN_LNDPRT = 1;
write(MMA8451_CTRL_REG4, ctrl_reg4.octet);
/* Step 9: Register 0x2E is Control Register 5 which gives the option of routing the interrupt to either INT1 or INT2 */
ctrl_reg5.octet = 0;
ctrl_reg5.bits.INT_CFG_LNDPRT = 1;
write(MMA8451_CTRL_REG5, ctrl_reg5.octet);
/* Step 10: Set the debounce counter in register 0x12 */
write(MMA8451_PL_COUNT, 5); // 5: debounce to 100ms at 50hz
/* Step 11: Put the device in Active Mode */
ctrl_reg1.octet = read_single(MMA8451_CTRL_REG1);
ctrl_reg1.bits.ACTIVE = 1;
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
/* Step 12: in service() function */
}
void MMA8451Q::transient_detect()
{
ctrl_reg1.octet = read_single(MMA8451_CTRL_REG1);
/* AN4071 Sensors Freescale Semiconductor, Inc.
* 7.1 Example Steps for Configuring Transient Detection
* Change in X or Y > 0.5g for 50 ms at 100 Hz ODR, Normal mode */
/* Step 1: Put the device in Standby Mode: Register 0x2A CTRL_REG1 */
ctrl_reg1.bits.ACTIVE = 0;
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
ctrl_reg1.bits.DR = 3; //Set device in 100 Hz ODR, Standby
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
/* Step 2: Enable X and Y Axes and enable the latch: Register 0x1D Configuration Register */
transient_cfg.octet = 0;
transient_cfg.bits.ELE = 1; // enable latch
transient_cfg.bits.YTEFE = 1; // enable Y
transient_cfg.bits.XTEFE = 1; // enable X
transient_cfg.bits.ZTEFE = 1; // enable Z
write(MMA8451_TRANSIENT_CFG, transient_cfg.octet);
/* Step 3: Set the Threshold: Register 0x1F
* Note: Step count is 0.063g per count, 0.5g / 0.063g = 7.93.
* Therefore set the threshold to 8 counts */
write(MMA8451_TRANSIENT_THS, 8);
/* Step 4: Set the Debounce Counter for 50 ms: Register 0x20
* Note: 100 Hz ODR, therefore 10 ms step sizes */
write(MMA8451_TRANSIENT_COUNT, 5);
/* Step 5: Enable Transient Detection Interrupt in the System (CTRL_REG4) */
ctrl_reg4.octet = 0;
ctrl_reg4.bits.INT_EN_TRANS = 1;
write(MMA8451_CTRL_REG4, ctrl_reg4.octet);
/* Step 6: Route the Transient Interrupt to INT 1 hardware pin (CTRL_REG5) */
ctrl_reg5.octet = 0;
ctrl_reg5.bits.INT_CFG_TRANS = 1;
write(MMA8451_CTRL_REG5, ctrl_reg5.octet);
/* Step 7: Put the device in Active Mode: Register 0x2A CTRL_REG1 */
ctrl_reg1.octet = read_single(MMA8451_CTRL_REG1);
ctrl_reg1.bits.ACTIVE = 1;
write(MMA8451_CTRL_REG1, ctrl_reg1.octet);
/* Step 8: Write Interrupt Service Routine Reading the
* System Interrupt Status and the Transient Status */
}
uint8_t MMA8451Q::service()
{
mma_int_source_t int_src;
if (m_int_pin)
return 0; // no interrupt
int_src.octet = read_single(MMA8451_INT_SOURCE);
if (int_src.bits.SRC_DRDY) {
read(MMA8451_OUT_X_MSB, out.octets, 6);
}
if (int_src.bits.SRC_FF_MT) {
read_single(MMA8451_FF_MT_SRC);
}
if (int_src.bits.SRC_PULSE) {
read_single(MMA8451_PULSE_SRC);
}
if (int_src.bits.SRC_LNDPRT) {
//mma_pl_status_t pl_status;
/*AN4068 Step 12: Write a Service Routine to Service the Interrupt */
pl_status.octet = read_single(MMA8451_PL_STATUS);
if (verbose) {
printf("PL_STATUS: ");
if (pl_status.bits.NEWLP) {
if (pl_status.bits.LO)
printf("Z-tilt-LO ");
if (pl_status.bits.LAPO == 0)
printf("up ");
else if (pl_status.bits.LAPO == 1)
printf("down ");
else if (pl_status.bits.LAPO == 2)
printf("left ");
else if (pl_status.bits.LAPO == 3)
printf("right ");
if (pl_status.bits.BAFRO)
printf("back ");
else
printf("front ");
}
printf("\r\n");
}
} // ...int_src.bits.SRC_LNDPRT
if (int_src.bits.SRC_TRANS) {
transient_src_t t_src;
t_src.octet = read_single(MMA8451_TRANSIENT_SRC);
if (verbose) {
printf("transient src:%x ", t_src.octet);
if (t_src.bits.XTRANSE)
printf("X_Pol:%d ", t_src.bits.X_Trans_Pol);
if (t_src.bits.YTRANSE)
printf("Y_Pol:%d ", t_src.bits.Y_Trans_Pol);
if (t_src.bits.ZTRANSE)
printf("Z_Pol:%d ", t_src.bits.Z_Trans_Pol);
printf("\r\n");
}
} // ...int_src.bits.SRC_TRANS
if (int_src.bits.SRC_ASLP) {
read_single(MMA8451_SYSMOD);
}
return int_src.octet;
}