I2C hang recover function added
Dependencies: UniGraphic mbed vt100
In this version, check_i2c_pins function was added in edge_mgr.cpp.
プログラムの起動時、I2Cモジュールを初期化する前に、I2Cに使用するピンの電位を確認し
もし一方でも Low に張り付いていた場合、SCL を GPIO 出力に設定して
所定回数 (I2C_UNLOCK_TRIAL_CYCLE) 反転させることにより、疑似リセットクロックを生成します。
その後は、通常の起動手順に復帰し、以降はこれまでと同様の動作をします。
sensors/MMA8451Q.cpp
- Committer:
- gaku_miyagawa
- Date:
- 2018-06-18
- Revision:
- 2:de22987be9ba
- Parent:
- 0:d895cd1cd897
File content as of revision 2:de22987be9ba:
/** * MMA8451Q 3-Axis, 14-bit/8-bit Digital Accelerometer */ #include "mbed.h" #include "MMA8451Q.h" #include "af_mgr.h" #define REG_STATUS 0x00 // when F_MODE = 00 #define REG_FIFO_STATUS 0x00 // when F_MODE > 0 #define REG_XYZ_FIFO 0x01 // Root pointer to XYZ FIFO data #define REG_OUT_X_MSB 0x01 // 8 MSBs of 14-bit sample #define REG_OUT_X_LSB 0x02 // 6 LSBs of 14-bit sample #define REG_OUT_Y_MSB 0x03 #define REG_OUT_Y_LSB 0x04 #define REG_OUT_Z_MSB 0x05 #define REG_OUT_Z_LSB 0x06 #define REG_F_SETUP 0x09 // FIFO setup #define REG_TRIG_CFG 0x0A // Map of FIFO daa capture events #define REG_SYSMOD 0x0B // Current System Mode #define REG_INT_SOURCE 0x0C // Interrupt status #define REG_WHO_AM_I 0x0D // Device ID (0x1A) #define REG_XYZ_DATA_CFG 0x0E // Dynamic Range Settings #define REG_HP_FILTER_CUTOFF 0x0F // Cutoff freq is set to 16Hz@800Hz #define REG_PL_STATUS 0x10 // Landscape/Portrait orientation status #define REG_PL_CFG 0x11 // Landscape/Portrait configuration #define REG_PL_COUNT 0x12 // Landscape/Portrait debounce counter #define REG_PL_BF_ZCOMP 0x13 // Back/Front, Z-Lock Trip threshold #define REG_P_L_THS_REG 0x14 // Portrait to Landscape Trip Angle is 29 degree #define REG_FF_MT_CFG 0x15 // Freefall/Motion function block configuration #define REG_FF_MT_SRC 0x16 // Freefall/Motion event source register #define REG_FF_MT_THS 0x17 // Freefall/Motion threshold register #define REG_FF_MT_COUNT 0x18 // Freefall/Motion debounce counter // TRANSIENT #define REG_TRANSIENT_CFG 0x1D // Transient functional block configuration #define REG_TRANSIENT_SRC 0x1E // Transient event status register #define REG_TRANSIENT_THS 0x1F // Transient event threshold #define REG_TRANSIENT_COUNT 0x20 // Transient debounce counter // PULSE #define REG_PULSE_CFG 0x21 // ELE, Double_XYZ or Single_XYZ #define REG_PULSE_SRC 0x22 // EA, Double_XYZ or Single_XYZ #define REG_PULSE_THSX 0x23 // X pulse threshold #define REG_PULSE_THSY 0x24 // Y pulse threshold #define REG_PULSE_THSZ 0x25 // Z pulse threshold #define REG_PULSE_TMLT 0x26 // Time limit for pulse #define REG_PULSE_LTCY 0x27 // Latency time for 2nd pulse #define REG_PULSE_WIND 0x28 // Window time for 2nd pulse #define REG_ASLP_COUNT 0x29 // Counter setting for Auto-SLEEP // Control Registers #define REG_CTRL_REG1 0x2A // ODR = 800Hz, STANDBY Mode #define REG_CTRL_REG2 0x2B // Sleep Enable, OS Modes, RST, ST #define REG_CTRL_REG3 0x2C // Wake from Sleep, IPOL, PP_OD #define REG_CTRL_REG4 0x2D // Interrupt enable register #define REG_CTRL_REG5 0x2E // Interrupt pin (INT1/INT2) map // User Offset #define REG_OFF_X 0x2F // X-axis offset adjust #define REG_OFF_Y 0x30 // Y-axis offset adjust #define REG_OFF_Z 0x31 // Z-axis offset adjust // Value definitions #define BIT_TRIG_TRANS 0x20 // Transient interrupt trigger bit #define BIT_TRIG_LNDPRT 0x10 // Landscape/Portrati Orientation #define BIT_TRIG_PULSE 0x08 // Pulse interrupt trigger bit #define BIT_TRIG_FF_MT 0x04 // Freefall/Motion trigger bit MMA8451Q::MMA8451Q(I2C *i2c, int addr) : m_addr(addr<<1) { // activate the peripheral p_i2c = i2c ; uint8_t data[2] = {REG_CTRL_REG1, 0x01}; writeRegs(data, 2); } MMA8451Q::~MMA8451Q() { } int MMA8451Q::readRegs(int addr, uint8_t * data, int len) { char t[1] = {addr}; int result ; __disable_irq() ; // Disable Interrupts result = p_i2c->write(m_addr, t, 1, true); if (result == 0) { result = p_i2c->read(m_addr, (char *)data, len); } __enable_irq() ; // Enable Interrupts return( result ) ; } int MMA8451Q::writeRegs(uint8_t * data, int len) { int result ; __disable_irq() ; // Disable Interrupts result = p_i2c->write(m_addr, (char *)data, len); __enable_irq() ; // Enable Interrupts return( result ) ; } int MMA8451Q::getAllRawData(int16_t value[]) { int result ; uint8_t data[6] ; result = readRegs(REG_OUT_X_MSB, data, 6) ; if (result == 0) { value[0] = ((int16_t)((data[0] << 8) | data[1])) >> 2 ; value[1] = ((int16_t)((data[2] << 8) | data[3])) >> 2 ; value[2] = ((int16_t)((data[4] << 8) | data[5])) >> 2 ; } return( result ) ; } int MMA8451Q::getAllData(float fvalue[]) { int result ; uint8_t data[6] ; result = readRegs(REG_OUT_X_MSB, data, 6) ; if (result == 0) { fvalue[0] = (float)((int16_t)((data[0] << 8) | data[1])) / 16384.0 ; fvalue[1] = (float)((int16_t)((data[2] << 8) | data[3])) / 16384.0 ; fvalue[2] = (float)((int16_t)((data[4] << 8) | data[5])) / 16384.0 ; } return( result ) ; } int16_t MMA8451Q::getRawData(uint8_t addr) { int16_t value ; uint8_t data[2] ; readRegs(addr, data, 2) ; value = ((int16_t)((data[0] << 8) | data[1])) >> 2 ; return( value ) ; } int16_t MMA8451Q::getRawX(void) { int16_t value ; value = getRawData(REG_OUT_X_MSB) ; return( value ) ; } int16_t MMA8451Q::getRawY(void) { int16_t value ; value = getRawData(REG_OUT_Y_MSB) ; return( value ) ; } int16_t MMA8451Q::getRawZ(void) { int16_t value ; value = getRawData(REG_OUT_Z_MSB) ; return( value ) ; } float MMA8451Q::getAccX(void) { return(((float)getRawX())/4096.0) ; } float MMA8451Q::getAccY(void) { return(((float)getRawY())/4096.0) ; } float MMA8451Q::getAccZ(void) { return(((float)getRawZ())/4096.0) ; }