#include "mt6701.h" #include "config.h" #include "soft_i2c.h" #include "stdio.h" #include "ti_msp_dl_config.h" #include "uart_redircet.h" volatile int16_t angle; volatile float angle_f; volatile float angle_f_rad; volatile bool gIsI2cError = false; #define DEBUG_I2C false /* Data sent to the Target */ uint8_t gTxPacket[I2C_TX_PACKET_SIZE] = {0x03}; /* Data received from Target */ volatile uint8_t gRxPacket[I2C_RX_PACKET_SIZE] = {0}; /* I2C clock configuration */ DL_I2C_ClockConfig gI2CclockConfig; /* Frequency of selected I2C clock*/ volatile uint32_t gClockSelFreq; /* Cycles to delay after controller transfer initiated */ volatile uint32_t gDelayCycles; /* I2C Target address */ #define I2C_TARGET_ADDRESS (0x06 << 1) void MT6701_iic_read_angel(void) { I2C_Start(); I2C_SendByte(I2C_TARGET_ADDRESS); I2C_RecviveAck(); I2C_SendByte(0X03); I2C_RecviveAck(); I2C_Start(); I2C_SendByte(I2C_TARGET_ADDRESS | 0x01); I2C_RecviveAck(); gRxPacket[0] = I2C_RecviveData(); I2C_SendAck(1); I2C_Start(); I2C_SendByte(I2C_TARGET_ADDRESS | 0x01); I2C_RecviveAck(); gRxPacket[1] = I2C_RecviveData(); I2C_SendAck(1); I2C_Stop(); } // void MT6701_iic_read_angel(void) { // /* Get I2C clock source and clock divider to use for delay cycle // calculation */ // DL_I2C_getClockConfig(I2C_1_INST, &gI2CclockConfig); // switch (gI2CclockConfig.clockSel) { // case DL_I2C_CLOCK_BUSCLK: // gClockSelFreq = 32000000; // break; // case DL_I2C_CLOCK_MFCLK: // gClockSelFreq = 4000000; // break; // default: // break; // } // /* // * Calculate number of clock cycles to delay after controller transfer // initiated // * gDelayCycles = 3 I2C functional clock cycles // * gDelayCycles = 3 * I2C clock divider * (CPU clock freq / I2C clock // freq) // */ // gDelayCycles = // (5 * (gI2CclockConfig.divideRatio + 1)) * (CPUCLK_FREQ / // gClockSelFreq); // if (DEBUG_ENABLED & DEBUG_MT_ENABLED & DEBUG_I2C) { // printf("i2c before writing -------\n"); // } // /* // * Fill FIFO with data. This example will send a MAX of 8 bytes since it // * doesn't handle the case where FIFO is full // */ // DL_I2C_fillControllerTXFIFO(I2C_1_INST, &gTxPacket[0], I2C_TX_PACKET_SIZE); // /* Wait for I2C to be Idle */ // while ( // !(DL_I2C_getControllerStatus(I2C_1_INST) & // DL_I2C_CONTROLLER_STATUS_IDLE)) // ; // /* Send the packet to the controller. // * This function will send Start + Stop automatically. // */ // DL_I2C_startControllerTransfer(I2C_1_INST, I2C_TARGET_ADDRESS, // DL_I2C_CONTROLLER_DIRECTION_TX, // I2C_TX_PACKET_SIZE); // if (DEBUG_ENABLED & DEBUG_MT_ENABLED & DEBUG_I2C) { // printf("i2c writing done -------\n"); // } // /* Workaround for errata I2C_ERR_13 */ // delay_cycles(gDelayCycles); // /* Poll until the Controller writes all bytes */ // while (DL_I2C_getControllerStatus(I2C_1_INST) & // DL_I2C_CONTROLLER_STATUS_BUSY) // ; // /* Trap if there was an error */ // if (DL_I2C_getControllerStatus(I2C_1_INST) & // DL_I2C_CONTROLLER_STATUS_ERROR) { // gIsI2cError = true; // if (DEBUG_ENABLED & DEBUG_MT_ENABLED & DEBUG_I2C) { // printf("i2c error ------------------------------------------\n"); // } // /* LED will remain high if there is an error */ // __BKPT(0); // return; // } // /* Wait for I2C to be Idle */ // while ( // !(DL_I2C_getControllerStatus(I2C_1_INST) & // DL_I2C_CONTROLLER_STATUS_IDLE)) // ; // /* Add delay between transfers */ // delay_cycles(1000); // if (DEBUG_ENABLED & DEBUG_MT_ENABLED & DEBUG_I2C) { // printf("i2c before reading -------\n"); // } // /* Send a read request to Target */ // DL_I2C_startControllerTransfer(I2C_1_INST, I2C_TARGET_ADDRESS, // DL_I2C_CONTROLLER_DIRECTION_RX, // I2C_RX_PACKET_SIZE); // /* // * Receive all bytes from target. LED will remain high if not all bytes // * are received // */ // for (uint8_t i = 0; i < I2C_RX_PACKET_SIZE; i++) { // while (DL_I2C_isControllerRXFIFOEmpty(I2C_1_INST)) // ; // gRxPacket[i] = DL_I2C_receiveControllerData(I2C_1_INST); // } // if (DEBUG_ENABLED & DEBUG_MT_ENABLED & DEBUG_I2C) { // printf("i2c reading done -------\n"); // } // } volatile float Last_ts = 0.0; volatile float last_angle = 0.0; // 单圈值 float GetAngle_NoTrack(void) { MT6701_iic_read_angel(); angle = ((int16_t)gRxPacket[0] << 6) | (gRxPacket[1] >> 2); angle_f_rad = (float)angle * _2PI / 16384; if (DEBUG_ENABLED & DEBUG_MT_ENABLED) { printf("angle_rad read back is %f \n", angle_f_rad); } return angle_f_rad; } volatile float full_rotations = 0.0; volatile float Last_Angle_rad = 0.0; // 多圈值 float GetAngle(void) { volatile float D_Angle_rad = 0.0; volatile float Angle_rad = GetAngle_NoTrack(); D_Angle_rad = Angle_rad - Last_Angle_rad; if (fabs(D_Angle_rad) > (0.8f * 2 * PI)) { full_rotations = full_rotations + ((D_Angle_rad > 0) ? -1 : 1); } Last_Angle_rad = Angle_rad; return (full_rotations * 2 * PI + Last_Angle_rad); } volatile float Last_Vel_ts = 0.0; volatile float Vel_Last_Angle = 0.0; float GetVelocity(void) { volatile float dt = 0.0; volatile float Vel_ts = SysTick->VAL; if (Vel_ts < Last_Vel_ts) { dt = (Last_Vel_ts - Vel_ts) / 80 * 1e-6f; } else { dt = (0xFFFFFF - Vel_ts + Last_Vel_ts) / 80 * 1e-6f; } if (dt < 0.0001) { dt = 10000; } float Vel_Angle = GetAngle(); float dv = Vel_Angle - Vel_Last_Angle; float velocity = (Vel_Angle - Vel_Last_Angle) / dt; Last_Vel_ts = Vel_ts; Vel_Last_Angle = Vel_Angle; return velocity; } void MT6701_get_angle_degree(void) { MT6701_iic_read_angel(); angle = ((int16_t)gRxPacket[0] << 6) | (gRxPacket[1] >> 2); angle_f = (float)angle * 360 / 16384; }