void Accelerometer::readMemoryBlock(uint8_t *data, uint16_t dataSize, uint8_t bank, uint8_t address) { setMemoryBank(bank); i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &address); // Set memory start address uint8_t chunkSize; for (uint16_t i = 0; i < dataSize;) { chunkSize = MPU6050_DMP_MEMORY_CHUNK_SIZE; if (i + chunkSize > dataSize) chunkSize = dataSize - i; if (chunkSize > 256 - address) chunkSize = 256 - address; i2cReadBytes(MPU6050_RA_MEM_R_W, chunkSize, data + i); i += chunkSize; address += chunkSize; if (i < dataSize) { if (address == 0) bank++; setMemoryBank(bank); i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &address); // Set Memory start address } } }
bool Accelerometer::writeMemoryBlock(const uint8_t *data, uint16_t dataSize, uint8_t bank, uint8_t address, bool verify, bool useProgMem) { setMemoryBank(bank); i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &address); // Set Memory start address uint8_t chunkSize; uint8_t *verifyBuffer = NULL; uint8_t *progBuffer = NULL; uint16_t i; uint8_t j; if (verify) verifyBuffer = (uint8_t *)malloc(MPU6050_DMP_MEMORY_CHUNK_SIZE); if (useProgMem) progBuffer = (uint8_t *)malloc(MPU6050_DMP_MEMORY_CHUNK_SIZE); for (i = 0; i < dataSize;) { chunkSize = MPU6050_DMP_MEMORY_CHUNK_SIZE; if (i + chunkSize > dataSize) chunkSize = dataSize - i; if (chunkSize > 256 - address) chunkSize = 256 - address; if (useProgMem) for (j = 0; j < chunkSize; j++) progBuffer[j] = pgm_read_byte(data + i + j); else progBuffer = (uint8_t *)data + i; i2cWriteBytes(MPU6050_RA_MEM_R_W, chunkSize, progBuffer); if (verify && verifyBuffer) { setMemoryBank(bank); i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &address); // Set memory start address i2cReadBytes(MPU6050_RA_MEM_R_W, chunkSize, verifyBuffer); if (memcmp(progBuffer, verifyBuffer, chunkSize) != 0) { free(verifyBuffer); if (useProgMem) free(progBuffer); return false; } } i += chunkSize; address += chunkSize; if (i < dataSize) { if (address == 0) bank++; setMemoryBank(bank); i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &address); // Set memory start address } } if (verify) free(verifyBuffer); if (useProgMem) free(progBuffer); return true; }
void Accelerometer::setMemoryBank(uint8_t bank, bool prefetchEnabled, bool userBank) { bank &= 0x1F; if (userBank) bank |= 0x20; if (prefetchEnabled) bank |= 0x40; i2cWriteBytes(MPU6050_RA_BANK_SEL, 1, &bank); }
bool Accelerometer::writeDMPConfigurationSet(const uint8_t *data, uint16_t dataSize, bool useProgMem) { uint8_t *progBuffer = NULL, success, special; uint16_t i, j; if (useProgMem) progBuffer = (uint8_t *)malloc(8); uint8_t bank, offset, length; for (i = 0; i < dataSize;) { if (useProgMem) { bank = pgm_read_byte(data + i++); offset = pgm_read_byte(data + i++); length = pgm_read_byte(data + i++); } else { bank = data[i++]; offset = data[i++]; length = data[i++]; } if (length > 0) { if (useProgMem) { if (sizeof(progBuffer) < length) progBuffer = (uint8_t *)realloc(progBuffer, length); for (j = 0; j < length; j++) progBuffer[j] = pgm_read_byte(data + i + j); } else progBuffer = (uint8_t *)data + i; success = writeMemoryBlock(progBuffer, length, bank, offset, true); i += length; } else { if (useProgMem) special = pgm_read_byte(data + i++); else special = data[i++]; if (special == 0x01) { uint8_t value = 0x32; i2cWriteBytes(MPU6050_RA_INT_ENABLE, 1, &value); success = true; } else success = false; } if (!success) { if (useProgMem) free(progBuffer); return false; } } if (useProgMem) free(progBuffer); return true; }
int main(int argv,char *argc[]) { unsigned char byte; unsigned int word; unsigned char block[32]; initAI(); block[0] = 0x00; printf("%d\n",i2cWriteBytes(1,0x48,0x40,block,1)); //printf("0x%02x\n",getAI(AI_01)); return 0; }
Accelerometer::Accelerometer() { m_i2cfd = open("/dev/i2c-1", O_RDWR); if(!m_i2cfd < 0) abort(); if(ioctl(m_i2cfd, I2C_SLAVE, 0x68) < 0) abort(); i2cWriteBits(MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CLKSEL_BIT, MPU6050_PWR1_CLKSEL_LENGTH, MPU6050_CLOCK_PLL_XGYRO); // Set Clock source i2cWriteBits(MPU6050_RA_GYRO_CONFIG, MPU6050_GCONFIG_FS_SEL_BIT, MPU6050_GCONFIG_FS_SEL_LENGTH, MPU6050_GYRO_FS_250); // Full scale gyro range i2cWriteBits(MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_AFS_SEL_BIT, MPU6050_ACONFIG_AFS_SEL_LENGTH, MPU6050_ACCEL_FS_2); // Full scale accel range i2cWriteBits(MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_SLEEP_BIT, 1, false); // Disable sleep mode i2cWriteBits(MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_DEVICE_RESET_BIT, 1, true); // Reset usleep(30000); i2cWriteBits(MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_SLEEP_BIT, 1, false); // Disable sleep mode setMemoryBank(0x10, true, true); // Get MPU hardware revision uint8_t value = 0x06; // Alright, this is dirty but a pointer to this value will be sent to every i2cWriteBytes... uint16_t value16; // Yeah... I know, I won't go to heaven but that's ok i2cWriteBytes(MPU6050_RA_MEM_START_ADDR, 1, &value); // Set memory start address i2cReadBytes(MPU6050_RA_MEM_R_W, 1, buffer); // Get hardware revision uint8_t hwRevision __attribute__((__unused__)) = buffer[0]; setMemoryBank(0, false, false); i2cReadBits(MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OTP_BNK_VLD_BIT, 1, buffer); uint8_t otpValid __attribute__((__unused__)) = buffer[0]; // Check OTP bank validity i2cReadBits(MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer); int8_t xgOffset = buffer[0]; i2cReadBits(MPU6050_RA_YG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer); int8_t ygOffset = buffer[0]; i2cReadBits(MPU6050_RA_ZG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer); int8_t zgOffset = buffer[0]; value = 0x7F; // Setup weird slave stuff i2cWriteBytes(MPU6050_RA_I2C_SLV0_ADDR, 1, &value); i2cWriteBits(MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_MST_EN_BIT, 1, false); // Disable I2C Master Mode value = 0x68; i2cWriteBytes(MPU6050_RA_I2C_SLV0_ADDR, 1, &value); i2cWriteBits(MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_MST_RESET_BIT, 1, true); // Reset I2C Master usleep(20000); if (writeMemoryBlock(dmpMemory, MPU6050_DMP_CODE_SIZE, 0, 0, true, true)) { // Load DMP code into memory banks if (writeDMPConfigurationSet(dmpConfig, MPU6050_DMP_CONFIG_SIZE, true)) { // Let's write the DMP configuration i2cWriteBits(MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CLKSEL_BIT, MPU6050_PWR1_CLKSEL_LENGTH, MPU6050_CLOCK_PLL_ZGYRO); // Set clock source value = 0x12; i2cWriteBytes(MPU6050_RA_INT_ENABLE, 1, &value); // Enable 0x12 interuption value = 4; // 1khz / (1 + 4) = 200 Hz i2cWriteBytes(MPU6050_RA_SMPLRT_DIV, 1, &value); i2cWriteBits(MPU6050_RA_CONFIG, MPU6050_CFG_EXT_SYNC_SET_BIT, MPU6050_CFG_EXT_SYNC_SET_LENGTH, MPU6050_EXT_SYNC_TEMP_OUT_L); // External Frame Sync i2cWriteBits(MPU6050_RA_CONFIG, MPU6050_CFG_DLPF_CFG_BIT, MPU6050_CFG_DLPF_CFG_LENGTH, MPU6050_DLPF_BW_42); // DLPF Mode i2cWriteBits(MPU6050_RA_GYRO_CONFIG, MPU6050_GCONFIG_FS_SEL_BIT, MPU6050_GCONFIG_FS_SEL_LENGTH, MPU6050_GYRO_FS_2000); // Full scale gyro range value = 0x03; i2cWriteBytes(MPU6050_RA_DMP_CFG_1, 1, &value); value = 0x00; i2cWriteBytes(MPU6050_RA_DMP_CFG_2, 1, &value); // Setting X Y and Z gyro offsets to previous values i2cWriteBits(MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, xgOffset); i2cWriteBits(MPU6050_RA_YG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, ygOffset); i2cWriteBits(MPU6050_RA_ZG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, zgOffset); value16 = 0; // And gyro offsets users to 0 i2cWriteWords(MPU6050_RA_XG_OFFS_USRH, 1, &value16); i2cWriteWords(MPU6050_RA_YG_OFFS_USRH, 1, &value16); i2cWriteWords(MPU6050_RA_ZG_OFFS_USRH, 1, &value16); // Memory update 1/7 uint8_t dmpUpdate[16], j; uint16_t pos = 0; for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); //Memory update 2/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); resetFIFO(); uint8_t fifoCount = getFIFOCount(); uint8_t fifoBuffer[128]; value = 2; i2cWriteBytes(MPU6050_RA_MOT_THR, 1, &value); // Motion threshold value = 156; i2cWriteBytes(MPU6050_RA_ZRMOT_THR, 1, &value); // Zero Motion threshold value = 80; i2cWriteBytes(MPU6050_RA_MOT_DUR, 1, &value); // Motion duration value = 0; i2cWriteBytes(MPU6050_RA_ZRMOT_DUR, 1, &value); // Zero Motion duration resetFIFO(); setFIFOEnabled(true); setDMPEnabled(true); i2cWriteBits(MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_DMP_RESET_BIT, 1, true); // Reset DMP // Memory update 3/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); // Memory update 4/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); // Memory update 5/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); while ((fifoCount = getFIFOCount()) < 3); getFIFOBytes(fifoBuffer, fifoCount); uint8_t mpuIntStatus __attribute__((__unused__)) = getIntStatus(); // Memory update 6/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); readMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); while ((fifoCount = getFIFOCount()) < 3); getFIFOBytes(fifoBuffer, fifoCount); mpuIntStatus = getIntStatus(); // Memory update 7/7 for (j = 0; j < 4 || j < dmpUpdate[2] + 3; j++, pos++) dmpUpdate[j] = pgm_read_byte(&dmpUpdates[pos]); writeMemoryBlock(dmpUpdate + 3, dmpUpdate[2], dmpUpdate[0], dmpUpdate[1]); setDMPEnabled(false); dmpPacketSize = 42; resetFIFO(); getIntStatus(); } else abort(); } else abort(); i2cReadBits(MPU6050_RA_WHO_AM_I, MPU6050_WHO_AM_I_BIT, MPU6050_WHO_AM_I_LENGTH, buffer); if(buffer[0] != 0x34) abort(); setDMPEnabled(true); zeroValues[0] = 0; zeroValues[1] = 0; zeroValues[2] = 0; }