Exemplo n.º 1
0
bool MPU6050::initialize() {
    setClockSource(MPU6050_CLOCK_PLL_XGYRO);
    setFullScaleGyroRange(MPU6050_GYRO_FS_250);
    setFullScaleAccelRange(MPU6050_ACCEL_FS_2);
    setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!
    return 1;
}
Exemplo n.º 2
0
void LSM330DLC::init(int acc_addr, int gyro_addr) {
  accAddr = acc_addr;
  gyroAddr = gyro_addr;
  
  setAccelDataRate(LSM330DLC_A_DATARATE_25HZ);
  setFullScaleAccelRange(LSM330DLC_A_FULLSCALE_PM2G);
  
  enableGyro();
  setFullScaleGyroRange(LSM330DLC_G_FULLSCALE_250DPS);
}
Exemplo n.º 3
0
void mpu_setup()
{
    devAddr = MPU6050_DEFAULT_ADDRESS;
    //switchSPIEnabled(true);
    DELAY_US(1*1000);
    setClockSource(MPU6050_CLOCK_PLL_XGYRO);
    setFullScaleGyroRange(MPU6050_GYRO_FS_250);
    setFullScaleAccelRange(MPU6050_ACCEL_FS_2);
    setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!
}
Exemplo n.º 4
0
void MPU6XXX32::init(SPI2C_config * con)
{
	i2cConfig = con;
	comP = SPI2C::setSPIC2C(i2cConfig);

	WR->setSPI2CConfig(i2cConfig);
	if (comP->currentConfg->spi2ctype == SPI2C_SPI_TRANSACTIONAL)
		spiMode = true;
	setClockSource(MPU6050_CLOCK_PLL_XGYRO);
	setFullScaleGyroRange(MPU6050_GYRO_FS_250);
	setFullScaleAccelRange(MPU6050_ACCEL_FS_2);
	setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!
}
Exemplo n.º 5
0
/** Power on and prepare for general usage.
 * This will activate the device and take it out of sleep mode (which must be done
 * after start-up). This function also sets both the accelerometer and the gyroscope
 * to their most sensitive settings, namely +/- 2g and +/- 250 degrees/sec, and sets
 * the clock source to use the X Gyro for reference, which is slightly better than
 * the default internal clock source.
 */
void MPU6050::initialize()
{

#ifdef useDebugSerial
    debugSerial.printf("MPU6050::initialize start\n\r");
#endif

    setClockSource(MPU6050_CLOCK_PLL_XGYRO);
    setFullScaleGyroRange(MPU6050_GYRO_FS_500);
    setFullScaleAccelRange(MPU6050_ACCEL_FS_16);
    setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!

#ifdef useDebugSerial
    debugSerial.printf("MPU6050::initialize end\n\r");
#endif
}
Exemplo n.º 6
0
void CurieIMUClass::setGyroRange(int range)
{
    BMI160GyroRange bmiRange;

    if (range >= 2000) {
        bmiRange = BMI160_GYRO_RANGE_2000;
    } else if (range >= 1000) {
        bmiRange = BMI160_GYRO_RANGE_1000;
    } else if (range >= 500) {
        bmiRange = BMI160_GYRO_RANGE_500;
    } else if (range >= 250) {
        bmiRange = BMI160_GYRO_RANGE_250;
    } else {
        bmiRange = BMI160_GYRO_RANGE_125;
    }

    setFullScaleGyroRange(bmiRange);
}
Exemplo n.º 7
0
/** Power on and prepare for general usage.
 * This will activate the device and take it out of sleep mode (which must be done
 * after start-up). This function also sets both the accelerometer and the gyroscope
 * to their most sensitive settings, namely +/- 2g and +/- 250 degrees/sec, and sets
 * the clock source to use the X Gyro for reference, which is slightly better than
 * the default internal clock source.
 */
PUBLIC void initializeLSM6DS0(bool useAccel, bool useGyro) {
	xAccelOffset = yAccelOffset = zAccelOffset = 0;
	xGyroOffset = yGyroOffset = zGyroOffset = 0;

	gyroEnabled = useGyro;
	accelEnabled = useAccel;

	if(gyroEnabled)
	{
		gScale = GYRO_FS_245DSP;
		calcGyroRes();
	}

	if(accelEnabled)
	{
		aScale = ACC_FS_2G;
		calcAccelRes();
	}

	if(testConnection())
	{
		resetLSM6DS0();

		if(accelEnabled)
		{
			initAccel();
			setFullScaleAccelRange(aScale);
			setAccelODR(ACC_ODR_119Hz);
		}

		if(gyroEnabled)
		{
			initGyro();
			setFullScaleGyroRange(gScale);
			setGyroODR(GYRO_ODR_119Hz_CO_14Hz);
		}

		calibrateLSM6DS0(gbias,abias);
	}
}
Exemplo n.º 8
0
/******************************** MPU6050 Functions ********************************/
void initializeIMU()
{

	//Init Interrupt Output Pin
	P1REN |= BIT4;
	P1OUT |= BIT4;
	P1IFG &= ~BIT4;                           // P1.4 IFG cleared
	P1IE |= BIT4;                             // P1.4 interrupt enabled

	P4SEL |= BIT1 + BIT2;					  // P4.1 & P4.2 SDA/SCL Select

	// Delays do not need to be this long. Delays are present to keep I2C line clear.
	// This functions can be altered by the user. Check MPU6050.h file by Jeff Rowberg to determine the sensitivty variables.
	setClockSource(MPU6050_CLOCK_PLL_XGYRO);	// Set MPU6050 clock
	msDelay(100);
	setFullScaleGyroRange(MPU6050_GYRO_FS_2000);	// Gyroscope sensitivity set to 2000 degrees/sec
	msDelay(100);
	setFullScaleAccelRange(MPU6050_ACCEL_FS_4);	// Accelerometer sensitivity set to 4g
	msDelay(100);
	setDLPFConfig(MPU6050_DLPF_BW_5);		// Digital Low Pass Filter Configuration
	setInterruptPin();
	setSleepEnabled(0);	// Wake up device.
	msDelay(100);
}
Exemplo n.º 9
0
int main (void)
{
        initI2C1 ();
        initUsart ();

#if 0

        /*
         * +----------------+
         * | Initialization |
         * +----------------+
         */

        accelgyro.initialize();
            setClockSource(MPU6050_CLOCK_PLL_XGYRO/*0x01*/);
                /*
                 * Excerpt from domcumentation : Upon power up, the MPU-60X0 clock source defaults to the internal oscillator.
                 * However, it is highly recommended that the device be configured to use one of the gyroscopes. Below is the code
                 * which does it:
                 */
                I2Cdev::writeBits(devAddr, MPU6050_RA_PWR_MGMT_1/*0x6B*/, MPU6050_PWR1_CLKSEL_BIT/*2*/, MPU6050_PWR1_CLKSEL_LENGTH/*3*/, source/*MPU6050_CLOCK_PLL_XGYRO         0x01*/);

            setFullScaleGyroRange(MPU6050_GYRO_FS_250/*0x00*/);
                /*
                 * 0x1b register is used to trigger gyroscope self-test and configure the gyroscopes’ full scale range. Below
                 * we set ful scale to be +/- 250 units (seconds?)
                 */
                I2Cdev::writeBits(devAddr, MPU6050_RA_GYRO_CONFIG/*0x1B*/, MPU6050_GCONFIG_FS_SEL_BIT/*4*/, MPU6050_GCONFIG_FS_SEL_LENGTH/*2*/, range/*0x00*/);

            setFullScaleAccelRange(MPU6050_ACCEL_FS_2/*0x00*/);
                /*
                 * Set accelerometer full scale to be +/- 2g.
                 */
                I2Cdev::writeBits(devAddr, MPU6050_RA_ACCEL_CONFIG/*0x1C*/, MPU6050_ACONFIG_AFS_SEL_BIT/*4*/, MPU6050_ACONFIG_AFS_SEL_LENGTH/*2*/, range/*0*/);

            setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!
                /*
                 * By default MPU6050 is in sleep mode after powering up. Below we are waking it back on. This
                 * is done using the same register as in first line,
                 */
                I2Cdev::writeBit(devAddr, MPU6050_RA_PWR_MGMT_1/*0x6B*/, MPU6050_PWR1_SLEEP_BIT/*6*/, enabled/*false*/);

        accelgyro.testConnection()
                getDeviceID() == 0x34;
                        /*
                         * This register is used to verify the identity of the device. The contents of WHO_AM_I are
                         * the upper 6 bits of the MPU-60X0’s 7-bit I C address. The Power-On-Reset value of Bit6:Bit1 is 0b110100 == 0x34.
                         */
                        I2Cdev::readBits(devAddr, MPU6050_RA_WHO_AM_I/*0x75*/, MPU6050_WHO_AM_I_BIT/*6*/, MPU6050_WHO_AM_I_LENGTH/*6*/, buffer);
                        return buffer[0];

        /*
         * +----------------+
         * | Main loop      |
         * +----------------+
         */
        int16_t ax, ay, az;
        int16_t gx, gy, gz;

        accelgyro.getMotion6(&ax, &ay, &az, &gx, &gy, &gz);

                /*
                 * In MPU-6000 and MPU-6050 Product Specification Rev 3.3 on pages 36 and 37 we read, that I²C reads and writes
                 * can be performed with single byte or multiple bytes. In single byte mode, we issue (after sending slave
                 * address ofcourse) a register address, and send or receive one byte of data. Multiple byte reads and writes, at the
                 * other hand consist of slave address, regiser address and multiple consecutive bytes od data. Slave puts or gets
                 * first byte from the register with the address we've just sent, and increases this addres by 1 after each byte.
                 *
                 * This is very useful in case of accelerometer and gyroscope because manufacturer has set up the apropriate registers
                 * cnsecutively, so one can read accel, internal temp and gyro data in one read command. Below is the code which does
                 * exactly this:
                 */
                I2Cdev::readBytes(devAddr, MPU6050_RA_ACCEL_XOUT_H/*0x3B*/, 14, buffer);
                *ax = (((int16_t)buffer[0]) << 8) | buffer[1];
                *ay = (((int16_t)buffer[2]) << 8) | buffer[3];
                *az = (((int16_t)buffer[4]) << 8) | buffer[5];
                *gx = (((int16_t)buffer[8]) << 8) | buffer[9];
                *gy = (((int16_t)buffer[10]) << 8) | buffer[11];
                *gz = (((int16_t)buffer[12]) << 8) | buffer[13];

#endif

        // Configuration:
        I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Transmitter); // start a transmission in Master transmitter mode
        I2C_write_slow (I2C1, MPU6050_RA_PWR_MGMT_1); // Register address
        I2C_write (I2C1, MPU6050_CLOCK_PLL_XGYRO); // Register value = 0x01. Which means, that DEVICE_RESET, SLEEP, CYCLE and TEMP_DIS are all 0.
        I2C_stop (I2C1);

        I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Transmitter);
        I2C_write (I2C1, MPU6050_RA_GYRO_CONFIG);
        I2C_write (I2C1, MPU6050_GYRO_FS_250); // All bits set to zero.
        I2C_stop (I2C1);

        I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Transmitter);
        I2C_write (I2C1, MPU6050_RA_ACCEL_CONFIG);
        I2C_write (I2C1, MPU6050_ACCEL_FS_2); // All bits set to zero.
        I2C_stop (I2C1);

        // Simple test if communication is working

        I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Transmitter);
        I2C_write (I2C1, MPU6050_RA_WHO_AM_I);
        I2C_stop (I2C1);
        I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Receiver);
        uint8_t whoAmI = I2C_read_nack (I2C1); // read one byte and don't request another byte
        I2C_stop (I2C1);

        if (whoAmI == 0x34) {
                usartSendString (USART1, "Accelerometer has been found!\r\n");
        }
        else {
                usartSendString (USART1, "*NO* Accelerometer has been found!\r\n");
        }

        while (1) {
                I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Transmitter);
                I2C_write (I2C1, MPU6050_RA_ACCEL_XOUT_H);
                I2C_stop (I2C1);
                I2C_start (I2C1, MPU6050_ADDRESS_AD0_LOW, I2C_Direction_Receiver);
                uint16_t ax = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t ay = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t az = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t temp = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t gx = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t gy = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_ack (I2C1);
                uint16_t gz = ((uint16_t)I2C_read_ack (I2C1) << 8) | I2C_read_nack (I2C1);
                I2C_stop (I2C1);

                printf ("Accel : (%d, %d, %d), temperature : %d, gyro : (%d, %d, %d)\r\n", ax, ay, az, temp, gx, gy, gz);
        }
}
/**
 * Initialize DMP inside MPU6050
 * @return boolean
 */
uint8_t MPU6050::dmpInitialize() {

    //Resetting MPU6050...
    reset();
    usleep(30000); // wait after reset

    //Disabling sleep mode...
    setSleepEnabled(false);

    // get MPU hardware revision
    //Selecting user bank 16...
    setMemoryBank(0x10, true, true);
    //Selecting memory byte 6...
    setMemoryStartAddress(0x06);
    //Checking hardware revision...
    uint8_t hwRevision __attribute__((__unused__)) = readMemoryByte();
    //Revision @ user[16][6] =
    //hwRevision, HEX);
    //Resetting memory bank selection to 0...
    setMemoryBank(0, false, false);

    // check OTP bank valid
    //Reading OTP bank valid flag...
    uint8_t otpValid __attribute__((__unused__)) = getOTPBankValid();
    //OTP bank is
    //otpValid ? F("valid!") : F("invalid!

    // get X/Y/Z gyro offsets
    //Reading gyro offset values...
    /*
    int8_t xgOffset = getXGyroOffset();
    int8_t ygOffset = getYGyroOffset();
    int8_t zgOffset = getZGyroOffset();

    sleep(5);
    for(int cnt = 0; cnt < 1000; cnt = cnt + 1)
    {
        std::cout << "X: " << typeid(xgOffset).name() << "Y: " << typeid(ygOffset).name() << "Z: " << typeid(zgOffset).name() << "\n";
        sleep(1);
        //xgOffset = (getXGyroOffset() + xgOffset)/2;
        //ygOffset = (getYGyroOffset() + ygOffset)/2;
        //zgOffset = (getZGyroOffset() + zgOffset)/2;
    }
    */

    //X gyro offset =
    //xgOffset);
    //Y gyro offset =
    //ygOffset);
    //Z gyro offset =
    //zgOffset);

    // setup weird slave stuff (?)
    //Setting slave 0 address to 0x7F...
    setSlaveAddress(0, 0x7F);
    //Disabling I2C Master mode...
    setI2CMasterModeEnabled(false);
    //Setting slave 0 address to 0x68 (self)...
    setSlaveAddress(0, 0x68);
    /*
    if (addr == 104)
    {
        std::cout << "Address: 104";
        setSlaveAddress(0, 0x68);
    }
    else
    {
        std::cout << "Address: 105";
        setSlaveAddress(0, 0x69);
    }
     * */
    //Resetting I2C Master control...
    resetI2CMaster();
    usleep(20000);

    // load DMP code into memory banks
    //Writing DMP code to MPU memory banks (

    // bytes)
    if (writeProgMemoryBlock(dmpMemory, MPU6050_DMP_CODE_SIZE)) {

        // write DMP configuration
        //Writing DMP configuration to MPU memory banks (

        // bytes in config def)
        if (writeProgDMPConfigurationSet(dmpConfig, MPU6050_DMP_CONFIG_SIZE)) {

            //Setting clock source to Z Gyro...
            setClockSource(MPU6050_CLOCK_PLL_ZGYRO);

            //Setting DMP and FIFO_OFLOW interrupts enabled...
            setIntEnabled(0x12);

            //Setting sample rate to 200Hz...
            setRate(4); // 1khz / (1 + 4) = 200 Hz

            //Setting external frame sync to TEMP_OUT_L[0]...
            setExternalFrameSync(MPU6050_EXT_SYNC_TEMP_OUT_L);

            //Setting DLPF bandwidth to 42Hz...
            setDLPFMode(MPU6050_DLPF_BW_42);

            //Setting gyro sensitivity to +/- 2000 deg/sec...
            setFullScaleGyroRange(MPU6050_GYRO_FS_2000);

            //Setting DMP configuration bytes (function unknown)...
            setDMPConfig1(0x03);
            setDMPConfig2(0x00);

            //Clearing OTP Bank flag...
            setOTPBankValid(false);
            /*
            //Setting X/Y/Z gyro offsets to previous values...
            setXGyroOffset(xgOffset);
            setYGyroOffset(ygOffset);
            setZGyroOffset(zgOffset);

            //Setting X/Y/Z gyro user offsets to zero...
            setXGyroOffsetUser(0);
            setYGyroOffsetUser(0);
            setZGyroOffsetUser(0);
            */

            //Writing final memory update 1/7 (function unknown)...
            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]);

            //Writing final memory update 2/7 (function unknown)...
            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]);

            //Resetting FIFO...
            resetFIFO();

            //Reading FIFO count...
            uint8_t fifoCount = getFIFOCount();
            uint8_t fifoBuffer[128];

            //fifoCount);
            if (fifoCount > 0)
		getFIFOBytes(fifoBuffer, fifoCount);

            //Setting motion detection threshold to 2...
            setMotionDetectionThreshold(2);

            //Setting zero-motion detection threshold to 156...
            setZeroMotionDetectionThreshold(156);

            //Setting motion detection duration to 80...
            setMotionDetectionDuration(80);

            //Setting zero-motion detection duration to 0...
            setZeroMotionDetectionDuration(0);

            //Resetting FIFO...
            resetFIFO();

            //Enabling FIFO...
            setFIFOEnabled(true);

            //Enabling DMP...
            setDMPEnabled(true);

            //Resetting DMP...
            resetDMP();

            //Writing final memory update 3/7 (function unknown)...
            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]);

            //Writing final memory update 4/7 (function unknown)...
            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]);

            //Writing final memory update 5/7 (function unknown)...
            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);


            //Reading FIFO data...
            getFIFOBytes(fifoBuffer, fifoCount);

            //Reading interrupt status...
            uint8_t mpuIntStatus __attribute__((__unused__)) = getIntStatus();

            //Current interrupt status= mpuIntStatus, HEX

            //Reading final memory update 6/7 (function unknown)...
            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]);

            //Waiting for FIFO count > 2...
            while ((fifoCount = getFIFOCount()) < 3);

            //Current FIFO count=
            //fifoCount);

            //Reading FIFO data...
            getFIFOBytes(fifoBuffer, fifoCount);

            //Reading interrupt status...
            mpuIntStatus = getIntStatus();

            //Current interrupt status=
            //mpuIntStatus, HEX

            //Writing final memory update 7/7 (function unknown)...
            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]);

            //DMP is good to go! Finally.

            //Disabling DMP (you turn it on later)...
            setDMPEnabled(false);

            //Setting up internal 42-byte (default) DMP packet buffer...
            dmpPacketSize = 42;
            /*if ((dmpPacketBuffer = (uint8_t *)malloc(42)) == 0) {
                return 3; // TODO: proper error code for no memory
            }*/

            //Resetting FIFO and clearing INT status one last time...
            resetFIFO();
            getIntStatus();
        } else {
            //ERROR! DMP configuration verification failed.
            return 2; // configuration block loading failed
        }
    } else {
        //ERROR! DMP code verification failed.
        return 1; // main binary block loading failed
    }
    return 0; // success
}
Exemplo n.º 11
0
void CurieIMUClass::setGyroRange(int range)
{
    setFullScaleGyroRange(range);
}
Exemplo n.º 12
0
uint8_t MPU6050DMP::dmpInitialize() {
    // reset device
    DEBUG_PRINTLN(F("\n\nResetting MPU6050..."));
    reset();
    delay(30); // wait after reset

    // enable sleep mode and wake cycle
    /*Serial.println(F("Enabling sleep mode..."));
    setSleepEnabled(true);
    Serial.println(F("Enabling wake cycle..."));
    setWakeCycleEnabled(true);*/

    // disable sleep mode
    DEBUG_PRINTLN(F("Disabling sleep mode..."));
    setSleepEnabled(false);

    // get MPU hardware revision
    DEBUG_PRINTLN(F("Selecting user bank 16..."));
    setMemoryBank(0x10, true, true);
    DEBUG_PRINTLN(F("Selecting memory byte 6..."));
    setMemoryStartAddress(0x06);
    DEBUG_PRINTLN(F("Checking hardware revision..."));
    uint8_t hwRevision = readMemoryByte();
    DEBUG_PRINT(F("Revision @ user[16][6] = "));
    DEBUG_PRINTLNF(hwRevision, HEX);
    DEBUG_PRINTLN(F("Resetting memory bank selection to 0..."));
    setMemoryBank(0, false, false);

    // check OTP bank valid
    DEBUG_PRINTLN(F("Reading OTP bank valid flag..."));
    uint8_t otpValid = getOTPBankValid();
    DEBUG_PRINT(F("OTP bank is "));
    DEBUG_PRINTLN(otpValid ? F("valid!") : F("invalid!"));

    // get X/Y/Z gyro offsets
    DEBUG_PRINTLN(F("Reading gyro offset TC values..."));
    int8_t xgOffsetTC = getXGyroOffsetTC();
    int8_t ygOffsetTC = getYGyroOffsetTC();
    int8_t zgOffsetTC = getZGyroOffsetTC();
    DEBUG_PRINT(F("X gyro offset = "));
    DEBUG_PRINTLN(xgOffset);
    DEBUG_PRINT(F("Y gyro offset = "));
    DEBUG_PRINTLN(ygOffset);
    DEBUG_PRINT(F("Z gyro offset = "));
    DEBUG_PRINTLN(zgOffset);

    // setup weird slave stuff (?)
    DEBUG_PRINTLN(F("Setting slave 0 address to 0x7F..."));
    setSlaveAddress(0, 0x7F);
    DEBUG_PRINTLN(F("Disabling I2C Master mode..."));
    setI2CMasterModeEnabled(false);
    DEBUG_PRINTLN(F("Setting slave 0 address to 0x68 (self)..."));
    setSlaveAddress(0, 0x68);
    DEBUG_PRINTLN(F("Resetting I2C Master control..."));
    resetI2CMaster();
    delay(20);

    // load DMP code into memory banks
    DEBUG_PRINT(F("Writing DMP code to MPU memory banks ("));
    DEBUG_PRINT(MPU6050_DMP_CODE_SIZE);
    DEBUG_PRINTLN(F(" bytes)"));
    if (writeProgMemoryBlock(dmpMemory, MPU6050_DMP_CODE_SIZE)) {
        DEBUG_PRINTLN(F("Success! DMP code written and verified."));

        // write DMP configuration
        DEBUG_PRINT(F("Writing DMP configuration to MPU memory banks ("));
        DEBUG_PRINT(MPU6050_DMP_CONFIG_SIZE);
        DEBUG_PRINTLN(F(" bytes in config def)"));
        if (writeProgDMPConfigurationSet(dmpConfig, MPU6050_DMP_CONFIG_SIZE)) {
            DEBUG_PRINTLN(F("Success! DMP configuration written and verified."));

            DEBUG_PRINTLN(F("Setting clock source to Z Gyro..."));
            setClockSource(MPU6050_CLOCK_PLL_ZGYRO);

            DEBUG_PRINTLN(F("Setting DMP and FIFO_OFLOW interrupts enabled..."));
            setIntEnabled(0x12);

            DEBUG_PRINTLN(F("Setting sample rate to 200Hz..."));
            setRate(4); // 1khz / (1 + 4) = 200 Hz

            DEBUG_PRINTLN(F("Setting external frame sync to TEMP_OUT_L[0]..."));
            setExternalFrameSync(MPU6050_EXT_SYNC_TEMP_OUT_L);

            DEBUG_PRINTLN(F("Setting DLPF bandwidth to 42Hz..."));
            setDLPFMode(MPU6050_DLPF_BW_42);

            DEBUG_PRINTLN(F("Setting gyro sensitivity to +/- 2000 deg/sec..."));
            setFullScaleGyroRange(MPU6050_GYRO_FS_2000);

            DEBUG_PRINTLN(F("Setting DMP configuration bytes (function unknown)..."));
            setDMPConfig1(0x03);
            setDMPConfig2(0x00);

            DEBUG_PRINTLN(F("Clearing OTP Bank flag..."));
            setOTPBankValid(false);

            DEBUG_PRINTLN(F("Setting X/Y/Z gyro offset TCs to previous values..."));
            setXGyroOffsetTC(xgOffsetTC);
            setYGyroOffsetTC(ygOffsetTC);
            setZGyroOffsetTC(zgOffsetTC);

            //DEBUG_PRINTLN(F("Setting X/Y/Z gyro user offsets to zero..."));
            //setXGyroOffset(0);
            //setYGyroOffset(0);
            //setZGyroOffset(0);

            DEBUG_PRINTLN(F("Writing final memory update 1/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Writing final memory update 2/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Resetting FIFO..."));
            resetFIFO();

            DEBUG_PRINTLN(F("Reading FIFO count..."));
            uint16_t fifoCount = getFIFOCount();
            uint8_t fifoBuffer[128];

            DEBUG_PRINT(F("Current FIFO count="));
            DEBUG_PRINTLN(fifoCount);
            getFIFOBytes(fifoBuffer, fifoCount);

            DEBUG_PRINTLN(F("Setting motion detection threshold to 2..."));
            setMotionDetectionThreshold(2);

            DEBUG_PRINTLN(F("Setting zero-motion detection threshold to 156..."));
            setZeroMotionDetectionThreshold(156);

            DEBUG_PRINTLN(F("Setting motion detection duration to 80..."));
            setMotionDetectionDuration(80);

            DEBUG_PRINTLN(F("Setting zero-motion detection duration to 0..."));
            setZeroMotionDetectionDuration(0);

            DEBUG_PRINTLN(F("Resetting FIFO..."));
            resetFIFO();

            DEBUG_PRINTLN(F("Enabling FIFO..."));
            setFIFOEnabled(true);

            DEBUG_PRINTLN(F("Enabling DMP..."));
            setDMPEnabled(true);

            DEBUG_PRINTLN(F("Resetting DMP..."));
            resetDMP();

            DEBUG_PRINTLN(F("Writing final memory update 3/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Writing final memory update 4/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Writing final memory update 5/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Waiting for FIFO count > 2..."));
            while ((fifoCount = getFIFOCount()) < 3);

            DEBUG_PRINT(F("Current FIFO count="));
            DEBUG_PRINTLN(fifoCount);
            DEBUG_PRINTLN(F("Reading FIFO data..."));
            getFIFOBytes(fifoBuffer, fifoCount);

            DEBUG_PRINTLN(F("Reading interrupt status..."));
            uint8_t mpuIntStatus = getIntStatus();

            DEBUG_PRINT(F("Current interrupt status="));
            DEBUG_PRINTLNF(mpuIntStatus, HEX);

            DEBUG_PRINTLN(F("Reading final memory update 6/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("Waiting for FIFO count > 2..."));
            while ((fifoCount = getFIFOCount()) < 3);

            DEBUG_PRINT(F("Current FIFO count="));
            DEBUG_PRINTLN(fifoCount);

            DEBUG_PRINTLN(F("Reading FIFO data..."));
            getFIFOBytes(fifoBuffer, fifoCount);

            DEBUG_PRINTLN(F("Reading interrupt status..."));
            mpuIntStatus = getIntStatus();

            DEBUG_PRINT(F("Current interrupt status="));
            DEBUG_PRINTLNF(mpuIntStatus, HEX);

            DEBUG_PRINTLN(F("Writing final memory update 7/7 (function unknown)..."));
            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]);

            DEBUG_PRINTLN(F("DMP is good to go! Finally."));

            DEBUG_PRINTLN(F("Disabling DMP (you turn it on later)..."));
            setDMPEnabled(false);

            DEBUG_PRINTLN(F("Setting up internal 42-byte (default) DMP packet buffer..."));
            dmpPacketSize = 42;
            /*if ((dmpPacketBuffer = (uint8_t *)malloc(42)) == 0) {
                return 3; // TODO: proper error code for no memory
            }*/

            DEBUG_PRINTLN(F("Resetting FIFO and clearing INT status one last time..."));
            resetFIFO();
            getIntStatus();
        } else {
            DEBUG_PRINTLN(F("ERROR! DMP configuration verification failed."));
            return 2; // configuration block loading failed
        }
    } else {
        DEBUG_PRINTLN(F("ERROR! DMP code verification failed."));
        return 1; // main binary block loading failed
    }
    return 0; // success
}