ina129Spark.cpp

//**************************************************************************
/*!
    @file     Adafruit_INA219.cpp
    @author   K.Townsend (Adafruit Industries)
	@license  BSD (see license.txt)

	Driver for the INA219 current sensor

	This is a library for the Adafruit INA219 breakout
	----> https://www.adafruit.com/products/???

	Adafruit invests time and resources providing this open source code,
	please support Adafruit and open-source hardware by purchasing
	products from Adafruit!

	@section  HISTORY

    v1.0 - First release
*/
//**************************************************************************
#include "ina129Spark.h"

/**************************************************************************/
/*!
    @brief  Sends a single command byte over I2C
*/
/**************************************************************************/
void Adafruit_INA219::wireWriteRegister(uint8_t reg, uint16_t value)
{
  Wire.beginTransmission(ina219_i2caddr);
  Wire.write(reg);                       // Register
  Wire.write((value >> 8) & 0xFF);       // Upper 8-bits
  Wire.write(value & 0xFF);              // Lower 8-bits

  Wire.endTransmission();
}

/**************************************************************************/
/*!
    @brief  Reads a 16 bit values over I2C
*/
/**************************************************************************/
void Adafruit_INA219::wireReadRegister(uint8_t reg, uint16_t *value)
{
  Wire.beginTransmission(ina219_i2caddr);
  Wire.write(reg);                          // Register

  Wire.endTransmission();

  delay(1); // Max 12-bit conversion time is 586us per sample

  Wire.requestFrom(ina219_i2caddr, (uint8_t)2);
  // Shift values to create properly formed integer
  *value = ((Wire.read() << 8) | Wire.read());

}

/**************************************************************************/
/*!
    @brief  Configures to INA219 to be able to measure up to 32V and 2A
            of current.  Each unit of current corresponds to 100uA, and
            each unit of power corresponds to 2mW. Counter overflow
            occurs at 3.2A.

    @note   These calculations assume a 0.1 ohm resistor is present
*/
/**************************************************************************/
void Adafruit_INA219::ina219SetCalibration_32V_2A(void)
{
  // By default we use a pretty huge range for the input voltage,
  // which probably isn't the most appropriate choice for system
  // that don't use a lot of power.  But all of the calculations
  // are shown below if you want to change the settings.  You will
  // also need to change any relevant register settings, such as
  // setting the VBUS_MAX to 16V instead of 32V, etc.

  // VBUS_MAX = 32V             (Assumes 32V, can also be set to 16V)
  // VSHUNT_MAX = 0.32          (Assumes Gain 8, 320mV, can also be 0.16, 0.08, 0.04)
  // RSHUNT = 0.1               (Resistor value in ohms)

  // 1. Determine max possible current
  // MaxPossible_I = VSHUNT_MAX / RSHUNT
  // MaxPossible_I = 0.32A

  // 2. Determine max expected current
  // MaxExpected_I = 1.0A

  // 3. Calculate possible range of LSBs (Min = 15-bit, Max = 12-bit)
  // MinimumLSB = MaxExpected_I/32767
  // MinimumLSB = 0.000031             (31uA per bit)
  // MaximumLSB = MaxExpected_I/4096
  // MaximumLSB = 0.000244              (244uA per bit)

  // 4. Choose an LSB between the min and max values
  //    (Preferrably a roundish number close to MinLSB)
  // CurrentLSB = 0.0001 (100uA per bit)

  // 5. Compute the calibration register
  // Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
  // Cal = 409.6 (0x019A)

  ina219_calValue = 4010;

  // 6. Calculate the power LSB
  // PowerLSB = 20 * CurrentLSB
  // PowerLSB = 0.002 (2mW per bit)

  // 7. Compute the maximum current and shunt voltage values before overflow
  //
  // Max_Current = Current_LSB * 32767
  // Max_Current = 3.2767A before overflow
  //
  // If Max_Current > Max_Possible_I then
  //    Max_Current_Before_Overflow = MaxPossible_I
  // Else
  //    Max_Current_Before_Overflow = Max_Current
  // End If
  //
  // Max_ShuntVoltage = Max_Current_Before_Overflow * RSHUNT
  // Max_ShuntVoltage = 3.2V
  //
  // If Max_ShuntVoltage >= VSHUNT_MAX
  //    Max_ShuntVoltage_Before_Overflow = VSHUNT_MAX
  // Else
  //    Max_ShuntVoltage_Before_Overflow = Max_ShuntVoltage
  // End If

  // 8. Compute the Maximum Power
  // MaximumPower = Max_Current_Before_Overflow * VBUS_MAX
  // MaximumPower = 3.2 * 32V
  // MaximumPower = 102.4W

  // Set multipliers to convert raw current/power values
  ina219_currentDivider_mA = 10;  // Current LSB = 100uA per bit (1000/100 = 10)
  ina219_powerDivider_mW = 2;     // Power LSB = 1mW per bit (2/1)

  // Set Calibration register to 'Cal' calculated above
  wireWriteRegister(INA219_REG_CALIBRATION, ina219_calValue);

  // Set Config register to take into account the settings above
  uint16_t config = INA219_CONFIG_BVOLTAGERANGE_32V |
                    INA219_CONFIG_GAIN_8_320MV |
                    INA219_CONFIG_BADCRES_12BIT |
                    INA219_CONFIG_SADCRES_12BIT_1S_532US |
                    INA219_CONFIG_MODE_SANDBVOLT_CONTINUOUS;
  wireWriteRegister(INA219_REG_CONFIG, config);
}

/**************************************************************************/
/*!
    @brief  Configures to INA219 to be able to measure up to 32V and 1A
            of current.  Each unit of current corresponds to 40uA, and each
            unit of power corresponds to 800?W. Counter overflow occurs at
            1.3A.

    @note   These calculations assume a 0.1 ohm resistor is present
*/
/**************************************************************************/
void Adafruit_INA219::ina219SetCalibration_32V_1A(void)
{
  // By default we use a pretty huge range for the input voltage,
  // which probably isn't the most appropriate choice for system
  // that don't use a lot of power.  But all of the calculations
  // are shown below if you want to change the settings.  You will
  // also need to change any relevant register settings, such as
  // setting the VBUS_MAX to 16V instead of 32V, etc.

  // VBUS_MAX = 32V		(Assumes 32V, can also be set to 16V)
  // VSHUNT_MAX = 0.32	(Assumes Gain 8, 320mV, can also be 0.16, 0.08, 0.04)
  // RSHUNT = 1.0			(Resistor value in ohms)

  // 1. Determine max possible current
  // MaxPossible_I = VSHUNT_MAX / RSHUNT
  // MaxPossible_I = 0.32A

  // 2. Determine max expected current
  // MaxExpected_I = 1.0A

  // 3. Calculate possible range of LSBs (Min = 15-bit, Max = 12-bit)
  // MinimumLSB = MaxExpected_I/32767
  // MinimumLSB = 0.0000305             (30.5?A per bit)
  // MaximumLSB = MaxExpected_I/4096
  // MaximumLSB = 0.000244              (244?A per bit)

  // 4. Choose an LSB between the min and max values
  //    (Preferrably a roundish number close to MinLSB)
  // CurrentLSB = 0.0000400 (40?A per bit)

  // 5. Compute the calibration register
  // Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
  // Cal = 10240 (0x2800)

  ina219_calValue = 1024;

  // 6. Calculate the power LSB
  // PowerLSB = 20 * CurrentLSB
  // PowerLSB = 0.0008 (800?W per bit)

  // 7. Compute the maximum current and shunt voltage values before overflow
  //
  // Max_Current = Current_LSB * 32767
  // Max_Current = 1.31068A before overflow
  //
  // If Max_Current > Max_Possible_I then
  //    Max_Current_Before_Overflow = MaxPossible_I
  // Else
  //    Max_Current_Before_Overflow = Max_Current
  // End If
  //
  // ... In this case, we're good though since Max_Current is less than MaxPossible_I
  //
  // Max_ShuntVoltage = Max_Current_Before_Overflow * RSHUNT
  // Max_ShuntVoltage = 1.31068V
  //
  // If Max_ShuntVoltage >= VSHUNT_MAX
  //    Max_ShuntVoltage_Before_Overflow = VSHUNT_MAX
  // Else
  //    Max_ShuntVoltage_Before_Overflow = Max_ShuntVoltage
  // End If

  // 8. Compute the Maximum Power
  // MaximumPower = Max_Current_Before_Overflow * VBUS_MAX
  // MaximumPower = 0.32 * 32V
  // MaximumPower = 10.24W

  // Set multipliers to convert raw current/power values
  ina219_currentDivider_mA = 25;      // Current LSB = 40uA per bit (1000/40 = 25)
  ina219_powerDivider_mW = 1;         // Power LSB = 800?W per bit

  // Set Calibration register to 'Cal' calculated above
  wireWriteRegister(INA219_REG_CALIBRATION, ina219_calValue);

  // Set Config register to take into account the settings above
  uint16_t config = INA219_CONFIG_BVOLTAGERANGE_32V |
                    INA219_CONFIG_GAIN_8_320MV |
                    INA219_CONFIG_BADCRES_12BIT |
                    INA219_CONFIG_SADCRES_12BIT_1S_532US |
                    INA219_CONFIG_MODE_SANDBVOLT_CONTINUOUS;
  wireWriteRegister(INA219_REG_CONFIG, config);
}

/**************************************************************************/
/*!
    @brief  Instantiates a new INA219 class
*/
/**************************************************************************/
Adafruit_INA219::Adafruit_INA219(uint8_t addr) {
  ina219_i2caddr = addr;
  ina219_currentDivider_mA = 0;
  ina219_powerDivider_mW = 0;
}

/**************************************************************************/
/*!
    @brief  Setups the HW (defaults to 32V and 2A for calibration values)
*/
/**************************************************************************/
void Adafruit_INA219::begin() {
  Wire.begin();
  // Set chip to known config values to start
  ina219SetCalibration_32V_1A();
}

/**************************************************************************/
/*!
    @brief  Gets the raw bus voltage (16-bit signed integer, so +-32767)
*/
/**************************************************************************/
int16_t Adafruit_INA219::getBusVoltage_raw() {
  uint16_t value;
  wireReadRegister(INA219_REG_BUSVOLTAGE, &value);

  // Shift to the right 3 to drop CNVR and OVF and multiply by LSB
  return (int16_t)((value >> 3) * 4);
}

/**************************************************************************/
/*!
    @brief  Gets the raw shunt voltage (16-bit signed integer, so +-32767)
*/
/**************************************************************************/
int16_t Adafruit_INA219::getShuntVoltage_raw() {
  uint16_t value;
  wireReadRegister(INA219_REG_SHUNTVOLTAGE, &value);
  return (int16_t)value;
}

/**************************************************************************/
/*!
    @brief  Gets the raw current value (16-bit signed integer, so +-32767)
*/
/**************************************************************************/
int16_t Adafruit_INA219::getCurrent_raw() {
  uint16_t value;

  // Sometimes a sharp load will reset the INA219, which will
  // reset the cal register, meaning CURRENT and POWER will
  // not be available ... avoid this by always setting a cal
  // value even if it's an unfortunate extra step
  wireWriteRegister(INA219_REG_CALIBRATION, ina219_calValue);

  // Now we can safely read the CURRENT register!
  wireReadRegister(INA219_REG_CURRENT, &value);

  return (int16_t)value;
}

/**************************************************************************/
/*!
    @brief  Gets the shunt voltage in mV (so +-327mV)
*/
/**************************************************************************/
float Adafruit_INA219::getShuntVoltage_mV() {
  int16_t value;
  value = getShuntVoltage_raw();
  return value * 0.01;
}

/**************************************************************************/
/*!
    @brief  Gets the shunt voltage in volts
*/
/**************************************************************************/
float Adafruit_INA219::getBusVoltage_V() {
  int16_t value = getBusVoltage_raw();
  return value * 0.001;
}

/**************************************************************************/
/*!
    @brief  Gets the current value in mA, taking into account the
            config settings and current LSB
*/
/**************************************************************************/
float Adafruit_INA219::getCurrent_mA() {
  float valueDec = getCurrent_raw();
  valueDec /= ina219_currentDivider_mA;
  return valueDec;
}