/*! * @file Adafruit_INA219_Soft.cpp * * @mainpage Adafruit INA219 current/power monitor IC * * @section intro_sec Introduction * * Driver for the INA219 current sensor * * This is a library for the Adafruit INA219 breakout * ----> https://www.adafruit.com/products/904 * * Adafruit invests time and resources providing this open source code, * please support Adafruit and open-source hardware by purchasing * products from Adafruit! * * @section author Author * * Written by Kevin "KTOWN" Townsend for Adafruit Industries. * * @section license License * * BSD license, all text here must be included in any redistribution. * */ #include "Arduino.h" #include #include "Adafruit_INA219_Soft.h" /*! * @brief Sends a single command byte over I2C * @param reg * register address * @param value * value to write */ void Adafruit_INA219_Soft::wireWriteRegister(uint8_t reg, uint16_t value) { _i2c->beginTransmission(ina219_i2caddr); _i2c->write(reg); // Register _i2c->write((value >> 8) & 0xFF); // Upper 8-bits _i2c->write(value & 0xFF); // Lower 8-bits _i2c->endTransmission(); } /*! * @brief Reads a 16 bit values over I2C * @param reg * register address * @param *value * read value */ void Adafruit_INA219_Soft::wireReadRegister(uint8_t reg, uint16_t *value) { _i2c->beginTransmission(ina219_i2caddr); _i2c->write(reg); // Register _i2c->endTransmission(); delay(1); // Max 12-bit conversion time is 586us per sample _i2c->requestFrom(ina219_i2caddr, (uint8_t)2); // Shift values to create properly formed integer *value = ((_i2c->read() << 8) | _i2c->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_Soft::setCalibration_32V_2A() { // 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 = 3.2A // 2. Determine max expected current // MaxExpected_I = 2.0A // 3. Calculate possible range of LSBs (Min = 15-bit, Max = 12-bit) // MinimumLSB = MaxExpected_I/32767 // MinimumLSB = 0.000061 (61uA per bit) // MaximumLSB = MaxExpected_I/4096 // MaximumLSB = 0,000488 (488uA 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 = 4096 (0x1000) ina219_calValue = 4096; // 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 = 0.32V // // 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_powerMultiplier_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 Set power save mode according to parameters * @param on * boolean value */ void Adafruit_INA219_Soft::powerSave(bool on) { uint16_t current; wireReadRegister(INA219_REG_CONFIG, ¤t); uint8_t next; if (on) { next = current | INA219_CONFIG_MODE_POWERDOWN; } else { next = current & ~INA219_CONFIG_MODE_POWERDOWN; } wireWriteRegister(INA219_REG_CONFIG, next); } /*! * @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_Soft::setCalibration_32V_1A() { // 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 = 3.2A // 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 = 10240; // 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 = 0.131068V // // 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 = 1.31068 * 32V // MaximumPower = 41.94176W // Set multipliers to convert raw current/power values ina219_currentDivider_mA = 25; // Current LSB = 40uA per bit (1000/40 = 25) ina219_powerMultiplier_mW = 0.8f; // Power LSB = 800uW 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 set device to alibration which uses the highest precision for * current measurement (0.1mA), at the expense of * only supporting 16V at 400mA max. */ void Adafruit_INA219_Soft::setCalibration_16V_400mA() { // Calibration which uses the highest precision for // current measurement (0.1mA), at the expense of // only supporting 16V at 400mA max. // VBUS_MAX = 16V // VSHUNT_MAX = 0.04 (Assumes Gain 1, 40mV) // RSHUNT = 0.1 (Resistor value in ohms) // 1. Determine max possible current // MaxPossible_I = VSHUNT_MAX / RSHUNT // MaxPossible_I = 0.4A // 2. Determine max expected current // MaxExpected_I = 0.4A // 3. Calculate possible range of LSBs (Min = 15-bit, Max = 12-bit) // MinimumLSB = MaxExpected_I/32767 // MinimumLSB = 0.0000122 (12uA per bit) // MaximumLSB = MaxExpected_I/4096 // MaximumLSB = 0.0000977 (98uA per bit) // 4. Choose an LSB between the min and max values // (Preferrably a roundish number close to MinLSB) // CurrentLSB = 0.00005 (50uA per bit) // 5. Compute the calibration register // Cal = trunc (0.04096 / (Current_LSB * RSHUNT)) // Cal = 8192 (0x2000) ina219_calValue = 8192; // 6. Calculate the power LSB // PowerLSB = 20 * CurrentLSB // PowerLSB = 0.001 (1mW per bit) // 7. Compute the maximum current and shunt voltage values before overflow // // Max_Current = Current_LSB * 32767 // Max_Current = 1.63835A 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_Current_Before_Overflow = MaxPossible_I // Max_Current_Before_Overflow = 0.4 // // Max_ShuntVoltage = Max_Current_Before_Overflow * RSHUNT // Max_ShuntVoltage = 0.04V // // If Max_ShuntVoltage >= VSHUNT_MAX // Max_ShuntVoltage_Before_Overflow = VSHUNT_MAX // Else // Max_ShuntVoltage_Before_Overflow = Max_ShuntVoltage // End If // // Max_ShuntVoltage_Before_Overflow = VSHUNT_MAX // Max_ShuntVoltage_Before_Overflow = 0.04V // 8. Compute the Maximum Power // MaximumPower = Max_Current_Before_Overflow * VBUS_MAX // MaximumPower = 0.4 * 16V // MaximumPower = 6.4W // Set multipliers to convert raw current/power values ina219_currentDivider_mA = 20; // Current LSB = 50uA per bit (1000/50 = 20) ina219_powerMultiplier_mW = 1.0f; // Power LSB = 1mW 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_16V | INA219_CONFIG_GAIN_1_40MV | 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 * @param addr the I2C address the device can be found on. Default is 0x40 */ Adafruit_INA219_Soft::Adafruit_INA219_Soft(uint8_t addr) { ina219_i2caddr = addr; ina219_currentDivider_mA = 0; ina219_powerMultiplier_mW = 0.0f; } /*! * @brief Setups the HW (defaults to 32V and 2A for calibration values) * @param theWire the TwoWire object to use */ void Adafruit_INA219_Soft::begin(SoftwareWire *theWire) { _i2c = theWire; init(); } /*! * @brief begin I2C and set up the hardware */ void Adafruit_INA219_Soft::init() { _i2c->begin(); // Set chip to large range config values to start setCalibration_32V_2A(); } /*! * @brief Gets the raw bus voltage (16-bit signed integer, so +-32767) * @return the raw bus voltage reading */ int16_t Adafruit_INA219_Soft::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) * @return the raw shunt voltage reading */ int16_t Adafruit_INA219_Soft::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) * @return the raw current reading */ int16_t Adafruit_INA219_Soft::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 raw power value (16-bit signed integer, so +-32767) * @return raw power reading */ int16_t Adafruit_INA219_Soft::getPower_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 POWER register! wireReadRegister(INA219_REG_POWER, &value); return (int16_t)value; } /*! * @brief Gets the shunt voltage in mV (so +-327mV) * @return the shunt voltage converted to millivolts */ float Adafruit_INA219_Soft::getShuntVoltage_mV() { int16_t value; value = getShuntVoltage_raw(); return value * 0.01; } /*! * @brief Gets the shunt voltage in volts * @return the bus voltage converted to volts */ float Adafruit_INA219_Soft::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 * @return the current reading convereted to milliamps */ float Adafruit_INA219_Soft::getCurrent_mA() { float valueDec = getCurrent_raw(); valueDec /= ina219_currentDivider_mA; return valueDec; } /*! * @brief Gets the power value in mW, taking into account the * config settings and current LSB * @return power reading converted to milliwatts */ float Adafruit_INA219_Soft::getPower_mW() { float valueDec = getPower_raw(); valueDec *= ina219_powerMultiplier_mW; return valueDec; }