# The MIT License (MIT)
#
# Copyright (c) 2017 Dean Miller for Adafruit Industries
#
# Permission is hereby granted, free of charge, to any person obtaining a copy
# of this software and associated documentation files (the "Software"), to deal
# in the Software without restriction, including without limitation the rights
# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
# copies of the Software, and to permit persons to whom the Software is
# furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included in
# all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
# THE SOFTWARE.
"""
`adafruit_ina219`
====================================================
CircuitPython driver for the INA219 current sensor.
* Author(s): Dean Miller
Implementation Notes
--------------------
**Hardware:**
* `Adafruit INA219 High Side DC Current Sensor Breakout <https://www.adafruit.com/product/904>`_
* `Adafruit INA219 FeatherWing <https://www.adafruit.com/product/3650>`_
**Software and Dependencies:**
* Adafruit CircuitPython firmware (2.2.0+) for the ESP8622 and M0-based boards:
https://github.com/adafruit/circuitpython/releases
* Adafruit's Bus Device library: https://github.com/adafruit/Adafruit_CircuitPython_BusDevice
"""
from micropython import const
from adafruit_bus_device.i2c_device import I2CDevice
from adafruit_register.i2c_struct import ROUnaryStruct, UnaryStruct
from adafruit_register.i2c_bits import ROBits, RWBits
from adafruit_register.i2c_bit import ROBit
__version__ = "0.0.0-auto.0"
__repo__ = "https://github.com/adafruit/Adafruit_CircuitPython_INA219.git"
# Bits
# pylint: disable=bad-whitespace
# pylint: disable=too-few-public-methods
# Config Register (R/W)
_REG_CONFIG = const(0x00)
[docs]class BusVoltageRange:
"""Constants for ``bus_voltage_range``"""
RANGE_16V = 0x00 # set bus voltage range to 16V
RANGE_32V = 0x01 # set bus voltage range to 32V (default)
[docs]class Gain:
"""Constants for ``gain``"""
DIV_1_40MV = 0x00 # shunt prog. gain set to 1, 40 mV range
DIV_2_80MV = 0x01 # shunt prog. gain set to /2, 80 mV range
DIV_4_160MV = 0x02 # shunt prog. gain set to /4, 160 mV range
DIV_8_320MV = 0x03 # shunt prog. gain set to /8, 320 mV range
[docs]class ADCResolution:
"""Constants for ``bus_adc_resolution`` or ``shunt_adc_resolution``"""
ADCRES_9BIT_1S = 0x00 # 9bit, 1 sample, 84us
ADCRES_10BIT_1S = 0x01 # 10bit, 1 sample, 148us
ADCRES_11BIT_1S = 0x02 # 11 bit, 1 sample, 276us
ADCRES_12BIT_1S = 0x03 # 12 bit, 1 sample, 532us
ADCRES_12BIT_2S = 0x09 # 12 bit, 2 samples, 1.06ms
ADCRES_12BIT_4S = 0x0A # 12 bit, 4 samples, 2.13ms
ADCRES_12BIT_8S = 0x0B # 12bit, 8 samples, 4.26ms
ADCRES_12BIT_16S = 0x0C # 12bit, 16 samples, 8.51ms
ADCRES_12BIT_32S = 0x0D # 12bit, 32 samples, 17.02ms
ADCRES_12BIT_64S = 0x0E # 12bit, 64 samples, 34.05ms
ADCRES_12BIT_128S = 0x0F # 12bit, 128 samples, 68.10ms
[docs]class Mode:
"""Constants for ``mode``"""
POWERDOW = 0x00 # power down
SVOLT_TRIGGERED = 0x01 # shunt voltage triggered
BVOLT_TRIGGERED = 0x02 # bus voltage triggered
SANDBVOLT_TRIGGERED = 0x03 # shunt and bus voltage triggered
ADCOFF = 0x04 # ADC off
SVOLT_CONTINUOUS = 0x05 # shunt voltage continuous
BVOLT_CONTINUOUS = 0x06 # bus voltage continuous
SANDBVOLT_CONTINUOUS = 0x07 # shunt and bus voltage continuous
# SHUNT VOLTAGE REGISTER (R)
_REG_SHUNTVOLTAGE = const(0x01)
# BUS VOLTAGE REGISTER (R)
_REG_BUSVOLTAGE = const(0x02)
# POWER REGISTER (R)
_REG_POWER = const(0x03)
# CURRENT REGISTER (R)
_REG_CURRENT = const(0x04)
# CALIBRATION REGISTER (R/W)
_REG_CALIBRATION = const(0x05)
# pylint: enable=too-few-public-methods
def _to_signed(num):
if num > 0x7FFF:
num -= 0x10000
return num
[docs]class INA219:
"""Driver for the INA219 current sensor"""
# Basic API:
# INA219( i2c_bus, i2c_addr) Create instance of INA219 sensor
# :param i2c_bus The I2C bus the INA219is connected to
# :param i2c_addr (0x40) Address of the INA219 on the bus (default 0x40)
# shunt_voltage RO : shunt voltage scaled to Volts
# bus_voltage RO : bus voltage (V- to GND) scaled to volts (==load voltage)
# current RO : current through shunt, scaled to mA
# power RO : power consumption of the load, scaled to Watt
# set_calibration_32V_2A() Initialize chip for 32V max and up to 2A (default)
# set_calibration_32V_1A() Initialize chip for 32V max and up to 1A
# set_calibration_16V_400mA() Initialize chip for 16V max and up to 400mA
# Advanced API:
# config register break-up
# reset WO : Write Reset.RESET to reset the chip (must recalibrate)
# bus_voltage_range RW : Bus Voltage Range field (use BusVoltageRange.XXX constants)
# gain RW : Programmable Gain field (use Gain.XXX constants)
# bus_adc_resolution RW : Bus ADC resolution and averaging modes (ADCResolution.XXX)
# shunt_adc_resolution RW : Shunt ADC resolution and averaging modes (ADCResolution.XXX)
# mode RW : operating modes in config register (use Mode.XXX constants)
# raw_shunt_voltage RO : Shunt Voltage register (not scaled)
# raw_bus_voltage RO : Bus Voltage field in Bus Voltage register (not scaled)
# conversion_ready RO : Conversion Ready bit in Bus Voltage register
# overflow RO : Math Overflow bit in Bus Voltage register
# raw_power RO : Power register (not scaled)
# raw_current RO : Current register (not scaled)
# calibration RW : calibration register (note: value is cached)
def __init__(self, i2c_bus, addr=0x40):
self.i2c_device = I2CDevice(i2c_bus, addr)
self.i2c_addr = addr
# Set chip to known config values to start
self._cal_value = 0
self._current_lsb = 0
self._power_lsb = 0
self.set_calibration_32V_2A()
# config register break-up
reset = RWBits( 1, _REG_CONFIG, 15, 2, False)
bus_voltage_range = RWBits( 1, _REG_CONFIG, 13, 2, False)
gain = RWBits( 2, _REG_CONFIG, 11, 2, False)
bus_adc_resolution = RWBits( 4, _REG_CONFIG, 7, 2, False)
shunt_adc_resolution = RWBits( 4, _REG_CONFIG, 3, 2, False)
mode = RWBits( 3, _REG_CONFIG, 0, 2, False)
# shunt voltage register
raw_shunt_voltage = ROUnaryStruct(_REG_SHUNTVOLTAGE, ">h")
#bus voltage register
raw_bus_voltage = ROBits( 13, _REG_BUSVOLTAGE, 3, 2, False)
conversion_ready = ROBit( _REG_BUSVOLTAGE, 1, 2, False)
overflow = ROBit( _REG_BUSVOLTAGE, 0, 2, False)
# power and current registers
raw_power = ROUnaryStruct(_REG_POWER, ">H")
raw_current = ROUnaryStruct(_REG_CURRENT, ">h")
# calibration register
_raw_calibration = UnaryStruct(_REG_CALIBRATION, ">H")
@property
def calibration(self):
"""Calibration register (cached value)"""
return self._cal_value # return cached value
@calibration.setter
def calibration(self, cal_value):
self._cal_value = cal_value # value is cached for ``current`` and ``power`` properties
self._raw_calibration = self._cal_value
@property
def shunt_voltage(self):
"""The shunt voltage (between V+ and V-) in Volts (so +-.327V)"""
# The least signficant bit is 10uV which is 0.00001 volts
return self.raw_shunt_voltage * 0.00001
@property
def bus_voltage(self):
"""The bus voltage (between V- and GND) in Volts"""
# Shift to the right 3 to drop CNVR and OVF and multiply by LSB
# Each least signficant bit is 4mV
return self.raw_bus_voltage * 0.004
@property
def current(self):
"""The current through the shunt resistor in milliamps."""
# Sometimes a sharp load will reset the INA219, which will
# reset the cal register, meaning CURRENT and POWER will
# not be available ... always setting a cal
# value even if it's an unfortunate extra step
self._raw_calibration = self._cal_value
# Now we can safely read the CURRENT register!
return self.raw_current * self._current_lsb
@property
def power(self):
"""The power through the load in Watt."""
# Sometimes a sharp load will reset the INA219, which will
# reset the cal register, meaning CURRENT and POWER will
# not be available ... always setting a cal
# value even if it's an unfortunate extra step
self._raw_calibration = self._cal_value
# Now we can safely read the CURRENT register!
return self.raw_power * self._power_lsb
[docs] def set_calibration_32V_2A(self): # pylint: disable=invalid-name
"""Configures to INA219 to be able to measure up to 32V and 2A of current. Counter
overflow occurs at 3.2A.
..note :: These calculations assume a 0.1 shunt ohm resistor is present
"""
# 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)
self._current_lsb = .1 # Current LSB = 100uA per bit
# 5. Compute the calibration register
# Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
# Cal = 4096 (0x1000)
self._cal_value = 4096
# 6. Calculate the power LSB
# PowerLSB = 20 * CurrentLSB
# PowerLSB = 0.002 (2mW per bit)
self._power_lsb = .002 # Power LSB = 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 Calibration register to 'Cal' calculated above
self._raw_calibration = self._cal_value
# Set Config register to take into account the settings above
self.bus_voltage_range = BusVoltageRange.RANGE_32V
self.gain = Gain.DIV_8_320MV
self.bus_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.shunt_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.mode = Mode.SANDBVOLT_CONTINUOUS
[docs] def set_calibration_32V_1A(self): # pylint: disable=invalid-name
"""Configures to INA219 to be able to measure up to 32V and 1A of current. Counter overflow
occurs at 1.3A.
.. note:: These calculations assume a 0.1 ohm shunt resistor is present"""
# 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 (30.5uA 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 = 0.0000400 (40uA per bit)
self._current_lsb = 0.04 # In milliamps
# 5. Compute the calibration register
# Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
# Cal = 10240 (0x2800)
self._cal_value = 10240
# 6. Calculate the power LSB
# PowerLSB = 20 * CurrentLSB
# PowerLSB = 0.0008 (800uW per bit)
self._power_lsb = 0.0008
# 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 Calibration register to 'Cal' calculated above
self._raw_calibration = self._cal_value
# Set Config register to take into account the settings above
self.bus_voltage_range = BusVoltageRange.RANGE_32V
self.gain = Gain.DIV_8_320MV
self.bus_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.shunt_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.mode = Mode.SANDBVOLT_CONTINUOUS
[docs] def set_calibration_16V_400mA(self): # pylint: disable=invalid-name
"""Configures to INA219 to be able to measure up to 16V and 400mA of current. Counter
overflow occurs at 1.6A.
.. note:: These calculations assume a 0.1 ohm shunt resistor is present"""
# 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)
self._current_lsb = 0.05 # in milliamps
# 5. Compute the calibration register
# Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
# Cal = 8192 (0x2000)
self._cal_value = 8192
# 6. Calculate the power LSB
# PowerLSB = 20 * CurrentLSB
# PowerLSB = 0.001 (1mW per bit)
self._power_lsb = 0.001
# 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 Calibration register to 'Cal' calculated above
self._raw_calibration = self._cal_value
# Set Config register to take into account the settings above
self.bus_voltage_range = BusVoltageRange.RANGE_16V
self.gain = Gain.DIV_1_40MV
self.bus_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.shunt_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.mode = Mode.SANDBVOLT_CONTINUOUS
[docs] def set_calibration_16V_5A(self): # pylint: disable=invalid-name
"""Configures to INA219 to be able to measure up to 16V and 5000mA of current. Counter
overflow occurs at 8.0A.
.. note:: These calculations assume a 0.02 ohm shunt resistor is present"""
# Calibration which uses the highest precision for
# current measurement (0.1mA), at the expense of
# only supporting 16V at 5000mA max.
# VBUS_MAX = 16V
# VSHUNT_MAX = 0.16 (Assumes Gain 3, 160mV)
# RSHUNT = 0.02 (Resistor value in ohms)
# 1. Determine max possible current
# MaxPossible_I = VSHUNT_MAX / RSHUNT
# MaxPossible_I = 8.0A
# 2. Determine max expected current
# MaxExpected_I = 5.0A
# 3. Calculate possible range of LSBs (Min = 15-bit, Max = 12-bit)
# MinimumLSB = MaxExpected_I/32767
# MinimumLSB = 0.0001529 (uA per bit)
# MaximumLSB = MaxExpected_I/4096
# MaximumLSB = 0.0012207 (uA per bit)
# 4. Choose an LSB between the min and max values
# (Preferrably a roundish number close to MinLSB)
# CurrentLSB = 0.00016 (uA per bit)
self._current_lsb = 0.1524 # in milliamps
# 5. Compute the calibration register
# Cal = trunc (0.04096 / (Current_LSB * RSHUNT))
# Cal = 13434 (0x347a)
self._cal_value = 13434
# 6. Calculate the power LSB
# PowerLSB = 20 * CurrentLSB
# PowerLSB = 0.003 (3.048mW per bit)
self._power_lsb = 0.003048
# 7. Compute the maximum current and shunt voltage values before overflow
#
# 8. Compute the Maximum Power
#
# Set Calibration register to 'Cal' calcutated above
self._raw_calibration = self._cal_value
# Set Config register to take into account the settings above
self.bus_voltage_range = BusVoltageRange.RANGE_16V
self.gain = Gain.DIV_4_160MV
self.bus_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.shunt_adc_resolution = ADCResolution.ADCRES_12BIT_1S
self.mode = Mode.SANDBVOLT_CONTINUOUS