esphome-docs/components/sensor/atm90e32.rst
John 9b32fd1885 added reactive power, power factor, chip temp... (#380)
and additional 6 channel example without software power calculation template
2019-10-27 12:05:21 +01:00

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ATM90E32 Power Sensor
=====================
.. seo::
:description: Instructions for setting up ATM90E32 energy metering sensors
:image: atm90e32.png
:keywords: ATM90E32, CircuitSetup, Split Single Phase Real Time Whole House Energy Meter, Expandable 6 Channel ESP32 Energy Meter Main Board
The ``atm90e32`` sensor platform allows you to use your ATM90E32 voltage/current and power sensors
(`datasheet <http://ww1.microchip.com/downloads/en/devicedoc/Atmel-46003-SE-M90E32AS-Datasheet.pdf>`__) sensors with
ESPHome. This sensor is commonly found in CircuitSetup 2 and 6 channel energy meters.
Communication with the device is done via an :ref:`SPI bus <spi>`, so you need to have an ``spi:`` entry in your configuration
with both ``mosi_pin`` and ``miso_pin`` set.
The atm90e32 IC can measure up to three AC voltages. Although, typically, only one
voltage measurement would be used for the mains electricity phase of a
household. Three current measurements are read via CT clamps.
The `CircuitSetup Split Single Phase Energy Meter <https://circuitsetup.us/index.php/product/split-single-phase-real-time-whole-house-energy-meter-v1-2/>`__ can read 2 current channels and 1 (expandable to 2) voltage channel.
.. figure:: images/atm90e32-cs-2chan-full.jpg
:align: center
:width: 50.0%
CircuitSetup Split Single Phase Real Time Whole House Energy Meter.
The `CircuitSetup Expandable 6 Channel Energy Meter <https://circuitsetup.us/index.php/product/expandable-6-channel-esp32-energy-meter/>`__ can read 6 current channels and 2 voltage channels at a time. This board has 2 atm90e32 ICs and requires 2 sensors to be configured in ESPHome.
.. figure:: images/atm90e32-cs-6chan-full.jpg
:align: center
:width: 50.0%
CircuitSetup Expandable 6 Channel ESP32 Energy Meter Main Board.
.. code-block:: yaml
# Example configuration entry for split single phase meter
spi:
clk_pin: 18
miso_pin: 19
mosi_pin: 23
sensor:
- platform: atm90e32
cs_pin: 5
phase_a:
voltage:
name: "EMON Line Voltage A"
current:
name: "EMON CT1 Current"
power:
name: "EMON Active Power CT1"
reactive_power:
name: "EMON Reactive Power CT1"
power_factor:
name: "EMON Power Factor CT1"
gain_voltage: 41820
gain_ct: 25498
phase_b:
current:
name: "EMON CT2 Current"
power:
name: "EMON Active Power CT2"
reactive_power:
name: "EMON Reactive Power CT2"
power_factor:
name: "EMON Power Factor CT2"
gain_voltage: 41820
gain_ct: 25498
frequency:
name: "EMON Line Frequency"
chip_temperature:
name: "EMON Chip Temperature"
line_frequency: 50Hz
gain_pga: 2X
update_interval: 60s
Configuration variables:
------------------------
- **cs_pin** (**Required**, :ref:`Pin Schema <config-pin_schema>`): The pin CS is connected to. For the 6 channel meter main board, this will always be 5 and 4. For the add-on boards a jumper can be selected for each CS pin, but default to 0 and 16.
- **line_frequency** (**Required**, string): The AC line frequency of the supply voltage. One of ``50Hz``, ``60Hz``.
- **phase_a** (*Optional*): The configuration options for the 1st phase.
- **voltage** (*Optional*): Use the voltage value of this phase in V (RMS).
All options from :ref:`Sensor <config-sensor>`.
- **current** (*Optional*): Use the current value of this phase in amperes. All options from
:ref:`Sensor <config-sensor>`.
- **power** (*Optional*): Use the power value on this phase in watts. All options from
:ref:`Sensor <config-sensor>`.
- **reactive_power** (*Optional*): Use the reactive power value on this phase. All options from
:ref:`Sensor <config-sensor>`.
- **power_factor** (*Optional*): Use the power factor value on this phase. All options from
:ref:`Sensor <config-sensor>`.
- **gain_voltage** (*Optional*, int): Voltage gain to scale the low voltage AC power pack to household mains feed.
Defaults to ``41820``.
- **gain_ct** (*Optional*, int): CT clamp calibration for this phase.
Defaults to ``25498``.
- **phase_b** (*Optional*): The configuration options for the 2nd phase. Same options as 1st phase.
- **phase_c** (*Optional*): The configuration options for the 3rd phase. Same options as 1st phase.
- **frequency** (*Optional*): Use the frequenycy value calculated by the meter. All options from
:ref:`Sensor <config-sensor>`.
- **chip_temperature** (*Optional*): Use the chip temperature value. All options from
:ref:`Sensor <config-sensor>`.
- **gain_pga** (*Optional*, string): The gain for the CT clamp, ``2X`` for 100A, ``4X`` for 100A - 200A. One of ``1X``, ``2X``, ``4X``.
Defaults to ``2X`` which is suitable for the popular SCT-013-000 clamp.
- **update_interval** (*Optional*, :ref:`config-time`): The interval to check the sensor. Defaults to ``60s``.
- **spi_id** (*Optional*, :ref:`config-id`): Manually specify the ID of the :ref:`SPI Component <spi>` if you want
to use multiple SPI buses.
Calibration
-----------
This sensor needs calibration to show correct values. The default gain configuration is set to use the `SCT-013-000 <https://amzn.to/2E0KVvo>`__
current transformers with gain_pga set to 2X, and the `Jameco Reliapro 9v AC transformer <https://amzn.to/2XcWJjI>`__.
A load which uses a known amount of current can be used to calibrate. For a more accurate calibration use a
`Kill-A-Watt <https://amzn.to/2TXT7jx>`__ meter or similar, mains voltages can fluctuate depending on grid load.
Voltage
^^^^^^^
Use the expected mains voltage for your region 110V/230V or plug in the Kill-A-Watt and select voltage. See what
value the ATM90E32 sensor reports for voltage. To adjust the sensor use the calculation:
``New gain_voltage = (your voltage reading / ESPHome voltage reading) * existing gain_voltage value``
Update **gain_voltage** for all phases in your ESPHome yaml, recompile and upload. Repeat as necessary.
Current
^^^^^^^
Switch on the current load and see what value the ATM90E32 sensor reports for
current on the selected phase. Using the known or measured current adjust the
sensor using calculation:
``New gain_ct = (your current reading / ESPHome current reading) * existing gain_ct value``
Update **gain_ct** for the phase in your ESPHome yaml, recompile and upload. Repeat as necessary.
It is possible that the two identical CT current sensors will have different
**gain_ct** numbers due to variances in manufacturing, although it will be
small. The current calibration can be done once and used on all sensors or
repeated for each one.
Additional Examples
-------------------
.. code-block:: yaml
# Example CircuitSetup 6-channel entry
spi:
clk_pin: 18
miso_pin: 19
mosi_pin: 23
sensor:
- platform: atm90e32
cs_pin: 5
phase_a:
voltage:
name: "EMON Line Voltage A"
current:
name: "EMON CT1 Current"
power:
name: "EMON Active Power CT1"
gain_voltage: 47660
gain_ct: 12577
phase_b:
current:
name: "EMON CT2 Current"
power:
name: "EMON Active Power CT2"
gain_voltage: 47660
gain_ct: 12577
phase_c:
current:
name: "EMON CT3 Current"
power:
name: "EMON Active Power CT3"
gain_voltage: 47660
gain_ct: 12577
frequency:
name: "EMON Line Frequency"
line_frequency: 50Hz
gain_pga: 2X
update_interval: 60s
- platform: atm90e32
cs_pin: 4
phase_a:
current:
name: "EMON CT4 Current"
power:
name: "EMON Active Power CT4"
gain_voltage: 47660
gain_ct: 12577
phase_b:
current:
name: "EMON CT5 Current"
power:
name: "EMON Active Power CT5"
gain_voltage: 47660
gain_ct: 12577
phase_c:
current:
name: "EMON CT6 Current"
power:
name: "EMON Active Power CT6"
gain_voltage: 47660
gain_ct: 12577
line_frequency: 50Hz
gain_pga: 2X
update_interval: 60s
.. code-block:: yaml
# Example CircuitSetup 6-channel without jumpers jp9-jp11 joined
# power is calculated in a template
substitutions:
disp_name: 6C
update_time: 10s
current_cal: '32498'
spi:
clk_pin: 18
miso_pin: 19
mosi_pin: 23
sensor:
- platform: atm90e32
cs_pin: 5
phase_a:
voltage:
name: ${disp_name} Volts A
id: ic1Volts
accuracy_decimals: 1
current:
name: ${disp_name} CT1 Amps
id: ct1Amps
gain_voltage: 7305
gain_ct: ${current_cal}
phase_b:
current:
name: ${disp_name} CT2 Amps
id: ct2Amps
gain_ct: ${current_cal}
phase_c:
current:
name: ${disp_name} CT3 Amps
id: ct3Amps
gain_ct: ${current_cal}
frequency:
name: ${disp_name} Freq A
line_frequency: 60Hz
gain_pga: 2X
update_interval: ${update_time}
- platform: atm90e32
cs_pin: 4
phase_a:
voltage:
name: ${disp_name} Volts B
id: ic2Volts
accuracy_decimals: 1
current:
name: ${disp_name} CT4 Amps
id: ct4Amps
gain_voltage: 7305
gain_ct: ${current_cal}
phase_b:
current:
name: ${disp_name} CT5 Amps
id: ct5Amps
gain_ct: ${current_cal}
phase_c:
current:
name: ${disp_name} CT6 Amps
id: ct6Amps
gain_ct: ${current_cal}
frequency:
name: ${disp_name} Freq B
line_frequency: 60Hz
gain_pga: 2X
update_interval: ${update_time}
#Watts per channel
- platform: template
name: ${disp_name} CT1 Watts
id: ct1Watts
lambda: return id(ct1Amps).state * id(ic1Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
- platform: template
name: ${disp_name} CT2 Watts
id: ct2Watts
lambda: return id(ct2Amps).state * id(ic1Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
- platform: template
name: ${disp_name} CT3 Watts
id: ct3Watts
lambda: return id(ct3Amps).state * id(ic1Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
- platform: template
name: ${disp_name} CT4 Watts
id: ct4Watts
lambda: return id(ct4Amps).state * id(ic2Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
- platform: template
name: ${disp_name} CT5 Watts
id: ct5Watts
lambda: return id(ct5Amps).state * id(ic2Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
- platform: template
name: ${disp_name} CT6 Watts
id: ct6Watts
lambda: return id(ct6Amps).state * id(ic2Volts).state;
accuracy_decimals: 0
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
#Total Amps
- platform: template
name: ${disp_name} Total Amps
id: totalAmps
lambda: return id(ct1Amps).state + id(ct2Amps).state + id(ct3Amps).state + id(ct4Amps).state + id(ct5Amps).state + id(ct6Amps).state ;
accuracy_decimals: 2
unit_of_measurement: A
icon: "mdi:flash"
update_interval: ${update_time}
#Total Watts
- platform: template
name: ${disp_name} Total Watts
id: totalWatts
lambda: return id(totalAmps).state * id(ic1Volts).state;
accuracy_decimals: 1
unit_of_measurement: W
icon: "mdi:flash-circle"
update_interval: ${update_time}
#kWh
- platform: total_daily_energy
name: ${disp_name} Total kWh
power_id: totalWatts
filters:
- multiply: 0.001
unit_of_measurement: kWh
See Also
--------
- :ref:`sensor-filters`
- :apiref:`atm90e32/atm90e32.h`
- :ghedit:`Edit`