PowerCalc is a custom component for Home Assistant to estimate the power consumption (as virtual meters) of lights, fans, smart speakers and other devices, which don't have a built-in power meter. The consumption of light entities is calculated using different strategies to estimate the power usage by looking at brightness, hue/saturation and color temperature. For other entities a generic calculation can be applied, based on the attributes relevant for that entity.
See supported models for the listing of supported devices which can be added out of the box without any further configuration.
- Installation
- Setup power sensors
- Configuration
- Calculation modes
- Daily fixed energy
- Sensor naming
- Setting up for energy dashboard
- Advanced features
- Light model library
- Debug logging
This integration is part of the default HACS repository. Just click "Explore and add repository" to install
Copy custom_components/powercalc
into your Home Assistant config
directory.
- Restart HA
- Add the following entry to
configuration.yaml
:
powercalc:
- Restart HA final time
Powercalc has a built-in library of more than 190 power profiles. Currently, this exists mostly of lights. These profiles have been measured and provided by users. See supported models for the listing of supported devices.
Powercalc scans your HA instance for entities which are supported for automatic configuration. It does that based on the manufacturer and model information known in HA. After following the installation steps above and restarting HA power and energy sensors should appear. When this is not the case please check the logs for any errors, you can also enable debug logging to get more details about the discovery routine.
When your appliance is not supported out of the box (or you want to have more control) you have extensive options for manual configuration. These are explained below.
Note: Manually configuring an entity will override an auto discovered entity
To manually add virtual sensors for your devices you have to add some configuration to configuration.yaml
, or you can use the GUI configuration ("Settings" -> "Devices & Services" -> "Add integration" -> "Powercalc") and follow the instructions.
Additionally, some settings can be applied on global level and will apply to all your virtual power sensors. This global configuration cannot be configured using the GUI yet.
After changing the configuration you need to restart HA to get your power sensors to appear. This is only necessary for changes in the YAML files.
For each entity you want to create a virtual power sensor for you'll need to add an entry in configuration.yaml
or use the GUI config flow. Not all configuration params listed below are available in the GUI, when you want to use the "advanced" options you need to use YAML configuration.
Each virtual power sensor have it's own configuration possibilities.
They are as follows:
Name | Type | Requirement | Description |
---|---|---|---|
entity_id | string | Required | HA entity ID. The id of the device you want your power sensor for |
unique_id | string | Optional | Powercalc tries to get a unique_id from the source entity by default. When the source entity does not have a unique_id you can configure one yourself. This allows you to change the name, area etc from the GUI. You can use for example https://www.uuidgenerator.net/ to generate a unique one |
manufacturer | string | Optional | Manufacturer, most of the time this can be automatically discovered |
model | string | Optional | Model id, most of the time this can be automatically discovered |
standby_power | float | Optional | Supply the wattage when the device is off |
unavailable_power | float | Optional | Supply the wattage when the device has unavailable state. When not specified standby_power will be used, or 0. |
disable_standby_power | boolean | Optional | Set to true to not show any power consumption when the device is standby |
name | string | Optional | Override the name |
create_energy_sensor | boolean | Optional | Set to disable/enable energy sensor creation. When set this will override global setting create_energy_sensors |
create_utility_meters | boolean | Optional | Set to disable/enable utility meter creation. When set this will override global setting create_utility_meters |
utility_meter_types | list | Optional | Define which cycles you want to create utility meters for. See cycle. This will override global setting utility_meter_types |
utility_meter_offset | string | Optional | Define the offset for utility meters. See offset. |
utility_meter_tariffs | list | Optional | Define different tariffs. See tariffs. |
custom_model_directory | string | Optional | Directory for a custom light model. Relative from the config directory |
power_sensor_category | string | Optional | Category for the created power sensor. See generic-properties. |
power_sensor_naming | string | Optional | Change the name (and id) of the sensors. Use the {} placeholder for the entity name of your appliance. When set this will override global setting power_sensor_naming |
energy_sensor_category | string | Optional | Category for the created energy sensor. See generic-properties. |
energy_sensor_naming | string | Optional | Change the name (and id) of the sensors. Use the {} placeholder for the entity name of your appliance. When set this will override global setting energy_sensor_naming |
energy_integration_method | string | Optional | Integration method for the energy sensor. See HA docs |
energy_sensor_unit_prefix | string | Optional | Unit prefix for the energy sensor. See HA docs. Set to none for to create a Wh sensor |
mode | string | Optional | Calculation mode, one of lut , linear , fixed . The default mode is lut |
multiply_factor | float | Optional | Multiplies the calculated power by this number. See multiply factor |
multiply_factor_standby | boolean | Optional | When set to true the multiply_factor will also be applied to the standby power |
fixed | object | Optional | Fixed mode options |
linear | object | Optional | Linear mode options |
wled | object | Optional | WLED mode options |
entities | list | Optional | Makes it possible to add multiple entities at once in one powercalc entry. Also enable possibility to create group sensors automatically. See multiple entities and grouping |
create_group | string | Optional | This setting is only applicable when you also use entities setting or include . Define a group name here. See multiple entities and grouping |
hide_members | boolean | Optional | Hide all group members in HA GUI, only applicable when create_group is also defined. |
include | object | Optional | Use this in combination with create_group to automatically include entities from a certain area, group or template. See Include entities |
power_sensor_id | string | Optional | Entity id of an existing power sensor. This can be used to let powercalc create energy sensors and utility meters. This will create no virtual power sensor. |
energy_sensor_id | string | Optional | Entity id of an existing energy sensor. Mostly used in conjunction with power_sensor_id . |
ignore_unavailable_state | boolean | Optional | Set this to true when you want the power sensor to display a value (unavailable_power , standby_power or 0) regardless of whether the source entity is available. The can be useful for example on a TV which state can become unavailable when it is set to off. |
calculation_enabled_condition | template | Optional | The configured power calculation strategy will only be executed when this template results in True, otherwise the power sensor will display 0 |
Minimalistic example creating two power sensors:
sensor:
- platform: powercalc
entity_id: light.hallway
- platform: powercalc
entity_id: light.living_room
This will add a power sensors with the entity ids sensor.hallway_power
and sensor.living_room_power
to your installation.
See Calculation modes for all possible sensor configurations.
All these settings are completely optional. You can skip this section if you don't need any advanced configuration.
Name | Type | Requirement | Default | Description |
---|---|---|---|---|
enable_autodiscovery | boolean | Optional | true | Whether you want powercalc to automatically setup power sensors for supported models in your HA instance. |
force_update_frequency | string | Optional | 00:10:00 | Interval at which the sensor state is updated, even when the power value stays the same. Format HH:MM:SS |
create_energy_sensors | boolean | Optional | true | Let the component automatically create energy sensors (kWh) for every power sensor |
power_sensor_naming | string | Optional | {} power | Change the name of the sensors. Use the {} placeholder for the entity name of your appliance. This will also change the entity_id of your sensor |
power_sensor_friendly_naming | string | Optional | Change the friendly name of the sensors, Use {} placehorder for the original entity name. |
|
power_sensor_category | string | Optional | Category for the created power sensors. See generic-properties. | |
energy_sensor_naming | string | Optional | {} energy | Change the name of the sensors. Use the {} placeholder for the entity name of your appliance. This will also change the entity_id of your sensor |
energy_sensor_friendly_naming | string | Optional | Change the friendly name of the sensors, Use {} placehorder for the original entity name. |
|
energy_sensor_category | string | Optional | Category for the created energy sensors. See generic-properties. | |
create_utility_meters | boolean | Optional | false | Set to true to automatically create utility meters of your energy sensors. See utility_meters |
utility_meter_types | list | Optional | daily, weekly, monthly | Define which cycles you want to create utility meters for. See cycle |
utility_meter_tariffs | list | Optional | Define different tariffs. See tariffs. | |
energy_integration_method | string | Optional | trapezoid | Integration method for the energy sensor. See HA docs |
energy_sensor_precision | numeric | Optional | 4 | Number of decimals you want for the energy sensors. See HA docs |
energy_sensor_unit_prefix | string | Optional | Unit prefix for the energy sensor. See HA docs. Set to none for to create a Wh sensor |
|
create_domain_groups | list | Optional | Create grouped power sensor aggregating all powercalc sensors of given domains, see Group sensors per domain | |
ignore_unavailable_state | boolean | Optional | false | Set to true when you want the power sensor to display a value (0 or standby_power ) regardless of whether the source entity is available. |
disable_extended_attributes | boolean | Optional | false | Set to true to disable all extra attributes powercalc adds to the power, energy and group entity states. This will help keep the database size small especially when you have a lot of powercalc sensors and frequent update ratio |
Example:
powercalc:
force_update_frequency: 00:01:00 #Each minute
power_sensor_naming: "{} Powersensor"
create_energy_sensors: false
To calculate estimated power consumption different modes are supported, they are as follows:
Supported domain: light
This is the most accurate mode. For a lot of light models measurements are taken using smart plugs. All this data is saved into CSV files. When you have the LUT mode activated the current brightness/hue/saturation of the light will be checked and closest matching line will be looked up in the CSV.
- Supported models for LUT mode
- LUT file structure
For most lights the device information in HA will supply the manufacturer and model correctly, so you only need to supply the entity_id
.
sensor:
- platform: powercalc
entity_id: light.livingroom_floorlamp
When the correct manufacturer and model could somehow not be discovered from HA, you can supply these manually. You can also use this option to force using a certain LUT.
sensor:
- platform: powercalc
entity_id: light.livingroom_floorlamp
manufacturer: signify
model: LCT010
Some light models (currently LIFX brand) require you to refer a so called "sub LUT" directory, because they have different power charasteristics based on some information not known to HA. For example LIFX BR30 Night Vision light has some infrared mode which can be set in the LIFX app. To load the LUT file for a infrared setting of 25 you can use the following configuration. You will need to lookup the available sub LUT's in the powercalc data directory.
sensor:
- platform: powercalc
entity_id: light.lifx_nighvision
manufacturer: lifx
model: LIFX BR30 Night Vision/infrared_25
Supported domains: light
, fan
, media_player
The linear mode can be used for dimmable devices which don't have a lookup table available. You need to supply the min and max power draw yourself, by either looking at the datasheet or measuring yourself with a smart plug / power meter. Power consumpion is calculated by ratio. So when you have your fan running at 50% speed and define watt range 2 - 6, than the estimated consumption will be 4 watt.
Name | Type | Requirement | Description |
---|---|---|---|
attribute | string | Optional | State attribute to use for the linear range. When not supplied will be brightness for lights, percentage for fans and volume for media players. |
min_power | float | Optional | Power usage for lowest brightness level |
max_power | float | Optional | Power usage for highest brightness level |
calibrate | string | Optional | Calibration values |
gamma_curve | float | Optional | Apply a gamma correction, for example 2.8 |
sensor:
- platform: powercalc
entity_id: light.livingroom_floorlamp
linear:
min_power: 0.5
max_power: 8
Note: defining only
min_power
andmax_power
is only allowed for light and fan entities, when you are using another entity (for example asensor
orinput_number
) you must use the calibrate mode.
With the calibrate
setting you can supply more than one power value for multiple brightness/percentage levels.
This allows for a more accurate estimation because not all lights are straight linear.
Also you can use this calibration table for other entities than lights and fans, to supply the state values and matching power values.
sensor:
- platform: powercalc
entity_id: light.livingroom_floorlamp
linear:
calibrate:
- 1 -> 0.3
- 10 -> 1.25
- 50 -> 3.50
- 100 -> 6.8
- 255 -> 15.3
Note: For lights the supplied values must be in brightness range 1-255, when you select 1 in lovelace UI slider this is actually brightness level 3. For fan speeds the range is 1-100 (percentage)
Configuration with an sensor (sensor.heater_modulation
) which supplies a percentage value (1-100):
sensor:
- platform: powercalc
entity_id: sensor.heater_modulation
name: Heater
linear:
calibrate:
- 1 -> 200
- 100 -> 1650
You could also use this to setup a power profile for your robot vacuum cleaner, which only consumes power when it is docked into the charching port. You need to use this in conjunction with the calculation_enabled_condition
to only activate the power calculation when the device is docked.
- platform: powercalc
entity_id: vacuum.my_robot_cleaner
calculation_enabled_condition: "{{ is_state('vacuum.my_robot_cleaner', 'docked') }}"
linear:
attribute: battery_level
calibrate:
- 1 -> 20
- 79 -> 20
- 80 -> 15
- 99 -> 8
- 100 -> 1.5
Supported domains: light
, fan
, humidifier
, switch
, binary_sensor
, device_tracker
, remote
, media_player
, input_boolean
, input_number
, input_select
, sensor
, climate
, vacuum
, water_heater
When you have an appliance which only can be set on and off you can use this mode. You need to supply a single watt value in the configuration which will be used when the device is ON
Name | Type | Requirement | Description |
---|---|---|---|
power | float | Optional | Power usage when the appliance is turned on (in watt). Can also be a template |
states_power | dict | Optional | Power usage per entity state. Values can also be a template |
sensor:
- platform: powercalc
entity_id: light.nondimmabled_bulb
fixed:
power: 20
sensor:
- platform: powercalc
entity_id: light.bathroom
fixed:
power: "{{states('input_number.bathroom_watts')}}"
When you don't have a source entity or helper (ex. input_boolean
) to bind on and you just want the power sensor to reflect the template value you can use sensor.dummy
as the entity_id
sensor:
- platform: powercalc
entity_id: sensor.dummy
fixed:
power: "{{states('input_number.bathroom_watts')}}"
The states_power
setting allows you to specify a power per entity state. This can be useful for example on Sonos devices which have a different power consumption in different states.
sensor:
- platform: powercalc
entity_id: media_player.sonos_living
fixed:
states_power:
playing: 8.3
paused: 2.25
idle: 1.5
You can also use state attributes. Use the |
delimiter to seperate the attribute and value. Here is en example:
sensor:
- platform: powercalc
entity_id: media_player.sonos_living
fixed:
power: 12
states_power:
media_content_id|Spotify: 5
media_content_id|Youtube: 10
When no match is found in states_power
lookup than the configured power
will be considered.
Supported domains: light
You can use WLED strategy for light strips which are controlled by WLED. WLED calculates estimated current based on brightness levels and the microcontroller (ESP) used. Powercalc asks to input the voltage on which the lightstrip is running and optionally a power factor. Based on these factors the wattage is calculated.
Name | Type | Requirement | Default | Description |
---|---|---|---|---|
voltage | float | Required | Voltage for the lightstrip | |
power_factor | float | Optional | 0.9 | Power factor, between 0.1 and 1.0 |
sensor:
- platform: powercalc
entity_id: light.wled_lightstrip
wled:
voltage: 5
sensor:
- platform: powercalc
entity_id: light.livingroom_floorlamp
linear:
min_power: 0.5
max_power: 8
standby_power: 0.2
name: My amazing power meter
Available from v0.13 an higher
Sometimes you want to keep track of energy usage of individual devices which are not managed by Home Assistant. When you know the energy consumption in kWh or W powercalc can make it possible to create an energy sensor (which can also be used in the energy dashboard). This can be helpful for devices which are always on and have a relatively fixed power draw. For example an IP camera, intercom, Google nest, Alexa, network switches etc.
Name | Type | Requirement | Default | Description |
---|---|---|---|---|
value | float | Required | Value either in watts or kWh. Can also be a template | |
unit_of_measurement | string | Optional | kWh | kWh or W |
on_time | period | Optional | 24:00:00 | How long the device is on per day. Only applies when unit_of_measurement is set to W . Format HH:MM:SS |
update_frequency | integer | Optional | 1800 | Seconds between each increase in kWh |
This will add 0.05 kWh per day to the energy sensor called "IP camera upstairs"
sensor:
- platform: powercalc
name: IP camera upstairs
daily_fixed_energy:
value: 0.05
Or define in watts, with an optional on time (which is 24 hour a day by default).
sensor:
- platform: powercalc
name: Intercom
daily_fixed_energy:
value: 21
unit_of_measurement: W
on_time: 12:00:00
This will simulate the device using 21 watts for 12 hours a day. The energy sensor will increase by 0.252 kWh a day.
Let's assume you have a source sensor light.patio
with name "Patio".
Powercalc will create the following sensors by default.
- sensor.patio_power (Patio power)
- sensor.patio_energy (Patio energy)
Utility meters will use the energy name as a base and suffix with
_daily
,_weekly
,_monthly
To change the default suffixes _power
and _energy
you can use the power_sensor_naming
and energy_sensor_naming
options.
The following configuration:
powercalc:
energy_sensor_naming: "{} kWh consumed"
will create:
- sensor.patio_power (Patio power)
- sensor.patio_kwh_consumed (Patio kWh consumed)
This option allows you to separately change only the name (shown in GUI), it will not have effect on the entity id
powercalc:
energy_sensor_naming: "{} kwh"
energy_sensor_friendly_naming: "{} Energy consumed
will create:
- sensor.patio_kwh (Patio Energy consumed)
You can also change the sensor name with the name
option
sensor:
- platform: powercalc
entity_id: light.patio
name: Patio Light
will create:
- sensor.patio_light_power (Patio light power)
- sensor.patio_light_energy (Patio light energy)
If you want to use the virtual power sensors with the new energy integration, you have to create an energy sensor which utilizes the power of the powercalc sensor. Starting from v0.4 of powercalc it will automatically create energy sensors for you by default. No need for any custom configuration. These energy sensors then can be selected in the energy dashboard.
You can disable the automatic creation of energy sensors with the option create_energy_sensors
in your configuration (see global configuration).
Note: It can take some time for the energy sensors to appear in the energy dashboard, sometimes more than an hour. Just have a little patience ;-)
Powercalc provides multiple possibilities to create aggregate group sensors, which sums the power of multiple individual power sensors into one sensor.
- Group sensors per domain
- Manually defining groups by configuration
Available from v0.19 and higher
Powercalc makes it easy to create a group sensors for all entities of a given domain with the create_domain_groups
option. For example let's assume you want group sensors for all your lights and media players you can use the following configuration.
powercalc:
create_domain_groups:
- light
- media_player
Available from v0.8 and higher
entities
will allow you to multiple power sensors in one powercalc
sensor entry.
create_group
will also create a group summing all the underlying entities. Which can directly be used in energy dashboard.
Each entry under entities
can use the same configuration as when defined directly under sensor
sensor:
- platform: powercalc
create_group: All hallway lights
entities:
- entity_id: light.hallway
- entity_id: light.living_room
linear:
min_power: 0.5
max_power: 8
This will create the following entities:
- sensor.hallway_power
- sensor.hallway_energy
- sensor.living_room_power
- sensor.living_room_energy
- sensor.all_hallway_lights_power (group sensor)
- sensor.all_hallway_lights_energy (group sensor)
Nesting groups
Available from v0.15 and higher
You can also nest groups, this makes it possible to add an entity to multiple groups.
sensor:
- platform: powercalc
create_group: All lights
entities:
- entity_id: light.a
- entity_id: light.b
- create_group: Upstairs lights
entities:
- entity_id: light.c
- create_group: Bedroom Bob lights
entities:
- entity_id: light.d
Each group will have power sensors created for the following lights:
- All lights:
light.a
,light.b
,light.c
,light.d
- Upstairs lights:
light.c
,light.d
- Bedroom Bob lights:
light.d
Note: a maximum nesting level of 5 groups is allowed!
Powercalc provides several methods to automatically include a bunch of entities in a group with the include
option.
Note: only entities will be included which are in the supported models list (these can be auto configured). You can combine
include
andentities
to extend the group with custom configured entities.
Include area
Available from v0.12 and higher
sensor:
- platform: powercalc
create_group: Outdoor
include:
area: outdoor
This can also be mixed with the entities
option, to add or override entities to the group. i.e.
sensor:
- platform: powercalc
create_group: Outdoor
include:
area: outdoor
entities:
- entity_id: light.frontdoor
fixed:
power: 100
Include group
Available from v0.14 and higher
Includes entities from a Home Assistant group or light group
sensor:
- platform: powercalc
create_group: Livingroom lights
include:
group: group.livingroom_lights
Include template
Available from v0.14 and higher
sensor:
- platform: powercalc
create_group: All indoor lights
include:
template: {{expand('group.all_indoor_lights')|map(attribute='entity_id')|list}}
Include domain
Available from v0.19 and higher
sensor:
- platform: powercalc
create_group: All lights
include:
domain: light
This feature allows you to multiply the calculated power.
This can be useful in the following use cases:
- You have a bunch of similar lights which you control as a group and want a single power sensor.
- You are using a LED strip from the LUT models, but you have extended or shortened it.
Let's assume you have a combination of 4 GU10 spots in your ceiling in a light group light.livingroom_spots
- platform: powercalc
entity_id: light.livingroom_spots
multiply_factor: 4
This will add the power sensor sensor.livingroom_spots_power
and the measured power will be multiplied by 4, as the original measurements are for 1 spot.
By default the multiply factor will NOT be applied to the standby power, you can set the multiply_factor_standby
to do this.
- platform: powercalc
entity_id: light.livingroom_spots
multiply_factor: 4
multiply_factor_standby: true
Note: a multiply_factor lower than 1 will decrease the power. For example 0.5 will half the power.
The energy sensors created by the component will keep increasing the total kWh, and never reset. When you want to know the energy consumed the last 24 hours, or last month you can use the utility_meter component of Home Assistant. Powercalc allows you to automatically create utility meters for all your powercalc sensors with a single line of configuration.
powercalc:
create_utility_meters: true
By default utility meters are created for daily
, weekly
, monthly
cycles.
You can change this behaviour with the utility_meter_types
configuration option.
powercalc:
create_utility_meters: true
utility_meter_types:
- daily
- yearly
The utility meters have the same name as your energy sensor, but are extended by the meter cycle.
Assume you have a light light.floorlamp_livingroom
, than you should have the following sensors created:
sensor.floorlamp_livingroom_power
sensor.floorlamp_livingroom_energy
sensor.floorlamp_livingroom_energy_daily
sensor.floorlamp_livingroom_energy_weekly
sensor.floorlamp_livingroom_energy_monthly
Available from v0.14 and higher
Use the following configuration to use an existing power sensor and let powercalc create the energy sensors and utility meters for it:
- platform: powercalc
entity_id: light.toilet
power_sensor_id: sensor.toilet_light_power
Available from v0.23 and higher
Powercalc provides a service powercalc.reset_energy
which you can call to reset energy sensors to 0 kWh.
You can call this service from the GUI (Developer tools -> Services)
The component ships with predefined light measurements for some light models. This library will keep extending by the effort of community users.
These models are located in config/custom_components/powercalc/data
directory.
You can also define your own models in config/powercalc-custom-models
directory, when a manufacturer/model exists in this directory this will take precedence over the default data directory.
Each light model has it's own subdirectory {manufacturer}/{modelid}
. i.e. signify/LCT010
Every model MUST contain a model.json
file which defines the supported calculation modes and other configuration.
See the json schema how the file must be structured or the examples below.
When LUT mode is supported also CSV lookup files must be provided.
Example lut mode:
{
"name": "Hue White and Color Ambiance A19 E26 (Gen 5)",
"standby_power": 0.4,
"supported_modes": [
"lut"
],
"measure_method": "script",
"measure_device": "Shelly Plug S"
}
Example linear mode
{
"name": "Hue Go",
"supported_modes": [
"linear"
],
"standby_power": 0.2,
"linear_config": {
"min_power": 0,
"max_power": 6
},
"measure_method": "manual",
"measure_device": "From manufacturer specifications"
}
To calculate power consumption a lookup is done into CSV data files.
Depending on the supported color modes of the light the integration expects one or more CSV files here:
- hs.csv.gz (hue/saturation, colored lamps)
- color_temp.csv.gz (color temperature)
- brightness.csv.gz (brightness only lights)
Some lights support two color modes (both hs and color_temp), so there must be two CSV files.
The files are gzipped to keep the repository footprint small, and installation fast but gzipping files is not mandatory.
Example:
- signify
- LCT010
- model.json
- hs.csv.gz
- color_temp.csv.gz
- The file MUST contain a header row.
- The data rows in the CSV files MUST have the following column order:
hs.csv
bri,hue,sat,watt
color_temp.csv
bri,mired,watt
brightness.csv
bri,watt
Ranges:
- brightness (0-255)
- hue (0-65535)
- saturation (0-255)
- mired (0-500) min value depending on min mired value of the light model
New files are created by taking measurements using a smartplug (i.e. Shelly plug) and changing the light to all kind of different variations using the Hue API or Home Assistant API.
The tooling is available at utils/measure
.
The script supports several smartplugs with power monitoring.
See the README for more information.
See the list of supported lights which don't need any manual configuration
Yeelights may not autodetect by default, see here for additional steps to configure them.
Add the following to configuration.yaml:
logger:
default: warning
logs:
custom_components.powercalc: debug