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A full featured Thermostat for Home Assistant: presets, window, motion, presence and overpowering management

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Tip

Tip This thermostat integration aims to drastically simplify your automations around climate management. Because all classical events in climate are natively handled by the thermostat (nobody at home ?, activity detected in a room ?, window open ?, power shedding ?), you don't have to build over complicated scripts and automations to manage your climates ;-).

This custom component for Home Assistant is an upgrade and is a complete rewrite of the component "Awesome thermostat" (see Github) with addition of features.

New News

  • Release 5.2: Added a central_mode allowing all VTherms to be controlled centrally #158.
  • Release 5.1: Limitation of the values sent to the valves and the temperature sent to the underlying climate.
  • Release 5.0: Added a central configuration allowing the sharing of attributes that can be shared #239.
  • Release 4.3: Added an auto-fan mode for the over_climate type allowing ventilation to be activated if the temperature difference is significant #223.
  • Release 4.2: The calculation of the slope of the temperature curve is now done in °/hour and no longer in °/min #242. Correction of automatic detection of openings by adding smoothing of the temperature curve.
Others releases
  • Release 4.1: Added an Expert regulation mode in which the user can specify their own auto-regulation parameters instead of using the pre-programmed ones #194.
  • Release 4.0: Added the support of Versatile Thermostat UI Card. See Versatile Thermostat UI Card. Added a Slow regulation mode for slow latency heating devices #168. Change the way the power is calculated in case of VTherm with multi-underlying equipements #146. Added the support of AC and Heat for VTherm over switch alse #144
  • Release 3.8: Added a self-regulation function for over climate thermostats whose regulation is done by the underlying climate. See Self-regulation and #129. Added the possibility of inverting the command for an over switch thermostat to address installations with pilot wire and diode #124.
  • Release 3.7: Addition of the Versatile Thermostat type over valve to control a TRV valve directly or any other dimmer type equipment for heating. Regulation is then done directly by acting on the opening percentage of the underlying entity: 0 the valve is cut off, 100: the valve is fully opened. See #131. Added a function allowing the bypass of opening detection #138. Added Slovak language
  • Release 3.6: Added the motion_off_delay parameter to improve motion management #116, #128. Added AC (air conditioning) mode for a VTherm over switch. Preparing the Github project to facilitate contributions #127
  • Release 3.5: Multiple thermostats when using "thermostat over another thermostat" mode #113
  • Release 3.4: bug fixes and expose preset temperatures for AC mode #103
  • Release 3.3: add the Air Conditionned mode (AC). This feature allow to use the eventual AC mode of your underlying climate entity. You have to check the "Use AC mode" checkbox in configuration and give preset temperature value for AC mode and AC mode when absent if absence is configured
  • Release 3.2: add the ability to control multiple switches from the same thermostat. In this mode, the switches are triggered with a delay to minimize the power required at one time (we minimize the recovery periods). See Configuration
  • Release 3.1: added detection of open windows/doors by temperature drop. This new function makes it possible to automatically stop a radiator when the temperature drops suddenly. See Auto mode
  • Major release 3.0: addition of thermostat equipment and associated sensors (binary and non-binary). Much closer to the Home Assistant philosophy, you now have direct access to the energy consumed by the radiator controlled by the thermostat and many other sensors that will be useful in your automations and dashboard.
  • release 2.3: addition of the power and energy measurement of the radiator controlled by the thermostat.
  • release 2.2: addition of a safety function allowing a radiator not to be left heating forever in the event of a thermometer failure
  • major release 2.0: addition of the "over climate" thermostat allowing you to transform any thermostat into a Versatile Thermostat and add all the functions of the latter.

Major changes in version 5.0

New

You can now define a central configuration which will allow you to share certain attributes on all your VTherms (or only part of them). To use this possibility, you must:

  1. Create a VTherm of type “Central Configuration”,
  2. Enter the attributes of this central configuration

To then use it in the other VTherms, you must reconfigure them and whenever possible check the "Use central configuration" box. This check box appears in all attribute groups that can use central configuration: main attributes, TPI, openings, movement, power, presence and advanced parameters.

The configurable attributes in the central configuration are listed here: Parameter summary.

When changing the central configuration, all VTherms will be reloaded to take these changes into account.

Consequently, the entire configuration phase of a VTherm has been profoundly modified to be able to use the central configuration or overload the values of the central configuration with values specific to the VTherm being configured.

Note: the VTherm configuration screenshots have not been updated.

Thanks for the beer buymecoffee

Many thanks to @salabur, @pvince83, @bergoglio, @EPicLURcher, @ecolorado66, @Kriss1670, @maia, @f.maymil, @moutte69, @Jerome, @Gunnar M, @Greg.o, @John Burgess, @abyssmal, @capinfo26, @Helge, @MattG, @MattG, @Mexx62, @Someone, @Lajull for the beers. It's very nice and encourages me to continue!

When to use / not use

This thermostat can control 3 types of equipment:

  1. a radiator that only operates in on/off mode (called ``thermostat_over_switch```). The minimum configuration necessary to use this type thermostat is:
    1. equipment such as a radiator (a ``switch``` or equivalent),
    2. a temperature probe for the room (or an input_number),
    3. an outdoor temperature sensor (consider weather integration if you don't have one)
  2. another thermostat which has its own operating modes (named ``thermostat_over_climate```). For this type of thermostat the minimum configuration requires:
    1. equipment - such as air conditioning, a thermostatic valve - which is controlled by its own ``climate'' type entity,
  3. equipment which can take a value from 0 to 100% (called thermostat_over_valve). At 0 the heating is cut off, 100% it is fully opened. This type allows you to control a thermostatic valve (see Shelly valve) which exposes an entity of type number. allowing you to directly control the opening of the valve. Versatile Thermostat regulates the room temperature by adjusting the opening percentage, using the interior and exterior temperature sensors using the TPI algorithm described below.

The thermostat_over_climate type allows you to add all the functionality provided by VersatileThermostat to your existing equipment. The climate VersatileThermostat entity will control your existing climate entity, turning it off if the windows are open, switching it to Eco mode if no one is present, etc. See here. For this type of thermostat, any heating cycles are controlled by the underlying climate entity and not by the Versatile Thermostat itself. An optional self-regulation function allows the Versatile Thermostat to adjust the temperature given as a setpoint to the underlying in order to reach the setpoint.

Installations with pilot wire and activation diode benefit from an option which allows the on/off control of the underlying radiator to be reversed. To do this, use the over switch type and check the command inversion option.

Incompatibilities

Some TRV type thermostats are known to be incompatible with the Versatile Thermostat. This is the case for the following valves:

  1. Danfoss POPP valves with temperature feedback. It is impossible to turn off this valve and it self-regulates, causing conflicts with the VTherm,
  2. "Homematic" (and possible Homematic IP) thermostats are known to have problems with Versatile Thermostats because of limitations of the underlying RF protocol. This problem especially occurs when trying to control several Homematic thermostats at once in one Versatile Thermostat instance. In order to reduce duty cycle load, you may e.g. group thermostats with Homematic-specific procedures (e.g. using a wall thermostat) and let Versatile Thermostat only control the wall thermostat directly. Another option is to control only one thermostat and propagate the changes in HVAC mode and temperature by an automation.
  3. Thermostat of type Heatzy which doesn't supports the set_temperature command.
  4. Thermostats of type Rointe tends to awake alone even if VTherm turns it off. Others functions works fine.

Why another thermostat implementation ?

This component named Versatile thermostat manage the following use cases :

  • Configuration through standard integration GUI (using Config Entry flow),
  • Full uses of presets mode,
  • Unset the preset mode when the temperature is manually defined on a thermostat,
  • Turn off/on a thermostat when a door or windows is opened/closed after a certain delay,
  • Change preset when an activity is detected or not in a room for a defined time,
  • Use a TPI (Time Proportional Interval) algorithm thank's to [Argonaute] algorithm ,
  • Add power shedding management or regulation to avoid exceeding a defined total power. When max power is exceeded, a hidden 'power' preset is set on the climate entity. When power goes below the max, the previous preset is restored.
  • Add home presence management. This feature allows you to dynamically change the temperature of preset considering a occupancy sensor of your home.
  • Add services to interact with the thermostat from others integration: you can force the presence / un-presence using a service, and you can dynamically change the temperature of the presets and change dynamically the safety parameters.
  • Add sensors to see the internal states of the thermostat,
  • Centralized control of all Versatile Thermostats to stop them all, switch them all to frost protection, force them into Heating mode (winter), force them into Cooling mode (summer).

How to install this incredible Versatile Thermostat ?

HACS installation (recommended)

  1. Install HACS. That way you get updates automatically.
  2. The Versatile Thermostat integration is now offered directly from the HACF interface (integration tab).
  3. search and install "Versatile Thermostat" in HACS and click install.
  4. Restart Home Assistant,
  5. Then you can add an Versatile Thermostat integration in the integration page. You add as many Versatile Thermostat that you need (typically one per heater that should be managed)

Manual installation

  1. Using the tool of choice open the directory (folder) for your HA configuration (where you find configuration.yaml).
  2. If you do not have a custom_components directory (folder) there, you need to create it.
  3. In the custom_components directory (folder) create a new folder called versatile_thermostat.
  4. Download all the files from the custom_components/versatile_thermostat/ directory (folder) in this repository.
  5. Place the files you downloaded in the new directory (folder) you created.
  6. Restart Home Assistant
  7. Configure new Versatile Thermostat integration

Configuration

-- VTherm = Versatile Thermostat in the remainder of this document --

Tip Notes

Three ways to configure VTherms are available:

  1. Each Versatile Thermostat is completely independently configured. Choose this option if you do not want to have any central configuration or management.
  2. Some aspects are configured centrally. This allows e.g. define the min/max temperature, open window detection, etc. at the level of a single central instance. For each VTherm you configure, you can then choose to use the central configuration or override it with custom settings.
  3. In addition to this centralized configuration, all VTherms can be controlled by a single entity of type select. This function is named central_mode. This allows you to stop / start / freeze / etc. all VTherms at once. For each VTherm, the user indicates whether he is affected by this central_mode.

Creation of a new Versatile Thermostat

Click on Add integration button in the integration page image

The configuration can be change through the same interface. Simply select the thermostat to change, hit "Configure" and you will be able to change some parameters or configuration.

Then follow the configurations steps as follow:

Minimal configuration update

image

image

Give the main mandatory attributes:

  1. a name (will be the name of the integration and also the name of the climate entity)
  2. the thermostat type thermostat_over_switch to control a radiator controlled by a switch or thermostat_over_climate to control another thermostat, or thermostat_over_valve Cf. [above](# why-a-new-thermostat-implementation)
  3. a temperature sensor entity identifier which gives the temperature of the room in which the radiator is installed,
  4. a temperature sensor entity giving the outside temperature. If you don't have an external sensor, you can use local weather integration
  5. a cycle duration in minutes. On each cycle, the heater will cycle on and then off for a calculated time to reach the target temperature (see preset below). In over_climate mode, the cycle is only used to carry out basic controls but does not directly regulate the temperature. It's the underlying climate that does it,
  6. minimum and maximum thermostat temperatures,
  7. the power of the l'équipement which will activate the power and energy sensors of the device,
  8. the possibility of controlling the thermostat centrally. Cf centralized control,
  9. the list of features that will be used for this thermostat. Depending on your choices, the following configuration screens will appear or not.

Tip Notes

  1. With the thermostat_over_switch type, calculation are done at each cycle. So in case of conditions change, you will have to wait for the next cycle to see a change. For this reason, the cycle should not be too long. 5 min is a good value,
  2. if the cycle is too short, the heater could never reach the target temperature. For the storage radiator for example it will be used unnecessarily.

Select the driven entity

Depending on your choice of thermostat type, you will need to choose one or more switch, climate or number type entities. Only entities compatible with the type are presented.

Tip How to choose the type The choice of type is important. Even if it is always possible to modify it afterwards via the configuration HMI, it is preferable to ask yourself the following few questions:

  1. what type of equipment am I going to pilot? In order, here is what to do:
    1. if you have a thermostatic valve (TRV) that can be controlled in Home Assistant via a number type entity (for example a Shelly TRV), choose the over_valve type. It is the most direct type and which ensures the best regulation,
    2. if you have an electric radiator (with or without pilot wire) and a switch type entity allows you to turn it on or off, then the over_switch type is preferable. Regulation will be done by the Versatile Thermostat according to the temperature measured by your thermometer, where you have placed it,
    3. in all other cases, use the over_climate mode. You keep your original climate entity and the Versatile Thermostat "only" controls the on/off and the target temperature of your original thermostat. Regulation is done by your original thermostat in this case. This mode is particularly suitable for all-in-one reversible air conditioning systems whose exposure in Home Assistant is limited to a climate type entity.
  2. what type of regulation do I want? If the controlled equipment has its own regulation mechanism (air conditioning, certain TRV valve) and this regulation works well, opt for an ``over_climate``` It is possible to choose an over switch thermostat which controls air conditioning by checking the "AC Mode" box. In this case, only the cooling mode will be visible.

For a thermostat_over_switch type thermostat

image The algorithm to use is currently limited to TPI is available. See algorithm. If several type entities are configured, the thermostat shifts the activations in order to minimize the number of switches active at a time t. This allows for better power distribution since each radiator will turn on in turn. Example of synchronized triggering: image

It is possible to choose an over switch thermostat which controls air conditioning by checking the "AC Mode" box. In this case, only the cooling mode will be visible.

If your equipment is controlled by a pilot wire with a diode, you will certainly need to check the "Invert Check" box. It allows you to set the switch to On when you need to turn the equipment off and to Off when you need to turn it on.

For a thermostat of type thermostat_over_climate:

image

It is possible to choose an over climate thermostat which controls reversible air conditioning by checking the “AC Mode” box. In this case, depending on the equipment ordered, you will have access to heating and/or cooling.

Self-regulation

Since release 3.8, you have the possibility to activate the self-regulation function. This function allows VersatileThermostat to adapt the temperature setpoint given to the underlying climate so that the room temperature actually reaches the setpoint. To do this, the VersatileThermostat calculates an offset based on the following information:

  1. the current difference between the actual temperature and the set temperature,
  2. the accumulation of past differences,
  3. the difference between the outside temperature and the setpoint

These three pieces of information are combined to calculate the offset which will be added to the current setpoint and sent to the underlying climate.

The self-regulation function is configured with:

  1. a degree of regulation:
    1. Light - for low self-regulation needs. In this mode, the maximum offset will be 1.5°,
    2. Medium - for average self-regulation. A maximum offset of 2° is possible in this mode,
    3. Strong - for a strong need for self-regulation. The maximum offset is 3° in this mode and the auto-regulation will react strongly to temperature changes.
  2. A self-regulation threshold: value below which new regulation will not be applied. Let us imagine that at a time t, the offset is 2°. If in the next calculation, the offset is 2.4°, it will not be applied. It will only be applied that the difference between 2 offsets will be at least equal to this threshold,
  3. Minimum period between 2 self-regulation changes: this number, expressed in minutes, indicates the duration between 2 regulation changes.

These three parameters make it possible to modulate the regulation and avoid multiplying the regulation sendings. Some equipment such as TRVs and boilers do not like the temperature setpoint to be changed too often.

Tip Implementation tip

  1. Do not start self-regulation straight away. Watch how the natural regulation of your equipment works. If you notice that the set temperature is not reached or that it is taking too long to be reached, start the regulation,
  2. First start with a slight self-regulation and keep both parameters at their default values. Wait a few days and check if the situation has improved,
  3. If this is not sufficient, switch to Medium self-regulation, wait for stabilization,
  4. If this is still not sufficient, switch to Strong self-regulation,
  5. If it is still not good, you will have to switch to expert mode to be able to finely adjust the regulation parameters. See below.

Self-regulation consists of forcing the equipment to go further by forcing its set temperature regularly. Its consumption can therefore be increased, as well as its wear.

Self-regulation in Expert mode

In Expert mode you can finely adjust the auto-regulation parameters to achieve your objectives and optimize as best as possible. The algorithm calculates the difference between the setpoint and the actual temperature of the room. This discrepancy is called error. The adjustable parameters are as follows:

  1. kp: the factor applied to the raw error,
  2. ki: the factor applied to the accumulation of errors,
  3. k_ext: the factor applied to the difference between the interior temperature and the exterior temperature,
  4. offset_max: the maximum correction (offset) that the regulation can apply,
  5. stabilization_threshold: a stabilization threshold which, when reached by the error, resets the accumulation of errors to 0,
  6. accumulated_error_threshold: the maximum for error accumulation.

For tuning, these observations must be taken into account:

  1. kp * error will give the offset linked to the raw error. This offset is directly proportional to the error and will be 0 when the target is reached,
  2. the accumulation of the error makes it possible to correct the stabilization of the curve while there remains an error. The error accumulates and the offset therefore gradually increases which should eventually stabilize at the target temperature. For this fundamental parameter to have an effect it must not be too small. An average value is 30
  3. ki * accumulated_error_threshold will give the maximum offset linked to the accumulation of the error,
  4. k_ext allows a correction to be applied immediately (without waiting for errors to accumulate) when the outside temperature is very different from the target temperature. If the stabilization is done too high when the temperature differences are significant, it is because this parameter is too high. It should be possible to cancel completely to let the first 2 offsets take place

The pre-programmed values are as follows:

Slow régulation :

kp: 0.2  # 20% of the current internal regulation offset are caused by the current difference of target temperature and room temperature
ki: 0.8 / 288.0  # 80% of the current internal regulation offset are caused by the average offset of the past 24 hours
k_ext: 1.0 / 25.0  # this will add 1°C to the offset when it's 25°C colder outdoor than indoor
offset_max: 2.0  # limit to a final offset of -2°C to +2°C
stabilization_threshold: 0.0  # this needs to be disabled as otherwise the long term accumulated error will always be reset when the temp briefly crosses from/to below/above the target
accumulated_error_threshold: 2.0 * 288  # this allows up to 2°C long term offset in both directions

Light régulation :

kp: 0.2
ki: 0.05
k_ext: 0.05
offset_max: 1.5
stabilization_threshold: 0.1
accumulated_error_threshold: 10

Medium régulation :

kp: 0.3
ki: 0.05
k_ext: 0.1
offset_max: 2
stabilization_threshold: 0.1
accumulated_error_threshold: 20

Strong régulation :

"""Strong parameters for regulation
A set of parameters which doesn't take into account the external temp
and concentrate to internal temp error + accumulated error.
This should work for cold external conditions which else generates
high external_offset"""

kp: 0.4
ki: 0.08
k_ext: 0.0
offset_max: 5
stabilization_threshold: 0.1
accumulated_error_threshold: 50

To use Expert mode you must declare the values you want to use for each of these parameters in your configuration.yaml in the following form:

versatile_thermostat:
     auto_regulation_expert:
         kp: 0.4
         ki: 0.08
         k_ext: 0.0
         offset_max: 5
         stabilization_threshold: 0.1
         accumulated_error_threshold: 50

and of course, configure the VTherm's self-regulation mode in Expert mode. All VTherms in Expert mode will use these same settings.

For the changes to be taken into account, you must either completely restart Home Assistant or just the Versatile Thermostat integration (Dev tools / Yaml / reloading the configuration / Versatile Thermostat).

Auto-fan mode

This mode introduced in 4.3 makes it possible to force the use of ventilation if the temperature difference is significant. In fact, by activating ventilation, distribution occurs more quickly, which saves time in reaching the target temperature. You can choose which ventilation you want to activate between the following settings: Low, Medium, High, Turbo.

Obviously your underlying equipment must be equipped with ventilation and be controllable for this to work. If your equipment does not include Turbo mode, Fortemode will be used as a replacement. Once the temperature difference becomes low again, the ventilation will go into a "normal" mode which depends on your equipment, namely (in order):Silence (mute), Auto (auto), Low (low)`. The first value that is possible for your equipment will be chosen.

For a thermostat of type thermostat_over_valve:

image You can choose up to domain entity number or ìnput_number which will control the valves. The algorithm to use is currently limited to TPI is available. See algorithm.

It is possible to choose an over valve thermostat which controls air conditioning by checking the "AC Mode" box. In this case, only the cooling mode will be visible.

Configure the TPI algorithm coefficients

click on 'Validate' on the previous page, and if you choose a over_switch or over_valve thermostat and you will get there: image

For more informations on the TPI algorithm and tuned please refer to algorithm.

Configure the preset temperature

Click on 'Validate' on the previous page and you will get there: image

The preset mode allows you to pre-configurate targeted temperature. Used in conjonction with Scheduler (see scheduler you will have a powerfull and simple way to optimize the temperature vs electrical consumption of your hous. Preset handled are the following :

  • Eco : device is running an energy-saving mode
  • Comfort : device is in comfort mode
  • Boost : device turn all valve full up

If AC mode is used, you will also be able to configure temperatures when the equipment is in cooling mode.

None is always added in the list of modes, as it is a way to not use the presets modes but a manual temperature instead.

Tip Notes

  1. Changing manually the target temperature, set the preset to None (no preset). This way you can always set a target temperature even if no preset are available.
  2. standard Away preset is a hidden preset which is not directly selectable. Versatile Thermostat uses the presence management or movement management to set automatically and dynamically the target temperature depending on a presence in the home or an activity in the room. See presence management.
  3. if you uses the power shedding management, you will see a hidden preset named power. The heater preset is set to power when overpowering conditions are encountered and shedding is active for this heater. See power management.
  4. if you uses the advanced configuration you will see the preset set to safety if the temperature could not be retrieved after a certain delay
  5. ff you don't want to use the preseet, give 0 as temperature. The preset will then been ignored and will not displayed in the front component

Configure the doors/windows turning on/off the thermostats

You must have chosen the With opening detection feature on the first page to arrive on this page. The detection of openings can be done in 2 ways:

  1. either with a sensor placed on the opening (sensor mode),
  2. either by detecting a sudden drop in temperature (auto mode)

The sensor mode

In sensor mode, you must fill in the following information: image

  1. an entity ID of a window/door sensor. It should be a binary_sensor or an input_boolean. The state of the entity must be 'on' when the window is open or 'off' when it is closed
  2. a delay in seconds before any change. This allows a window to be opened quickly without stopping the heating.

Auto mode

In auto mode, the configuration is as follows: image

  1. a detection threshold in degrees per minute. When the temperature drops below this threshold, the thermostat will turn off. The lower this value, the faster the detection will be (in return for a risk of false positives),
  2. an end of detection threshold in degrees per minute. When the temperature drop goes above this value, the thermostat will go back to the previous mode (mode and preset),
  3. maximum detection time. Beyond this time, the thermostat will return to its previous mode and preset even if the temperature continues to drop.

To set the thresholds it is advisable to start with the reference values ​​and adjust the detection thresholds. A few tries gave me the following values ​​(for a desktop):

  • detection threshold: 0.05°C/min
  • non-detection threshold: 0 °C/min
  • maximum duration: 60 min.

A new "slope" sensor has been added for all thermostats. It gives the slope of the temperature curve in °C/min (or °K/min). This slope is smoothed and filtered to avoid aberrant values ​​from the thermometers which would interfere with the measurement. image

To properly adjust it is advisable to display on the same historical graph the temperature curve and the slope of the curve (the "slope"): image

And that's all ! your thermostat will turn off when the windows are open and turn back on when closed.

Tip Notes

  1. If you want to use multiple door/window sensors to automate your thermostat, just create a group with the usual behavior (https://www.home-assistant.io/integrations/binary_sensor.group/)
  2. If you don't have a window/door sensor in your room, just leave the sensor entity id blank,
  3. Only one mode is allowed. You cannot configure a thermostat with a sensor and automatic detection. The 2 modes may contradict each other, it is not possible to have the 2 modes at the same time,
  4. It is not recommended to use the automatic mode for equipment subject to frequent and normal temperature variations (corridors, open areas, ...)

Configure the activity mode or motion detection

If you choose the Motion management feature, lick on 'Validate' on the previous page and you will get there: image

We will now see how to configure the new Activity mode. What we need:

  • a motion sensor. The entity id of a motion sensor. Motion sensor states should be 'on' (motion detected) or 'off' (no motion detected)

  • a motion delay (in seconds) duration defining how long we wait for motion confirmation before considering the motion

  • a end of motion delay (in seconds) duration defining how long we wait for end of motion confirmation before considering the end of motion

  • a target "motion" preset. We will used the temperature of this preset when an activity is detected.

  • a target "no motion" preset. We will used the temperature of this second preset when no activity is detected.

  • we have a room with a thermostat set to activity mode, the "movement" mode chosen is comfort (21.5°C), the "no movement" mode chosen is Eco (18.5°C) and the movement delay is 30 sec during detection and 5 minutes at the end of detection.

  • the room has been empty for a while (no activity detected), the temperature of this room is 18.5°

  • someone enters the room, activity is detected if movement is present for at least 30 seconds. The temperature then rises to 21.5°

  • if the movement is present for less than 30 seconds (rapid passage), the temperature remains at 18.5°,

  • imagine that the temperature has risen to 21.5°, when the person leaves the room, after 5 minutes the temperature is reduced to 18.5°.

  • if the person returns before 5 minutes, the temperature remains at 21.5°

For this to work, the climate thermostat should be in Activity preset mode.

Tip Notes

  1. Be aware that as for the others preset modes, Activity will only be proposed if it's correctly configure. In other words, the 4 configuration keys have to be set if you want to see Activity in home assistant Interface

Configure the power management

If you choose the Power management feature, click on 'Validate' on the previous page and you will get there: image

This feature allows you to regulate the power consumption of your radiators. Known as shedding, this feature allows you to limit the electrical power consumption of your heater if overpowering conditions are detected. Give a sensor to the current power consumption of your house, a sensor to the max power that should not be exceeded, the power consumption of your heaters linked to the VTherm (in the first step of the configuration) and the algorithm will not start a radiator if the max power will be exceeded after radiator starts.

Note that all power values should have the same units (kW or W for example). This allows you to change the max power along time using a Scheduler or whatever you like.

Tip Notes

  1. When shedding is encountered, the heater is set to the preset named power. This is a hidden preset, you cannot select it manually.
  2. I use this to avoid exceeded the limit of my electrical power contract when an electrical vehicle is charging. This makes a kind of auto-regulation.
  3. Always keep a margin, because max power can be briefly exceeded while waiting for the next cycle calculation typically or by not regulated equipement.
  4. If you don't want to use this feature, just leave the entities id empty
  5. If you control several heaters, the power consumption of your heater setup should be the sum of the power.

Configure presence or occupancy

If selected on the first page, this feature allows you to dynamically change the temperature of all configured thermostat presets when no one is home or when someone comes home. To do this, you must configure the temperature that will be used for each preset when presence is disabled. When the presence sensor turns off, these temperatures will be used. When it turns back on, the "normal" temperature configured for the preset is used. See preset management. To configure presence, complete this form:

image

To do this, you must configure:

  1. An occupancy sensor whose state must be 'on' or 'home' if someone is present or 'off' or 'not_home' otherwise,
  2. The temperature used in Eco predefined in the event of absence,
  3. The temperature used in Comfort preset in case of absence,
  4. The temperature used in Boost preset in case of absence

If AC mode is used, you will also be able to configure temperatures when the equipment is in cooling mode.

ATTENTION: groups of people do not function as a presence sensor. They are not recognized as a presence sensor. You must use a template as described here Using a group of people as a presence sensor.

Tip Notes

  1. the change in temperature is immediate and is reflected on the front shutter. The calculation will take into account the new target temperature at the next calculation of the cycle,
  2. you can use the person.xxxx direct sensor or a group of Home Assistant sensors. The presence sensor manages the on or home states as present and the off or not_home states as absent.

Advanced configuration

Those parameters allows to fine tune the thermostat. The advanced configuration form is the following:

image

The first delay (minimal_activation_delay_sec) in sec in the minimum delay acceptable for turning on the heater. When calculation gives a power on delay below this value, the heater will stays off.

The second delay (security_delay_min) is the maximal delay between two temperature measure before setting the preset to safety and turning off the thermostat. If the temperature sensor is no more giving temperature measures, the thermostat and heater will turns off after this delay and the preset of the thermostat will be set to safety. This is useful to avoid overheating is the battery of your temperature sensor is too low.

The third parameter (security_min_on_percent) is the minimum value of on_percent below which the safety preset will not be activated. This parameter makes it possible not to put a thermostat in safety, if the controlled radiator does not heat sufficiently. Setting this parameter to 0.00 will trigger the safety preset regardless of the last heating setpoint, conversely 1.00 will never trigger the safety preset (which amounts to disabling the function).

The fourth parameter (security_default_on_percent) is the on_percent value that will be used when the thermostat enters safety mode. If you put 0 then the thermostat will be cut off when it goes into safety mode, putting 0.2% for example allows you to keep a little heating (20% in this case), even in mode safety. It avoids finding your home totally frozen during a thermometer failure.

See example tuning for common tuning examples

Tip Notes

  1. When the temperature sensor comes to life and returns the temperatures, the preset will be restored to its previous value,
  2. Attention, two temperatures are needed: internal temperature and external temperature and each must give the temperature, otherwise the thermostat will be in "safety" preset,
  3. A service is available that allows you to set the 3 safety parameters. This can be used to adapt the safety function to your use.
  4. For natural usage, the security_default_on_percent should be less than security_min_on_percent,
  5. Thermostat of type thermostat_over_climate are not concerned by the safety feature.

Centralized control

Since release 5.2, if you have defined a centralized configuration, you have a new entity named select.central_mode which allows you to control all VTherms with a single action. For a VTherm to be centrally controllable, its configuration attribute named use_central_mode must be true.

This entity is presented in the form of a list of choices which contains the following choices:

  1. Auto: the 'normal' mode in which each VTherm behaves as in previous versions,
  2. Stooped: all VTherms are turned off (hvac_off),
  3. Heat only: all VTherms are put in heating mode when this mode is supported by the VTherm, otherwise it is stopped,
  4. Cool only: all VTherms are put in cooling mode when this mode is supported by the VTherm, otherwise it is stopped,
  5. Frost protection: all VTherms are put in frost protection preset when this preset is supported by the VTherm, otherwise it is stopped.

It is therefore possible to control all VTherms (only those explicitly designated) with a single control. Example rendering:

central_mode

Parameters synthesis

Paramètre Libellé "over switch" "over climate" "over valve" "central configuration"
name Name X X X -
thermostat_type Thermostat type X X X -
temperature_sensor_entity_id Temperature sensor entity id X X (self-regulation) X -
external_temperature_sensor_entity_id External temperature sensor entity id X X (self-regulation) X X
cycle_min Cycle duration (minutes) X X X -
temp_min Minimal temperature allowed X X X X
temp_max Maximal temperature allowed X X X X
device_power Total device power X X X -
use_central_mode Allow the centralized control X X X -
use_window_feature Use window detection X X X -
use_motion_feature Use motion detection X X X -
use_power_feature Use power management X X X -
use_presence_feature Use presence detection X X X -
heater_entity1_id 1rst heater switch X - - -
heater_entity2_id 2nd heater switch X - - -
heater_entity3_id 3rd heater switch X - - -
heater_entity4_id 4th heater switch X - - -
proportional_function Algorithm X - X -
climate_entity1_id 1rst underlying climate - X - -
climate_entity2_id 2nd underlying climate - X - -
climate_entity3_id 3rd underlying climate - X - -
climate_entity4_id 4th underlying climate - X - -
valve_entity1_id 1rst underlying valve - - X -
valve_entity2_id 2nd underlying valve - - X -
valve_entity3_id 3rd underlying valve - - X -
valve_entity4_id 4th underlying valve - - X -
ac_mode Use the Air Conditioning (AC) mode X X X -
tpi_coef_int Coefficient to use for internal temperature delta X - X X
tpi_coef_ext Coefficient to use for external temperature delta X - X X
frost_temp Temperature in frost protection preset X X X X
eco_temp Temperature in Eco preset X X X X
comfort_temp Temperature in Comfort preset X X X X
boost_temp Temperature in Boost preset X X X X
eco_ac_temp Temperature in Eco preset for AC mode X X X X
comfort_ac_temp Temperature in Comfort preset for AC mode X X X X
boost_ac_temp Temperature in Boost preset for AC mode X X X X
window_sensor_entity_id Window sensor entity id X X X -
window_delay Window sensor delay (seconds) X X X X
window_auto_open_threshold Temperature decrease threshold for automatic window open detection (in °/min) X X X X
window_auto_close_threshold Temperature increase threshold for end of automatic detection (in °/min) X X X X
window_auto_max_duration Maximum duration of automatic window open detection (in min) X X X X
motion_sensor_entity_id Motion sensor entity id X X X -
motion_delay Delay before considering the motion (seconds) X X X X
motion_off_delay Delay before considering the end of motion (seconds) X X X X
motion_preset Preset to use when motion is detected X X X X
no_motion_preset Preset to use when no motion is detected X X X X
power_sensor_entity_id Power sensor entity id X X X X
max_power_sensor_entity_id Max power sensor entity id X X X X
power_temp Temperature for Power shedding X X X X
presence_sensor_entity_id Presence sensor entity id X X X X
frost_away_temp Temperature in Frost protection preset when no presence X X X X
eco_away_temp Temperature in Eco preset when no presence X X X X
comfort_away_temp Temperature in Comfort preset when no presence X X X X
boost_away_temp Temperature in Boost preset when no presence X X X X
eco_ac_away_temp Temperature in Eco preset when no presence in AC mode X X X X
comfort_ac_away_temp Temperature in Comfort preset when no presence in AC mode X X X X
boost_ac_away_temp Temperature in Boost preset when no presence in AC mode X X X X
minimal_activation_delay Minimal activation delay X - X X
security_delay_min Safety delay (in minutes) X - X X
security_min_on_percent Minimal power percent to enable safety mode X - X X
security_default_on_percent Power percent to use in safety mode X - X X
auto_regulation_mode Le mode d'auto-régulation - X - -
auto_regulation_dtemp La seuil d'auto-régulation - X - -
auto_regulation_period_min La période minimale d'auto-régulation - X - -
inverse_switch_command Inverse the switch command (for pilot wire switch) X - - -
``auto_fan_mode` Auto fan mode - X - -

Examples tuning

Electrical heater

  • cycle: between 5 and 10 minutes,
  • minimal_activation_delay_sec: 30 seconds

Central heating (gaz or fuel heating system)

  • cycle: between 30 and 60 min,
  • minimal_activation_delay_sec: 300 seconds (because of the response time)

Temperature sensor will battery

  • security_delay_min: 60 min (because these sensors are lazy)
  • security_min_on_percent: 0.5 (50% - we go to the safety preset if the radiator was heating more than 50% of the time)
  • security_default_on_percent: 0.1 (10% - in preset safety, we keep a heating background 20% of the time)

These settings should be understood as follows:

If the thermometer no longer sends the temperature for 1 hour and the heating percentage (on_percent) was greater than 50%, then this heating percentage is reduced to 10%.

It's up to you to adapt these settings to your case!

What is important is not to take too many risks with these parameters: suppose you are away for a long period, that the batteries of your thermometer reach the end of their life, your radiator will heat up 10% of the time for the whole the duration of the outage.

Versatile Thermostat allows you to be notified when an event of this type occurs. Set up the alerts that go well as soon as you use this thermostat. See (#notifications)

Reactive temperature sensor (on mains)

  • security_delay_min: 15min
  • security_min_on_percent: 0.7 (70% - we go to the safety preset if the radiator was heating more than 70% of the time)
  • security_default_on_percent: 0.25 (25% - in preset safety, we keep a heating background 25% of the time)

My preset configuration

This is just an example of how I use the preset. It up to you to adapt to your configuration but it can be useful to understand how it works. Frost: 10 °C Eco: 17 °C Comfort: 19 °C Boost: 20 °C

When presence if off: Frost: 10 °C Eco: 16.5 °C Comfort: 17 °C Boost: 18 °C

Motion detector in my office is set to use Boost when motion is detected and Eco if not.

Algorithm

This integration uses a proportional algorithm. A Proportional algorithm is useful to avoid the oscillation around the target temperature. This algorithm is based on a cycle which alternate heating and stop heating. The proportion of heating vs not heating is determined by the difference between the temperature and the target temperature. Bigger the difference is and bigger is the proportion of heating inside the cycle.

This algorithm make the temperature converge and stop oscillating.

TPI algorithm

The TPI algorithm consist in the calculation at each cycle of a percentage of On state vs Off state for the heater using the target temperature, the current temperature in the room and the current external temperature. This algorithm is therefore only valid for Versatile Thermostats which regulate: over_switch and over_valve.

The percentage is calculated with this formula:

on_percent = coef_int * (target temperature - current temperature) + coef_ext * (target temperature - external temperature)
Then make 0 <= on_percent <= 1

Defaults values for coef_int and coef_ext are respectively: 0.6 and 0.01. Those defaults values are suitable for a standard well isolated room.

To tune those coefficients keep in mind that:

  1. if target temperature is not reach after stable situation, you have to augment the coef_ext (the on_percent is too low),
  2. if target temperature is exceeded after stable situation, you have to decrease the coef_ext (the on_percent is too high),
  3. if reaching the target temperature is too slow, you can increase the coef_int to give more power to the heater,
  4. if reaching the target temperature is too fast and some oscillations appears around the target, you can decrease the coef_int to give less power to the heater

In type over_valve the on_percent is reduced to a value between 0 and 100% and is used directly to control the opening of the valve.

See some situations at examples.

Sensors

With the thermostat are available sensors that allow you to view the alerts and the internal status of the thermostat. They are available in the entities of the device associated with the thermostat:

image

In order, there are:

  1. the main climate thermostat command entity,
  2. the energy consumed by the thermostat (value which continuously increases),
  3. the time of receipt of the last outside temperature,
  4. the time of receipt of the last indoor temperature,
  5. the average power of the device over the cycle (for TPIs only),
  6. the time spent in the off state in the cycle (TPI only),
  7. the time spent in the on state in the cycle (TPI only),
  8. load shedding status,
  9. cycle power percentage (TPI only),
  10. presence status (if presence management is configured),
  11. safety status,
  12. opening status (if opening management is configured),
  13. motion status (if motion management is configured),
  14. the valve opening percentage (for the over_valve type)

To color the sensors, add these lines and customize them as needed, in your configuration.yaml:

frontend:
  themes:
    versatile_thermostat_theme:
      state-binary_sensor-safety-on-color: "#FF0B0B"
      state-binary_sensor-power-on-color: "#FF0B0B"
      state-binary_sensor-window-on-color: "rgb(156, 39, 176)"
      state-binary_sensor-motion-on-color: "rgb(156, 39, 176)"
      state-binary_sensor-presence-on-color: "lightgreen"
      state-binary_sensor-running-on-color: "orange"

and choose the versatile_thermostat_theme theme in the panel configuration. You will get something that will look like this:

image

Services

This custom implementation offers some specific services to facilitate integration with others Home Assisstant components.

Force the presence / occupancy

This service allows you to force the presence status independantly of the presence sensor. This can be useful if you want to manage the presence through a service and not through a sensor. For example, you could use your alarm to force the absence when it is switched on.

The code to call this service is the following:

service: versatile_thermostat.set_presence
data:
    presence: "off"
target:
    entity_id: climate.my_thermostat

Change the temperature of presets

This services is useful if you want to dynamically change the preset temperature. Instead of changing preset, some use-case need to change the temperature of the preset. So you can keep the Scheduler unchanged to manage the preset and adjust the temperature of the preset. If the changed preset is currently selectionned, the modification of the target temperature is immediate and will be taken into account at the next calculation cycle.

You can change the one or the both temperature (when present or when absent) of each preset.

Use the following code the set the temperature of the preset:

service: versatile_thermostat.set_preset_temperature
data:
    preset: boost
    temperature: 17.8
    temperature_away: 15
target:
    entity_id: climate.my_thermostat

Or to change the preset of the AC mode, add _ac to the preset name like this:

service: versatile_thermostat.set_preset_temperature
data:
    preset: boost_ac
    temperature: 25
    temperature_away: 30
target:
    entity_id: climate.my_thermostat

Tip Notes - after a restart the preset are resetted to the configured temperature. If you want your change to be permanent you should modify the temperature preset into the confguration of the integration.

Change safety settings

This service is used to dynamically modify the safety parameters described here Advanced configuration. If the thermostat is in safety mode the new settings are applied immediately.

To change the safety settings use the following code:

service : thermostat_polyvalent.set_security
data:
    min_on_percent: "0.5"
    default_on_percent: "0.1"
    delay_min: 60
target:
    entity_id : climate.my_thermostat

ByPass Window Check

This service is used to bypass the window check implemented to stop thermostat when an open window is detected. When set to true window event won't have any effect on the thermostat, when set back to false it will make sure to disable the thermostat if window is still open.

To change the bypass setting use the following code:

service : thermostat_polyvalent.set_window_bypass
data:
    window_bypass: true
target:
    entity_id : climate.my_thermostat

Events

Significant thermostat events are notified via the message bus. The notified events are as follows:

  • versatile_thermostat_security_event: a thermostat enters or exits the safety preset
  • versatile_thermostat_power_event: a thermostat enters or exits the power preset
  • versatile_thermostat_temperature_event: one or both temperature measurements of a thermostat have not been updated for more than security_delay_min minutes
  • versatile_thermostat_hvac_mode_event: the thermostat is on or off. This event is also broadcast when the thermostat starts up
  • versatile_thermostat_preset_event: a new preset is selected on the thermostat. This event is also broadcast when the thermostat starts up

If you have followed correctly, when a thermostat goes into safety mode, 3 events are triggered:

  1. versatile_thermostat_temperature_event to indicate that a thermometer has become unresponsive,
  2. versatile_thermostat_preset_event to indicate the switch to safety preset,
  3. versatile_thermostat_hvac_mode_event to indicate the possible extinction of the thermostat

Each event carries the key values ​​of the event (temperatures, current preset, current power, etc.) as well as the states of the thermostat.

You can very easily capture its events in an automation, for example to notify users.

Custom attributes

To tune the algorithm you have access to all context seen and calculted by the thermostat through dedicated attributes. You can see (and use) those attributes in the "Development tools / states" HMI of HA. Enter your thermostat and you will see something like this: image

Custom attributes are the following:

Attribute Meaning
hvac_modes The list of modes supported by the thermostat
min_temp The minimal temperature
max_temp The maximal temperature
preset_modes The presets visible for this thermostat. Hidden presets are not showed here
current_temperature The current temperature as reported by the sensor
temperature The target temperature
hvac_action The action currently running by the heater. Can be idle, heating
preset_mode The currently selected preset. Can be one of the 'preset_modes' or a hidden preset like power
[eco/comfort/boost]_temp The temperature configured for the preset xxx
[eco/comfort/boost]_away_temp The temperature configured for the preset xxx when presence is off or not_home
power_temp The temperature used when shedding is detected
on_percent The percentage on calculated by the TPI algorithm
on_time_sec The On period in sec. Should be on_percent * cycle_min
off_time_sec The Off period in sec. Should be (1 - on_percent) * cycle_min
cycle_min The calculation cycle in minutes
function The algorithm used for cycle calculation
tpi_coef_int The coef_int of the TPI algorithm
tpi_coef_ext The coef_ext of the TPI algorithm
saved_preset_mode The last preset used before automatic switch of the preset
saved_target_temp The last temperature used before automatic switching
window_state The last known state of the window sensor. None if window is not configured
window_bypass_state True if the bypass of the window detection is activated
motion_state The last known state of the motion sensor. None if motion is not configured
overpowering_state The last known state of the overpowering sensor. None if power management is not configured
presence_state The last known state of the presence sensor. None if presence management is not configured
security_delay_min The delay before setting the safety mode when temperature sensor are off
security_min_on_percent The minimal on_percent below which safety preset won't be trigger
security_default_on_percent The on_percent used when thermostat is in safety
last_temperature_datetime The date and time in ISO8866 format of the last internal temperature reception
last_ext_temperature_datetime The date and time in ISO8866 format of the last external temperature reception
security_state The safety state. true or false
minimal_activation_delay_sec The minimal activation delay in seconds
last_update_datetime The date and time in ISO8866 format of this state
friendly_name The name of the thermostat
supported_features A combination of all features supported by this thermostat. See official climate integration documentation for more informations
valve_open_percent The opening percentage of the valve
regulated_target_temperature The self-regulated target temperature calculated
is_inversed True if the command is inversed (pilot wire with diode)
is_controlled_by_central_mode True if the VTherm can be centrally controlled
last_central_mode The last central mode used (None if the VTherm is not centrally controlled)

Some results

Convergence of temperature to target configured by preset: image

Cycle of on/off calculated by the integration: image

Coef_int too high (oscillations around the target) image

Algorithm calculation evolution image See the code of this component [below]

Fine tuned thermostat Thank's impuR_Shozz ! We can see stability around the target temperature (consigne) and when at target the on_percent (puissance) is near 0.3 which seems a very good value.

image

Enjoy !

Even better

Much better with the Veersatile Thermostat UI Card

A special card for the Versatile Thermostat has been developed (based on the Better Thermostat). It is available here Versatile Thermostat UI Card and offers a modern vision of all the VTherm statuses:

image

Even Better with Scheduler Component !

In order to enjoy the full power of Versatile Thermostat, I invite you to use it with https://github.com/nielsfaber/scheduler-component Indeed, the scheduler component porpose a management of the climate base on the preset modes. This feature has limited interest with the generic thermostat but it becomes highly powerfull with Awesome thermostat :

Starting here, I assume you have installed Awesome Thermostat and Scheduler Component.

In Scheduler, add a schedule :

image

Choose "climate" group, choose one (or multiple) entity/ies, select "MAKE SCHEME" and click next : (it is possible to choose "SET PRESET", but I prefer to use "MAKE SCHEME")

image

Set your mode scheme and save :

image

In this example I set ECO mode during the night and the day when nobody's at home BOOST in the morning and COMFORT in the evening.

I hope this example helps you, don't hesitate to give me your feedbacks !

Even-even better with custom:simple-thermostat front integration

The custom:simple-thermostat here is a great integration which allow some customisation which fits well with this thermostat. You can have something like that very easily image Example configuration:

      type: custom:simple-thermostat
      entity: climate.thermostat_sam2
      layout:
        step: row
      label:
        temperature: T°
        state: Etat
      hide:
        state: false
      control:
        hvac:
          _name: Mode
        preset:
          _name: Preset
      sensors:
        - entity: sensor.total_puissance_radiateur_sam2
          icon: mdi:lightning-bolt-outline
      header:
        toggle:
          entity: input_boolean.etat_ouverture_porte_sam
          name: Porte sam

You can customize this component using the HACS card-mod component to adjust the alert colors. Example for displaying safety and load shedding alerts in red:

          card_mod:
            style: |
              {% if is_state('binary_sensor.thermostat_chambre_security_state', 'on') %}
              ha-card .body .sensor-heading ha-icon[icon="mdi:alert-outline"] {
                color: red;
              }
              {% endif %}
              {% if is_state('binary_sensor.thermostat_chambre_overpowering_state', 'on') %}
              ha-card .body .sensor-heading ha-icon[icon="mdi:flash"] {
                color: red;
              }
              {% endif %}

image

Even better with Plotly to tune your Thermostat

You can get curve like presented in some results with kind of Plotly configuration only using the custom attributes of the thermostat described here:

Replace values in [[ ]] by yours.

- type: custom:plotly-graph
  entities:
    - entity: '[[climate]]'
      attribute: temperature
      yaxis: y1
      name: Consigne
    - entity: '[[climate]]'
      attribute: current_temperature
      yaxis: y1
      name: T°
    - entity: '[[climate]]'
      attribute: ema_temp
      yaxis: y1
      name: Ema
    - entity: '[[climate]]'
      attribute: regulated_target_temperature
      yaxis: y1
      name: Regulated T°
    - entity: '[[slope]]'
      name: Slope
      fill: tozeroy
      yaxis: y9
      fillcolor: rgba(100, 100, 100, 0.3)
      line:
        color: rgba(100, 100, 100, 0.9)
  hours_to_show: 4
  refresh_interval: 10
  height: 800
  config:
    scrollZoom: true
  layout:
    margin:
      r: 50
    legend:
      x: 0
      'y': 1.2
      groupclick: togglegroup
      title:
        side: top right
    yaxis:
      visible: true
      position: 0
    yaxis9:
      visible: true
      fixedrange: false
      range:
        - -0.5
        - 0.5
      position: 1
    xaxis:
      rangeselector:
        'y': 1.1
        x: 0.7
        buttons:
          - count: 1
            step: hour
          - count: 12
            step: hour
          - count: 1
            step: day
          - count: 7
            step: day

Example of graph obtained with Plotly :

image

And always better and better with the NOTIFIER daemon app to notify events

This automation uses the excellent App Daemon named NOTIFIER developed by Horizon Domotique that you will find in demonstration here and the code is [here](https ://github.com/jlpouffier/home-assistant-config/blob/master/appdaemon/apps/notifier.py). It allows you to notify the users of the accommodation when one of the events affecting safety occurs on one of the Versatile Thermostats.

This is a great example of using the notifications described here notification.

alias: Surveillance Mode Sécurité chauffage
description: Envoi une notification si un thermostat passe en mode sécurité ou power
trigger:
  - platform: event
    event_type: versatile_thermostat_security_event
    id: versatile_thermostat_security_event
  - platform: event
    event_type: versatile_thermostat_power_event
    id: versatile_thermostat_power_event
  - platform: event
    event_type: versatile_thermostat_temperature_event
    id: versatile_thermostat_temperature_event
condition: []
action:
  - choose:
      - conditions:
          - condition: trigger
            id: versatile_thermostat_security_event
        sequence:
          - event: NOTIFIER
            event_data:
              action: send_to_jmc
              title: >-
                Radiateur {{ trigger.event.data.name }} - {{
                trigger.event.data.type }} Sécurité
              message: >-
                Le radiateur {{ trigger.event.data.name }} est passé en {{
                trigger.event.data.type }} sécurité car le thermomètre ne répond
                plus.\n{{ trigger.event.data }}
              callback:
                - title: Stopper chauffage
                  event: stopper_chauffage
              image_url: /media/local/alerte-securite.jpg
              click_url: /lovelace-chauffage/4
              icon: mdi:radiator-off
              tag: radiateur_security_alerte
              persistent: true
      - conditions:
          - condition: trigger
            id: versatile_thermostat_power_event
        sequence:
          - event: NOTIFIER
            event_data:
              action: send_to_jmc
              title: >-
                Radiateur {{ trigger.event.data.name }} - {{
                trigger.event.data.type }} Délestage
              message: >-
                Le radiateur {{ trigger.event.data.name }} est passé en {{
                trigger.event.data.type }} délestage car la puissance max est
                dépassée.\n{{ trigger.event.data }}
              callback:
                - title: Stopper chauffage
                  event: stopper_chauffage
              image_url: /media/local/alerte-delestage.jpg
              click_url: /lovelace-chauffage/4
              icon: mdi:radiator-off
              tag: radiateur_power_alerte
              persistent: true
      - conditions:
          - condition: trigger
            id: versatile_thermostat_temperature_event
        sequence:
          - event: NOTIFIER
            event_data:
              action: send_to_jmc
              title: >-
                Le thermomètre du radiateur {{ trigger.event.data.name }} ne
                répond plus
              message: >-
                Le thermomètre du radiateur {{ trigger.event.data.name }} ne
                répond plus depuis longtemps.\n{{ trigger.event.data }}
              image_url: /media/local/thermometre-alerte.jpg
              click_url: /lovelace-chauffage/4
              icon: mdi:radiator-disabled
              tag: radiateur_thermometre_alerte
              persistent: true
mode: queued
max: 30

Contributions are welcome!

If you want to contribute to this please read the Contribution guidelines

Troubleshooting

Using a Heatzy

The use of a Heatzy is possible provided you use a virtual switch on this model:

- platform:template
   switches:
     bathroom_heating:
       unique_id: heating_bathroom
       friendly_name: Bathroom heating
       value_template: "{{ is_state_attr('climate.bathroom', 'preset_mode', 'comfort') }}"
       icon_template: >-
         {% if is_state_attr('climate.bathroom', 'preset_mode', 'comfort') %}
           mdi:radiator
         {% elif is_state_attr('climate.bathroom', 'preset_mode', 'away') %}
           mdi:snowflake
         {% else %}
           mdi:radiator-disabled
         {% endif %}
       turn on:
         service: climate.set_preset_mode
         entity_id: climate.bathroom
         data:
           preset_mode: "comfort"
       turn_off:
         service: climate.set_preset_mode
         entity_id: climate.bathroom
         data:
           preset_mode: "eco"

Thanks to @gael for this example.

Using a Heatsink with a Pilot Wire

As with the Heatzy above you can use a virtual switch which will change the preset of your radiator depending on the ignition state of the VTherm. Example :

- platform:template
   switches:
     radiator_soan:
         friendly_name: radiator_soan_inv
         value_template: "{{ is_state('switch.radiateur_soan', 'off') }}"
         turn on:
           service: switch.turn_off
           data:
             entity_id: switch.radiateur_soan
         turn_off:
           service: switch.turn_on
           data:
             entity_id: switch.radiateur_soan
         icon_template: "{% if is_state('switch.radiateur_soan', 'on') %}mdi:radiator-disabled{% else %}mdi:radiator{% endif %}"

Only the first radiator heats

In over_switch mode if several radiators are configured for the same VTherm, switching on will be done sequentially to smooth out consumption peaks as much as possible. This is completely normal and desired. It is described here: For a thermostat of type ``thermostat_over_switch```v

The radiator heats up even though the setpoint temperature is exceeded or does not heat up even though the room temperature is well below the setpoint

Type over_switch or over_valve

With a VTherm of type over_switch or over_valve, this fault just shows that the parameters of the TPI algorithm are incorrectly set. See TPI Algorithm to optimize the settings.

Type over_climate

With an over_climate type VTherm, the regulation is done by the underlying climate directly and VTherm simply transmits the instructions to it. So if the radiator heats up when the set temperature is exceeded, it is certainly because its internal temperature measurement is biased. This happens very often with TRVs and reversible air conditioning units which have an internal temperature sensor, or too close to the heating element (therefore too cold in winter).

Example of discussion around these topics: #316, #312, #278

To get around this, VTherm is equipped with a function called self-regulation which allows the instruction sent to the underlying to be adapted until the target temperature is respected. This function compensates for the measurement bias of internal thermometers. If the bias is important the regulation must be important. See Self-regulation to configure self-regulation.

Adjust window opening detection parameters in auto mode

If you cannot set the opening detection function in auto mode (see auto), you can try modifying the parameters of the temperature smoothing algorithm. In fact, automatic opening detection is based on the calculation of the temperature slope. To avoid artifacts due to an imprecise temperature sensor, this slope is calculated on a smoothed temperature with a smoothing algorithm called Exponential Moving Average. This algorithm has 3 parameters:

  1. lifecycle_sec: the duration in seconds taken into account for smoothing. The stronger it is, the greater the smoothing will be, but the longer there will be a detection delay,
  2. max_alpha: if two temperature measurements are separated in time, the second will have a very strong weight. The parameter makes it possible to limit the weight of a measurement which arrives well after the previous one. This value must be between 0 and 1. The lower it is, the less distant values are taken into account. The default is 0.5. This means that when a new temperature value will never weigh more than half of the moving average,
  3. precision: the number of digits after the decimal point retained for calculating the moving average.

To change its parameters, you must modify the configuration.yaml file and add the following section (the values are the default values):

versatile_thermostat:
  short_ema_params:
    max_alpha: 0.5
    halflife_sec: 300
    accuracy: 2

These parameters are sensitive and quite difficult to adjust. Please only use them if you know what you are doing and your temperature measurements are not already smooth.

Why does my Versatile Thermostat go into Safety?

Safety mode is only possible on VTherm over_switch and over_valve. It occurs when one of the 2 thermometers which gives the room temperature or the outside temperature has not sent a value for more than security_delay_min minutes and the radiator was heating at least security_min_on_percent.

As the algorithm is based on temperature measurements, if they are no longer received by the VTherm, there is a risk of overheating and fire. To avoid this, when the conditions mentioned above are detected, heating is limited to the security_default_on_percent parameter. This value must therefore be reasonably low. It helps prevent a fire while avoiding completely cutting off the radiator (risk of freezing).

All these parameters are adjusted on the last page of the VTherm configuration: “Advanced parameters”.

How to detect safety mode?

The first symptom is an abnormally low temperature with a slow and regular heating time in each cycle. Example:

safety mode

If you installed the Versatile Thermostat UI Card, the VTherm in question will have this shape:

safety mode UI Card

You can also check in the VTherm attributes the dates of receipt of the different dates. Attributes are available in Development Tools / Reports.

Example :

security_state: true
last_temperature_datetime: "2023-12-06T18:43:28.346010+01:00"
last_ext_temperature_datetime: "2023-12-06T13:04:35.164367+01:00"
last_update_datetime: "2023-12-06T18:43:28.351103+01:00"
...
security_delay_min: 60

We see that :

  1. the VTherm is in safety mode (security_state: true),
  2. the current time is 06/12/2023 at 18:43:28 (last_update_datetime: "2023-12-06T18:43:28.351103+01:00"),
  3. the last received time of indoor temperature is 06/12/2023 at 18:43:28 (last_temperature_datetime: "2023-12-06T18:43:28.346010+01:00"). So she's on time,
  4. the last reception time of the outdoor temperature is 06/12/2023 at 1:04:35 p.m. (last_ext_temperature_datetime: "2023-12-06T13:04:35.164367+01:00). external time which is more than 5 hours late and which caused the switch to safety mode, because the threshold is limited to 60 min (security_delay_min: 60)

How can I be notified when this happens?

To be notified, the VTherm sends an event as soon as it happens and one at the end of the safety alert. You can capture these events in an automation and send a notification for example, flash a light, trigger a siren, etc. It's up to you.

To manipulate the events generated by VTherm, cf. Events.

How to repair?

This will depend on the cause of the problem:

  1. If a sensor is faulty, it must be repaired (replace batteries, change it, check the Weather integration which gives the outside temperature, etc.),
  2. If the security_delay_min parameter is too small, it risks generating a lot of false alerts. A correct value is around 60 min, especially if you have battery-powered temperature sensors.
  3. Some temperature sensors do not send a measurement if the temperature has not changed. So in the event of a very stable temperature for a long time, the safety mode may be triggered. This is not very serious since it is removed as soon as the VTherm receives a temperature again. On certain thermometers (TuYA for example), you can force the maximum delay between 2 measurements. It will be appropriate to set a max delay < security_delay_min,
  4. As soon as the temperature is received again the safety mode will be removed and the previous values of preset, target temperature and mode will be restored.

Using a group of people as a presence sensor

Unfortunately, groups of people are not recognized as presence sensors. We cannot therefore use them directly in VTherm. The workaround is to create a binary_sensor template with the following code:

template.yaml file:

- binary_sensor:
     - name: occupied_house
       unique_id: occupied_house
       state: "{{is_state('person.person1', 'home') or is_state('person.person2', 'home') or is_state('input_boolean.force_presence', 'on')}}"
       device_class: occupancy

You will note in this example, the use of an input_boolean named force_presence which allows you to force the sensor to True and thus force the VTherm which uses it with active presence. This allows, for example, to force pre-heating of the home when leaving work, or when a person not natively recognized in HA is present.

configuration.yaml file:

...
template: !include templates.yaml
...

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A full featured Thermostat for Home Assistant: presets, window, motion, presence and overpowering management

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