Create a virtual thermostat with accurate and reactive temperature control through PID controller. Principle of the PID controller. Any heater or air conditioner unit with ON/OFF switch or pilot wire can be controlled using a pulse width modulation that depends on the temperature error and its variation over time.
I recommend using HACS for easier installation.
Go to HACS, select Integrations, click the three dots menu and select
"Custom repositories". Add the path to the Github repository in the first field, select Integration
as category and click Add. Once back in integrations panel, click the Install button on the Smart
Thermostat PID card to install.
Set up the smart thermostat and have fun.
- Go to default /homeassistant/.homeassistant/ (it's where your configuration.yaml is)
- Create /custom_components/ directory if it does not already exist
- Copy the smart_thermostat folder into /custom_components/
- Set up the smart_thermostat and have fun
The smart thermostat can be added to Home Assistant after installation by adding a climate section to your configuration.yaml file.
climate:
- platform: smart_thermostat
name: Smart Thermostat Example
unique_id: smart_thermostat_example
heater: switch.on_off_heater
target_sensor: sensor.ambient_temperature
min_temp: 7
max_temp: 28
ac_mode: False
target_temp: 19
keep_alive:
seconds: 60
away_temp: 14
kp: 5
ti: 100
td: 0
pwm: 00:15:00
The target sensor measures the ambient temperature while the heater switch controls an ON/OFF
heating system.
The PID controller computes the amount of time the heater should remain ON over the PWM period to
reach the temperature set point, in example with PWM set to 15 minutes, if output is 100% the
heater will be kept on for the next 15 minutes PWM period. If PID output is 33%, the heater will be
switched ON for 5 minutes only.
By default, the PID controller will be called each time the target sensor is updated. When using main powered sensor with high sampling rate, the sampling_period parameter should be used to slow down the PID controller refresh rate.
By adjusting the Kp, Ti and Td parameters, you can tune the system response to your liking. You can find many tutorials for guidance on the web. Here are a few useful links:
- PID Control made easy
- Practical PID Process Dynamics with Proportional Pressure Controllers
- PID Tuner
- PID development blog from Brett Beauregard
- PID controller explained
To make it quick and simple:
- Kp gain adjusts the proportional part of the error compensation. Higher values means stronger reaction to error. Increase the value for faster rise time.
- Ti time adjusts the integral part. Integral compensates the residual error when temperature settles in a cumulative way. The longer the temperature remains below the set point, the higher the integral compensation will be. If your system settles below the set point, decrease the Ti value. If it settles over the set point, increase the Ti value.
- Td time adjusts the derivative part of the compensation. Derivative compensates the inertia of the system, but can create instability unless tuned carefully. If the sensor temperature increases quickly between two samples, the PID will decrease the PWM level accordingly to limit the overshoot. It is possible to use a proportional-integral controller (without derivative), by setting Td to 0.
PID output value is the weighted sum of the control terms:
error = target_temp - current_temperature
di =
temperature change between last two samples
dt =
time elapsed between last two samples
P = Kp * error
I = last_I + (Kp / Ti * error * dt)
D = -(Kp * Td * di) / dt
output = P + I + D
Output is then limited to 0% to 100% range to control the PWM.
Optionally, when an outdoor temperature sensor entity is provided and ke is set, the thermostat can
automatically compensate building losses based on the difference between target temperature and
outdoor temperature. Internal heat production (e.g. by electronic applicances) cam be compensated
for by adding an offset to the outdoor sensor. An external component E is added to the PID output:
E = Ke * (target_temp - (outdoor_temp + outdoor_sensor_offset))
output = P + I + D + E
Output is then limited to 0% to 100% range to control the PWM.
The Ke gain depends on the insulation of the building and the power of the heater. A good approximation
can be found by making an XY-plot of the daily (or monthly) heating energy consumption versus the
daily (or monthly) outdoor temperature. The slope of the line then can be converted into a gain. This
compensation will act like the integral of the PID, but with faster response time, so the integral will be more stable.
You can use the autotune feature to find some working PID parameters.
Add the autotune: parameter with the desired tuning rule, and optionally set the noiseband and
lookback duration if the default 2 hours doesn't match your HVAC system bandwidth.
Restart Home Assistant to start the thermostat in autotune mode and set the desired temperature on
the thermostat. The autotuner will then start analyzing your heating system, measure the sampling
rate of the sensor, control the heater switch and monitor the temperature changes.
Wait for the autotune to finish by checking the autotune_status attribute for success. The Kp, Ki
and Kd gains will then be computed and set according to the selected rule and the thermostat
switches to PID.
The Kp, Ki and Kd gains are also computed using the other rules, and all values are shown in the
Home Assistant log like this: "Smart thermostat PID Autotuner output with ziegler-nichols rule:
Kp=######, Ki=######, Kd=######".
You should then save for reference the gains computed by the autotuner for future testing.
Warning: The thermostat set point can't be changed once the autotuner has started monitoring the temperature. The temperature regulation will work as a basic hysteresis thermostat based on set point and noise band. If your heating system and temperature monitoring is slow, reducing the noise band will reduce the temperature oscillations around the set point. If the sampling rate of your temperature sensor is too fast (few seconds) or noisy (frequent temperature changes) increase the noise band for system stability.
Warning: The autotuner result is saved in the entity attributes and restored after Home
Assistant is restarted.
However, it is recommended to save the new gains in the YAML configuration file to keep it in case
of Home Assistant database's is corrupted.
Services can be used in Home Assistant to configure the thermostat.
The following services are available:
Set PID gains: smart_thermostat.set_pid_gain
Use this service to adjust the PID gains without requiring a restart of Home
Assistant. Values are saved to Home Assistant database and restored after a restart.
Please consider saving the final gain parameters in YAML configuration file when satisfied to keep
it safe in case of database corruption.
Optional parameters : kp, ki and kd, as float.
Example:
service: smart_thermostat.set_pid_gain
data:
kp: 11.8
ki: 120
target:
entity_id: climate.smart_thermostat_example
Set PID mode: smart_thermostat.set_pid_mode
Use this service to set the PID mode to either 'auto' or 'off'.
When in auto, the PID will modulate the heating based on temperature value and variation. When in
off, the PID output will be 0% if temperature is above the set point, and 100% if temperature is
below the set point.
Mode is saved to Home Assistant database and restored after a restart.
Required parameter : mode as a string in ['auto', 'off'].
Example:
service: smart_thermostat.set_pid_mode
data:
mode: 'off'
target:
entity_id: climate.smart_thermostat_example
Set preset modes temperatures: smart_thermostat.set_preset_temp
Use this service to set the temperatures for the preset modes. It can be adjusted
for all preset modes, if a preset mode is not enabled through YAML, it will be enabled. You can use
any preset temp parameter available in smart thermostat settings.
Please note the value will then be saved in the entity's state in database and restored after
restarting Home Assistant, ignoring values in YAML. Use the disable options to remove active
presets.
Example:
service: smart_thermostat.set_preset_temp
data:
away_temp: 14.6
boost_temp: 22.5
home_temp_disable: true
target:
entity_id: climate.smart_thermostat_example
Clear the integral part: smart_thermostat.clear_integral
Use this service to reset the integral part of the PID controller to 0. Useful when tuning the PID
gains to quickly test the behavior without waiting the integral to stabilize by itself.
- name (Optional): Name of the thermostat.
- unique_id (Optional): unique entity_id for the smart thermostat.
- heater (Required): entity_id for heater control, should be a toggle device or a valve accepting direct input between 0% and 100%. If a valve is used, pwm parameter should be set to 0. Becomes air conditioning switch when ac_mode is set to true.
- invert_heater (Optional): if set to true, inverts the polarity of heater switch (switch is on while idle and off while active). Must be a boolean (defaults to false).
- target_sensor (Required): entity_id for a temperature sensor, target_sensor.state must be temperature.
- outdoor_sensor (Optional): entity_id for an outdoor temperature sensor, outdoor_sensor.state must be temperature.
- keep_alive (Required): sets update interval for the PWM pulse width. If interval is too big, the PWM granularity will be reduced, leading to lower accuracy of temperature control, can be float in seconds, or time hh:mm:ss.
- kp (Recommended): Set PID parameter, proportional (p) gain (float, default 100).
- ti (Recommended): Set PID parameter, integral (i) time (float, default 0).
- td (Recommended): Set PID parameter, derivative (d) time (float, default 0).
- ke (Optional): Set outdoor temperature compensation (e) gain(float, default 0).
- outside_sensor_offset (Optional): Set offset to outside temperature sensor, this value will be added. You can use it to compensate for the baseline of heat released by electric applicances etc.
- pwm (Optional): Set period of the pulse width modulation. If too long, the response time of the thermostat will be too slow, leading to lower accuracy of temperature control. Can be float in seconds or time hh:mm:ss (default 15mn). Set to 0 when using heater entity with direct input of 0/100% values like valves.
- min_cycle_duration (Optional): Set a minimum amount of time that the switch specified in the heater option must be in its current state prior to being switched either off or on (useful to protect boilers). Can be float in seconds or time hh:mm:ss (default 0s).
- min_off_cycle_duration (Optional): When
min_cycle_duration
is specified, Set a minimum amount of time that the switch specified in the heater option must remain in OFF state prior to being switched ON. Themin_cycle_duration
setting is then used for ON cycle only, allowing different minimum cycle time for ON and OFF. Can be float in seconds or time hh:mm:ss (defaults tomin_cycle_duration
value). - min_cycle_duration_pid_off (Optional): This parameter is the same as
min_cycle_duration
but is used specifically when PID is set to OFF. Defaults tomin_cycle_duration
value. - min_off_cycle_duration_pid_off (Optional): This parameter is the same as
min_off_cycle_duration but is used specifically when PID is set to OFF. Defaults to
min_cycle_duration_pid_off
value. - sampling_period (Optional): interval between two computation of the PID. If set to 0, PID computation is called each time the temperature sensor sends an update. Can be float in seconds or time hh:mm:ss (default 0).
- target_temp_step (Optional): the adjustment step of target temperature (valid are 0.1, 0.5 and 1.0, default 0.5 for Celsius and 1.0 for Fahrenheit).
- precision (Optional): the displayed temperature precision (valid are 0.1, 0.5 and 1.0, default 0.1 for Celsius and 1.0 for Fahrenheit).
- min_temp (Optional): Set minimum set point available (default: 7).
- max_temp (Optional): Set maximum set point available (default: 35).
- target_temp (Optional): Set initial target temperature. If not set target temperature will be set to null on startup.
- cold_tolerance (Optional): When PID is off, set a minimum amount of difference between the temperature read by the sensor specified in the target_sensor option and the target temperature that must change prior to being switched on. For example, if the target temperature is 25 and the tolerance is 0.5 the heater will start when the sensor equals or goes below 24.5 (float, default 0.3).
- hot_tolerance (Optional): When PID is off, set a minimum amount of difference between the temperature read by the sensor specified in the target_sensor option and the target temperature that must change prior to being switched off. For example, if the target temperature is 25 and the tolerance is 0.5 the heater will stop when the sensor equals or goes above 25.5 (float, default 0.3).
- ac_mode (Optional): Set the switch specified in the heater option to be treated as a cooling device instead of a heating device. Should be a boolean (default: false).
- preset_sync_mode (Optional): If set to sync mode, manually setting a temperature will enable the corresponding preset. In example, if away temperature is set to 14°C, manually setting the temperature to 14°C on the thermostat will automatically enable the away preset mode. Should be string either 'sync' or 'none' (default: 'none').
- boost_pid_off (Optional): When set to true, the PID will be set to OFF state while boost preset is selected, and the thermostat will operate in hysteresis mode. This helps to quickly raise the temperature in a room for a short period of time. Should be a boolean (default: false).
- away_temp (Optional): Set the default temperature used by the "Away" preset. If this is not
specified, away_mode feature will not be available. The temperature can then be adjusted using the
set_preset_temp
service, new value being restored after restarting HA. - eco_temp (Optional): Set the default temperature used by the "Eco" preset. If this is not
specified, eco feature will not be available. The temperature can then be adjusted using the
set_preset_temp
service, new value being restored after restarting HA. - boost_temp (Optional): Set the default temperature used by the "Boost" preset. If this is not
specified, boost feature will not be available. The temperature can then be adjusted using the
set_preset_temp
service, new value being restored after restarting HA. - comfort_temp (Optional): Set the default temperature used by the "Comfort" preset. If this is not specified, comfort feature will not be available.
- home_temp (Optional): Set the default temperature used by the "Home" preset. If this is not
specified, home feature will not be available. The temperature can then be adjusted using the
set_preset_temp
service, new value being restored after restarting HA. - sleep_temp (Optional): Set the default temperature used by the "Sleep" preset. If this is not
specified, sleep feature will not be available. The temperature can then be adjusted using the
set_preset_temp
service, new value being restored after restarting HA. - activity_temp (Optional): Set the default temperature used by the "Activity" preset. If this
is not specified, activity feature will not be available. The temperature can then be adjusted using
the
set_preset_temp
service, new value being restored after restarting HA. - sensor_stall (Optional): Sets the maximum time period between two sensor updates. If no update received from sensor after this time period, the system considers the sensor as stall and switch to safety mode, the output being forced to output_safety. If set to 0, the feature is disabled. Can be float in seconds or time hh:mm:ss (default 6 hours).
- output_safety (Optional): Sets the output level of the PID once the thermostat enters safety mode due to unresponsive temperature sensor. This can help to keep a minimum temperature in the room in case of sensor failure. The value should be a float between 0.0 and 100.0 (default 5.0).
- initial_hvac_mode (Optional): Forces the operation mode after Home Assistant is restarted. If not specified, the thermostat will restore the previous operation mode.
- debug (Optional): Make the climate entity expose the following internal values as extra
states attributes, so they can be accessed in HA with sensor templates for debugging purposes (
helpful to adjust the PID gains), example:
It is strongly recommended to disable the debug mode once the PID Thermostat is working fine, as the added extra states attributes will fill the Home Assistant database quickly.
- platform: template sensors: smart_thermostat_output: friendly_name: PID Output unit_of_measurement: "%" value_template: "{{ state_attr('climate.smart_thermostat_example', 'control_output') | float }}" smart_thermostat_p: friendly_name: PID P unit_of_measurement: "%" value_template: "{{ state_attr('climate.smart_thermostat_example', 'pid_p') | float }}" smart_thermostat_i: friendly_name: PID I unit_of_measurement: "%" value_template: "{{ state_attr('climate.smart_thermostat_example', 'pid_i') | float }}" smart_thermostat_d: friendly_name: PID D unit_of_measurement: "%" value_template: "{{ state_attr('climate.smart_thermostat_example', 'pid_d') | float }}" smart_thermostat_e: friendly_name: PID E unit_of_measurement: "%" value_template: "{{ state_attr('climate.smart_thermostat_example', 'pid_e') | float }}"
Available debug attributes are:pid_p
pid_i
pid_d
pid_e
pid_dt
- noiseband (Optional): set noiseband for autotune (float): Determines by how much the input value must overshoot/undershoot the set point before the state changes (default : 0.5).
- lookback (Optional): length of the autotune buffer for the signal analysis to detect peaks, can be float in seconds, or time hh:mm:ss (default 2 hours).
- autotune (Optional): Set the name of the selected rule for autotune settings (ie "ziegler-nichols"). If it's not set, autotune is disabled. The following tuning_rules are available: ruler | Kp_divisor, Ki_divisor, Kd_divisor ------------ | ------------- "ziegler-nichols" | 34, 40, 160 "tyreus-luyben" | 44, 9, 126 "ciancone-marlin" | 66, 88, 162 "pessen-integral" | 28, 50, 133 "some-overshoot" | 60, 40, 60 "no-overshoot" | 100, 40, 60 "brewing" | 2.5, 6, 380
This code is a fork from Smart Thermostat PID project:
https://github.com/ScratMan/HASmartThermostat
The python PID module with Autotune is based on pid-autotune:
https://github.com/hirschmann/pid-autotune