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444 lines
19 KiB
ReStructuredText
PID Climate
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===========
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.. seo::
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:description: Instructions for setting up PID climate controllers with ESPHome.
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:image: function.svg
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The ``pid`` climate platform allows you to regulate a value with a
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`PID controller <https://en.wikipedia.org/wiki/PID_controller>`__.
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PID controllers are good at modulating an output signal to get a sensor reading to a specified
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setpoint. For example, it can be used to modulate the power of a heating unit to get the
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temperature to a user-specified setpoint.
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.. note::
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PID is like cruise control in the cars: it keeps the car's speed constant by continuously
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adjusting the fuel quantity, based on load measurements. Eg when the car has to go up on a hill,
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the system notices the load increase thus immediately gives more fuel to the engine; and when it
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goes down on the other side of the hill, it notices the load decrease thus reduces or cuts off fuel
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completely so that car speed remains as constant as possible. The calculation takes in consideration
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constants like car weight, wind resistance etc.
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This kind of math can be used for a heating or cooling system too, and an auto-tuning algorithm can help
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determining such constants, which mainly describe the heat loss of the room or building. Goal is to
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keep the temperature as constant as possible, and smooth out oscillations otherwise produced by
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classic thermostats.
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Explaining how PID controllers work in detail is out of scope of this documentation entry,
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but there's a nice article explaining the function principle `here <https://blog.opticontrols.com/archives/344>`__.
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.. code-block:: yaml
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# Example configuration entry
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climate:
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- platform: pid
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name: "PID Climate Controller"
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sensor: temperature_sensor
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default_target_temperature: 21°C
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heat_output: heater
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control_parameters:
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kp: 0.49460
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ki: 0.00487
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kd: 12.56301
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output_averaging_samples: 5 # smooth the output over 5 samples
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derivative_averaging_samples: 5 # smooth the derivative value over 10 samples
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deadband_parameters:
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threshold_high: 0.5°C # deadband within +/-0.5°C of target_temperature
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threshold_low: -0.5°C
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Configuration variables:
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------------------------
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- **sensor** (**Required**, :ref:`config-id`): The sensor that is used to measure the current
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temperature.
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- **humidity_sensor** (**Optional**, :ref:`config-id`): If specified, this sensor is used to measure the current humidity.
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This is used for information only and does not influence temperature control.
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- **default_target_temperature** (**Required**, float): The default target temperature (setpoint)
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for the control algorithm. This can be dynamically set in the frontend later.
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- **heat_output** (*Optional*, :ref:`config-id`): The ID of a :ref:`float output <config-output>`
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that increases the current temperature. At least one of ``heat_output`` and ``cool_output`` must
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be specified.
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- **cool_output** (*Optional*, :ref:`config-id`): The ID of a :ref:`float output <config-output>`
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that decreases the current temperature. At least one of ``heat_output`` and ``cool_output`` must
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be specified.
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- **control_parameters** (**Required**): Control parameters of the PID controller.
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- **kp** (**Required**, float): The factor for the proportional term of the PID controller.
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- **ki** (*Optional*, float): The factor for the integral term of the PID controller.
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Defaults to ``0``.
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- **kd** (*Optional*, float): The factor for the derivative term of the PID controller.
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Defaults to ``0``.
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- **min_integral** (*Optional*, float): The minimum value of the integral term multiplied by
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``ki`` to prevent windup. Defaults to ``-1``.
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- **max_integral** (*Optional*, float): The maximum value of the integral term multiplied by
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``ki`` to prevent windup. Defaults to ``1``.
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- **starting_integral_term** (*Optional*, float): Set the initial output, by priming the integral
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term. This is useful for when your system is rebooted and you don't want to wait
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for it to get back equilibrium.
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- **output_averaging_samples** (*Optional*, int): average the output over this many samples. PID controllers
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can be quite sensitive to small changes on the input sensor. By averaging the last X output samples,
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the temperature can be more stable. However, the larger the sampling window, the less responsive the
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PID controller. Defaults to ``1`` which is no sampling/averaging.
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- **derivative_averaging_samples** (*Optional*, int): average the derivative term over this many samples. Many
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controllers don't use the derivative term because it is sensitive to slight changes in the input sensor.
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By taking an average of the derivative term it might become more useful for you. Most PID controllers call
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this derivative filtering. The derivative term is used to pre-act so don't filter too much. Defaults to ``1``
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which is no sampling/averaging.
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- **deadband_parameters** (*Optional*): Enables a deadband to stabilise and minimise changes in the
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output when the temperature is close to the target temperature. See `Deadband Setup`_.
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- **threshold_high/threshold_low** (**Required**, float): Specifies a high/low
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threshold defining the deadband around the target temperature. For instance with
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``default_target_temperature`` of ``21°C`` and thresholds of ``+/-0.5°C``, the deadband will be
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between ``20.5°C - 21.5°C``. The PID controller will limit output changes within the deadband.
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- **kp_multiplier** (*Optional*, float): Set the ``kp`` gain when inside the deadband. Defaults to ``0``.
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- **ki_multiplier** (*Optional*, float): Set the ``ki`` gain when inside the deadband. Defaults to ``0``.
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- **kd_multiplier** (*Optional*, float): Set the ``kd`` gain when inside the deadband. Recommended this
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is set to ``0``. Defaults to ``0``.
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- **deadband_output_averaging_samples** (*Optional*, int): Typically when inside the deadband the PID Controller has
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reached a state of equilibrium, so it advantageous to use a higher number of output samples
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like 10-30 samples. Defaults to ``1`` which is no sampling/averaging.
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- All other options from :ref:`Climate <config-climate>`.
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.. _pid-setup:
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PID Controller Setup
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--------------------
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To set up a PID climate controller, you need a couple of components:
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- A :ref:`Sensor <config-sensor>` to read the current temperature (``sensor``).
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- At least one :ref:`float output <config-output>` to drive for heating or cooling (or both).
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This could for example be a PWM output via :doc:`/components/output/sigma_delta_output` or :doc:`/components/output/slow_pwm` that drives a heating unit.
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Please note the output *must* be controllable with continuous value (not only ON/OFF, but any state
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in between for example 50% heating power).
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.. note::
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The sensor should have a short update interval. The PID update frequency is tied to the update
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interval of the sensor. Set a short ``update_interval`` like ``5s`` on the sensor.
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We recommend putting a filter on the sensor (see filters in :doc:`/components/sensor/index`) and
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using ``output_averaging_samples`` to calm the PID sensor from a noisy input sensor.
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Deadband Setup
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--------------
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A deadband is used to prevent the PID controller from further adjusting the power
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once the temperature has settled within a range of the target temperature.
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We do this by specifying a high/low threshold of the target temperature.
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To understand the benefit, consider a heating/cooling HVAC which is constantly
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oscillating between heating and cooling as the thermostat records very minor
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changes from +0.1º to -0.1º. Clearly this is undesirable and will cause wear
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and tear as the HVAC oscillates. With a deadband in place the heater won't
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activate until the thermostat breaches the low_threshold and the cooler won't activate
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until the thermostat breaches the high_threshold.
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The most basic setup specifies the threshold around the target temperature as follows:
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.. code-block:: yaml
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default_target_temperature: 21°C
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...
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deadband_parameters:
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threshold_high: 0.5°C
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threshold_low: -1.0°C
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In this example the deadband is between ``20.0°C - 21.5°C``. The PID controller will limit any output
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variation inside this deadband. How it limits depends on how you set the `Deadband Multipliers`_.
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.. figure:: images/deadband1.png
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Deadband Multipliers
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********************
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Deadband Multipliers tell the controller how to operate when inside of the deadband.
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Each of the p,i and d terms can be controlled using the kp, ki and kd multipliers. For instance, if the kp_multiplier
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is set to 0.05 then the final proportional term will be set to 5% of its normal value within the deadband.
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If all of the multipliers are set to 0, then the controller will not adjust power at all within the
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deadband. This is the default behavior.
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Most deadband implementations set kp and ki multipliers to a small gain like ``0.05`` and set
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derivative to 0. This means that the PID output will calmly make minor adjustments over a 20x longer
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timeframe to stay within the deadband zone.
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To start with we recommend just setting the ``ki_multiplier`` to ``0.05`` (5%). Then
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set ``kp_multiplier`` to ``0.05`` (5%) if the controller is falling out of the deadband too often.
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.. code-block:: yaml
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default_target_temperature: 21°C
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...
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deadband_parameters:
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threshold_high: 0.5°C
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threshold_low: -1.0°C
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kp_multiplier: 0.0 # proportional gain turned off inside deadband
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ki_multiplier: 0.05 # integral accumulates at only 5% of normal ki
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kd_multiplier: 0.0 # derviative is turned off inside deadband
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deadband_output_averaging_samples: 15 # average the output over 15 samples within the deadband
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.. figure:: images/deadband2.png
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Deadband Output Averaging Samples
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*********************************
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Since we expect the PID Controller to be at equilibrium while inside the deadband, we can
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average the output over a longer range of samples, like 15 samples. This helps even further
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with temperature and controller stability.
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.. _pid-autotune:
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Autotuning
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----------
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Finding suitable ``kp``, ``ki`` and ``kd`` control parameters for the PID controller manually
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needs some experience with PID controllers. ESPHome has an auto-tuning algorithm that automatically
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finds suitable PID parameters to start using an adaption of the Ziegler-Nichols method with
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relay autotuning (Åström and Hägglund).
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To autotune the control parameters:
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1. Set up the PID controller with all control parameters set to zero:
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.. code-block:: yaml
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climate:
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- platform: pid
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id: pid_climate
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name: "PID Climate Controller"
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sensor: temperature_sensor
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default_target_temperature: 21°C
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heat_output: heater
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control_parameters:
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kp: 0.0
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ki: 0.0
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kd: 0.0
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2. Create a :doc:`template button </components/button/template>` to start autotuning later:
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.. code-block:: yaml
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button:
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- platform: template
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name: "PID Climate Autotune"
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on_press:
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- climate.pid.autotune: pid_climate
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3. Compile & Upload the new firmware.
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Now you should have a climate entity called *PID Climate Controller* and a button called
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*PID Climate Autotune* visible in your frontend of choice.
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The autotune algorithm works by repeatedly switching the heat/cool output to full power and off.
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This induces an oscillation of the observed temperature and the measured period and amplitude
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is automatically calculated. To do this, it needs to observe at least 3 oscillation cycles.
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.. note::
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You **have to set the setpoint** of the climate controller to a value the
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device can reach. For example if the temperature of a room is to be controlled, the setpoint needs
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to be above the ambient temperature. If the ambient temperature is 20°C, the setpoint of the
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climate device should be set to at least ~24°C so that an oscillation can be induced.
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Also take care of external influences, like for example when room temperature is severely affected by
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outdoor weather like sun, if it starts to warm up the room in parallel with the heating
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autotune will likely fail or give false results.
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4. Set an appropriate setpoint (see note above) and turn on the climate controller (Heat, Cool or Auto).
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5. Click the *PID Climate Autotune* button and look at the the logs of the device.
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You should see output like
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.. code-block:: text
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PID Autotune:
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Autotune is still running!
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Status: Trying to reach 24.25 °C
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Stats so far:
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Phases: 4
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Detected 5 zero-crossings
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# ...
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.. note::
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In the output above, the autotuner is driving the heating output at 100% and trying to reach 24.25 °C.
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This will continue for some time until data for 3 phases (6 crossings of the setpoint; or a bit more, depending on
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the data quality) have been acquired.
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The autotune algorithm may take a long time to complete, it depends on the time needed to reproduce the
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heating up and cooling down oscillations the required number of times.
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6. When the PID autotuner has succeeded, output like the one below can be seen:
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.. code-block:: text
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PID Autotune:
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State: Succeeded!
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All checks passed!
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Calculated PID parameters ("Ziegler-Nichols PID" rule):
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control_parameters:
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kp: 0.49460
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ki: 0.00487
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kd: 12.56301
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Please copy these values into your YAML configuration! They will reset on the next reboot.
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As soon as the the autotune procedure finishes, the climate starts to work with the calculated parameters
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so that expected operation can be immediately verified.
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If satisfied, copy the values in ``control_parameters`` into your configuration:
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.. code-block:: yaml
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climate:
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- platform: pid
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# ...
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control_parameters:
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kp: 0.49460
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ki: 0.00487
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kd: 12.56301
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The *PID Climate Autotune* button can be removed from the config, if the results are satisfactory,
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it's not needed anymore.
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7. Complete, compile & upload the updated firmware.
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If the calculated PID parameters are not good, you can try some of the alternative parameters
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printed below the main control parameters in the log output.
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``climate.pid.autotune`` Action
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-------------------------------
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This action starts the autotune process of the PID controller.
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.. code-block:: yaml
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on_...:
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# Basic
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- climate.pid.autotune: pid_climate
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# Advanced
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- climate.pid.autotune:
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id: pid_climate
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noiseband: 0.25
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positive_output: 25%
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negative_output: -25%
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Configuration variables:
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- **id** (**Required**, :ref:`config-id`): ID of the PID Climate to start autotuning for.
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- **noiseband** (*Optional*, float): The noiseband of the process (=sensor) variable. The value
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of the PID controller must be able to reach this value. Defaults to ``0.25``.
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- **positive_output** (*Optional*, float): The positive output power to drive the heat output at.
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Defaults to ``1.0``.
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- **negative_output** (*Optional*, float): The negative output power to drive the cool output at.
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Defaults to ``-1.0``.
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The ``positive_output`` and ``negative_output`` parameters can be used to compensate the heating or the
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cooling process during the autotune, in the cases when they are not changing the temperature at the
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same rate, resulting in a not symmetrical oscillation. The autotune result will print a message when
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it's recommended to repeat the entire procedure with such parameters configured.
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``climate.pid.set_control_parameters`` Action
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---------------------------------------------
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This action sets new values for the control parameters of the PID controller. This can be
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used to manually tune the PID controller. Make sure to take update the values you want on
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the YAML file! They will reset on the next reboot.
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.. code-block:: yaml
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on_...:
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- climate.pid.set_control_parameters:
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id: pid_climate
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kp: 0.0
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ki: 0.0
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kd: 0.0
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Configuration variables:
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- **id** (**Required**, :ref:`config-id`): ID of the PID Climate to start autotuning for.
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- **kp** (**Required**, float): The factor for the proportional term of the PID controller.
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- **ki** (*Optional*, float): The factor for the integral term of the PID controller.
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Defaults to ``0``.
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- **kd** (*Optional*, float): The factor for the derivative term of the PID controller.
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Defaults to ``0``.
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``climate.pid.reset_integral_term`` Action
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------------------------------------------
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This action resets the integral term of the PID controller to 0. This might be necessary under certain
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conditions to avoid the control loop to overshoot (or undershoot) a target.
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.. code-block:: yaml
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on_...:
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# Basic
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- climate.pid.reset_integral_term: pid_climate
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Configuration variables:
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- **id** (**Required**, :ref:`config-id`): ID of the PID Climate being reset.
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``pid`` Sensor
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--------------
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Additionally, the PID climate platform provides an optional sensor platform to monitor
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the calculated PID parameters to help finding good PID values.
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.. code-block:: yaml
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sensor:
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- platform: pid
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name: "PID Climate Result"
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type: RESULT
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Configuration variables:
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- **name** (**Required**, string): The name of the sensor
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- **type** (**Required**, string): The value to monitor. One of
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- ``RESULT`` - The resulting value (sum of P, I, and D terms).
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- ``ERROR`` - The calculated error (setpoint - process_variable)
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- ``PROPORTIONAL`` - The proportional term of the PID controller.
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- ``INTEGRAL`` - The integral term of the PID controller.
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- ``DERIVATIVE`` - The derivative term of the PID controller.
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- ``HEAT`` - The resulting heating power to the supplied to the ``heat_output``.
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- ``COOL`` - The resulting cooling power to the supplied to the ``cool_output``.
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- ``KP`` - The current factor for the proportional term of the PID controller.
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- ``KI`` - The current factor for the integral term of the PID controller.
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- ``KD`` - The current factor for the differential term of the PID controller.
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Advanced options:
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- **climate_id** (*Optional*, :ref:`config-id`): The ID of the pid climate to get the values from.
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See Also
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--------
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- Ziegler-Nichols Method: Nichols, N. B. and J. G. Ziegler (1942), 'Optimum settings for automatic
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controllers', Transactions of the ASME, 64, 759-768
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- Åström, K. J. and T. Hägglund (1984a), 'Automatic tuning of simple regulators',
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Proceedings of IFAC 9th World Congress, Budapest, 1867-1872
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- :doc:`/components/climate/index`
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- :doc:`/components/output/sigma_delta_output`
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- :doc:`/components/output/slow_pwm`
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- `Principles of PID <https://blog.opticontrols.com/archives/344>`__
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- :apiref:`pid/pid_climate.h`
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- :apiref:`PID Autotuner <pid/pid_autotuner.h>`
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- :ghedit:`Edit`
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