<?xml version="1.0"?>
<!--
use "man thermal-conf.xml" for details
-->
<!-- BEGIN -->
<ThermalConfiguration>
<Platform>
<Name>Generic X86 Laptop Device</Name>
<ProductName>EXAMPLE_SYSTEM</ProductName>
<Preference>QUIET</Preference>
<ThermalSensors>
<ThermalSensor>
<Type>TSKN</Type>
<AsyncCapable>1</AsyncCapable>
</ThermalSensor>
</ThermalSensors>
<ThermalZones>
<ThermalZone>
<Type>SKIN</Type>
<TripPoints>
<TripPoint>
<SensorType>TSKN</SensorType>
<Temperature>55000</Temperature>
<type>passive</type>
<ControlType>SEQUENTIAL</ControlType>
<CoolingDevice>
<index>1</index>
<type>rapl_controller</type>
<influence> 100 </influence>
<SamplingPeriod> 16 </SamplingPeriod>
</CoolingDevice>
<CoolingDevice>
<index>2</index>
<type>intel_powerclamp</type>
<influence> 100 </influence>
<SamplingPeriod> 12 </SamplingPeriod>
</CoolingDevice>
</TripPoint>
</TripPoints>
</ThermalZone>
</ThermalZones>
</Platform>
<!-- Thermal configuration example only -->
<Platform>
<Name>Example Platform Name</Name>
<!--UUID is optional, if present this will be matched -->
<!-- Both product name and UUID can contain
wild card "*", which matches any platform
-->
<UUID>Example UUID</UUID>
<ProductName>Example Product Name</ProductName>
<Preference>QUIET</Preference>
<ThermalSensors>
<ThermalSensor>
<!-- New Sensor with a type and path -->
<Type>example_sensor_1</Type>
<Path>/some_path</Path>
<AsyncCapable>0</AsyncCapable>
</ThermalSensor>
<ThermalSensor>
<!-- Already present in thermal sysfs,
enable this or add/change config
For example, here we are indicating that
sensor can do async events to avoid polling
-->
<Type>example_thermal_sysfs_sensor</Type>
<!-- If async capable, then we don't need to poll -->
<AsyncCapable>1</AsyncCapable>
</ThermalSensor>
<ThermalSensor>
<!-- Examle of a virtual sensor. This sensor
depends on other real sensor or
virtual sensor.
E.g. here the temp will be
temp of example_sensor_1 * 0.5 + 10
-->
<Type>example_virtual_sensor</Type>
<Virtual>1</Virtual>
<SensorLink>
<SensorType>example_sensor_1</SensorType>
<Multiplier> 0.5 </Multiplier>
<Offset> 10 </Offset>
</SensorLink>
</ThermalSensor>
</ThermalSensors>
<ThermalZones>
<ThermalZone>
<Type>Example Zone type</Type>
<TripPoints>
<TripPoint>
<SensorType>example_sensor_1</SensorType>
<!-- Temperature at which to take action -->
<Temperature> 75000 </Temperature>
<!-- max/passive/active
If a MAX type is specified, then
daemon will use PID control
to aggresively throttle to avoid
reaching this temp.
-->
<type>max</type>
<!-- SEQUENTIAL | PARALLEL
When a trip point temp is violated, then
number of cooling device can be activated.
If control type is SEQUENTIAL then
It will exhaust first cooling device before trying
next.
-->
<ControlType>SEQUENTIAL</ControlType>
<CoolingDevice>
<index>1</index>
<type>example_cooling_device</type>
<!-- Influence will be used order cooling devices.
First cooling device will be used, which has
highest influence.
-->
<influence> 100 </influence>
<!-- Delay in using this cdev, this takes some time
too actually cool a zone
-->
<SamplingPeriod> 12 </SamplingPeriod>
</CoolingDevice>
</TripPoint>
</TripPoints>
</ThermalZone>
</ThermalZones>
<CoolingDevices>
<CoolingDevice>
<!--
Cooling device can be specified
by a type and optionally a sysfs path
If the type already present in thermal sysfs
no need of a path.
Compensation can use min/max and step size
to increasing cool the system.
Debounce period can be used to force
a waiting period for action
-->
<Type>example_cooling_device</Type>
<MinState>0</MinState>
<IncDecStep>10</IncDecStep>
<ReadBack> 0 </ReadBack>
<MaxState>50</MaxState>
<DebouncePeriod>5000</DebouncePeriod>
<!--
If there are no PID parameter
compensation increase step wise and exponentaially
if single step is not able to change trend.
Alternatively a PID parameters can be specified
then next step will use PID calculation using
provided PID constants.
-->>
<PidControl>
<kp>0.001</kp>
<kd>0.0001</kd>
<ki>0.0001</ki>
</PidControl>
</CoolingDevice>
</CoolingDevices>
</Platform>
</ThermalConfiguration>
<!-- END -->
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