.. _SD.PlatformPowerAndPerformance.JetsonXavierNxandJetsonAgxXavier: .. include:: /content/swdocs.rsts .. spelling:: AO aotag bpmp chipset cpufreq cpuidle crit curr debugfs devfreq dtsi etherwake hwmon iio Kickstart kickstart init MaxN millidegrees milliohms milliwatts nct nvfancontrol pid powermon runlevel SCy SoC soctherm systemd Tboard Tdiode tegra tegrastats thermtrip Tmargin wakeup SC7 DT Jetson Xavier NX Series and Jetson AGX Xavier Series !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! This topic describes power and performance management features of |NVIDIA(r)| |Jetson Xavier(tm) NX| series and |NVIDIA(r)| |Jetson AGX Xavier(tm)| series devices. It describes the power, thermal, and electrical management features visible to software, as well as some tools and related techniques. .. note:: These devices' power management features are very similar, and most of this document applies equally to both. For convenience, the text often refers to them by the shorter name *Jetson Xavier*. This term is used solely for convenience, and is not a product name. Jetson Xavier and |NVIDIA(r)| |Jetson(tm)| Board Support Package (BSP) provide many features related to power management, thermal management, and electrical management. These features deliver the best user experience possible given the constraints of a particular platform. They help to create a user experience of: - Uniformly high performance - Excellent battery life - Perfect stability - Cool operation (the device is comfortable to touch) Interacting Features @@@@@@@@@@@@@@@@@@@@ Power, thermal, and electrical management features place dynamic constraints on many operational settings (“knobs”), such as: - Clock gate settings - Clock frequencies - Power gate (or regulator enable) settings - Voltages - Processor power state (for example, which idle state is selected for the CPU) - Peripheral power state (for example, which idle state is selected for an I/O controller) - Chipset power state - Availability of CPU cores to the OS Some of these knobs are constrained by more than one feature. For example, ``cpufreq`` implements **load-based scaling**, which adjusts the CPU frequency according to how busy the CPU is. CPU thermal management, however, can override the target frequency of ``cpufreq``. Consequently, before you attempt to debug power, performance, thermal, or electrical problems, you must familiarize yourself with all of the power, thermal, and electrical management features in BSP. Kernel Space Power Saving Features @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ This section describes BSP features that save power and extend battery life. Many of these features are implemented by the Linux kernel, with support from firmware and hardware, and without significant involvement from the user space. Chipset Power States #################### The supported power states are listed in order of increasing flexibility or configurability: - **Off:** There is only one way for a system to be off. - **Deep Sleep (SC7)** offers a small amount of configurability. For example, before entering Deep Sleep, the software can select which hardware wake events can wake the chip from Deep Sleep. - **Active state** is extraordinarily flexible in terms of power and performance. It encompasses activity levels from low-power audio playback through peak performance. Power consumption in the Active state can range from tens of milliwatts to several watts. Supported Power States $$$$$$$$$$$$$$$$$$$$$$ The supported power states are: +------------------+-------------------------------------------------+ | Power State | Characteristics | +==================+=================================================+ | Off | **Power rails**: None of the power rails | | | supplying the SoC and DRAM are powered. | | | | | | **State**: No state is maintained in the SoC or | | | DRAM. | | | | | | **Exiting**: Into Active state via cold boot. | +------------------+-------------------------------------------------+ | Deep Sleep (SC7) | **Power rails**: ``VDD_RTC``, ``VDDIO_DDR``, | | | ``VDDIO_SYS``, and DRAM power rails are powered | | | on. VDD_CORE and VDD_CPU are powered off. | | | | | | **State**: The SoC maintains a small amount of | | | state information in the PMC block. DRAM | | | maintains the state. | | | | | | **Exiting**: Into Active state via a | | | predefined set of wake events. | +------------------+-------------------------------------------------+ | Active | **Power rails**: ``VDD_RTC``, ``VDDIO_DDR``, | | | ``VDDIO_SYS``, ``VDD_CORE``, and DRAM rails are | | | powered on. Other power rails, including | | | ``VDD_CPU``, may be powered on. | | | | | | **State**: Software actively manages the power | | | states of the devices that make up the SoC. | | | | | | **Exiting**: Software can initiate a transition | | | from Active to any other power state. | +------------------+---------------+---------------------------------+ Power State Mapping to Linux $$$$$$$$$$$$$$$$$$$$$$$$$$$$ BSP maps chipset power states to Linux power states as follows. +---------------------+---------------------+----------------------------------+ | Chipset power state | Linux power state | Comments | +=====================+=====================+==================================+ | Off | Off | — | +---------------------+---------------------+----------------------------------+ | Deep Sleep (SC7) | Suspend to RAM | The software can choose whether | | | | to enter Deep Sleep before the OS| | | | enters Suspend. | +---------------------+---------------------+----------------------------------+ | Active | Running/Idle | Many SoC devices may be idle or | | | (display on or off) | disabled under driver control. | | | | For example, ``VDD_GPU`` may be | | | | powered off and the companion | | | | GPU may be power-gated. | +---------------------+---------------------+----------------------------------+ Deep Sleep (SC7) $$$$$$$$$$$$$$$$ If the systemd init system is being used, you can initiate deep sleep from the user space with the following command:: $ sudo systemctl suspend You can also use the following command:: $ sudo bash -c "echo mem > /sys/power/state" The first method of entering deep sleep is preferred because it cooperates better with systemd, which maintains the Linux runlevel. If your system is not running systemd, use the second method. The system can be awakened from deep sleep by common wake sources available on Jetson platforms: +------------------+------------------------------------------------------------------------------+ | Wake source | Usage | +==================+==============================================================================+ | Power button | Press and release the power button on the Jetson device. If the power button | | | is not available, connect and disconnect the power button pin and ground. | +------------------+------------------------------------------------------------------------------+ | RTC alarm | Before entering low power state, program the RTC alarm with the following | | | command:: | | | | | | $ sudo bash -c "echo +10 > /sys/class/rtc/rtc/wakealarm" | | | | | | where ```` is the RTC ID. The ``rtc`` indicates the RTC used by system| | | and can be found with the following command:: | | | | | | $ find /sys/class/rtc/* -maxdepth 0 -printf "%f:" -exec bash -c \ | | | "cat {}/hctosys" \; | grep :1 | cut -d: -f1 | head -n1 | | | | +------------------+------------------------------------------------------------------------------+ | USB type-C cable | To flash the device, connect or disconnect a USB cable to the USB type-C | | hotplug | port. | +------------------+------------------------------------------------------------------------------+ | USB remote | Press any key on a USB keyboard connected to the device. | +------------------+------------------------------------------------------------------------------+ | Wake on LAN | On another machine on the same LAN, enter:: | | | | | | $ sudo etherwake -i | +------------------+------------------------------------------------------------------------------+ | SD card | Insert or remove SD card. | | detection | | +------------------+------------------------------------------------------------------------------+ Clock and Voltage Management @@@@@@@@@@@@@@@@@@@@@@@@@@@@ Because clock frequency is proportional to voltage, dynamic voltage scaling is closely related to frequency scaling. For example, higher clock frequencies require higher voltages and vice versa. Most clock register manipulation on Jetson Xavier is handled by the Boot and Power Management (BPMP) firmware, which runs on the BPMP processor. A Linux kernel driver on the CPU exposes a somewhat simplified view of the physical clock tree to software on the main CPU via the Linux Common Clock Framework. Each of the significant clock domains on the chip has its own dedicated clock source, known as a **Noise Aware Frequency Lock Loop** (NAFLL). Regulator Framework ################### The Linux regulator framework provides an abstraction that allows regulator consumer drivers to dynamically adjust voltage or current regulators at runtime, without knowledge of the underlying hardware power tree. The framework provides a mechanism that platform initialization code can use to declare a power tree topology and assign a driver that provides regulators for each node in the hardware power tree. Such a driver is called a **regulator provider driver**. BSP configures the platform power tree appropriately for Jetson Xavier. Additionally, drivers within BSP act as regulator consumers, where appropriate. When you port BSP to a new platform, you must ensure that: - The platform power tree is configured to match the underlying hardware. - All drivers for peripheral devices use the regulator consumer APIs correctly. - The device tree and board configuration file information for your new platform avoid conflicts between functions using the same I/O pads. BSP drivers registering as regulator consumers can cause I/O pads on the chip to be unavailable for other functions. The SoC core power rails (``VDD_CORE``, ``VDD_CPU``, ``VDD_GPU``, and ``VDD_CV``) are under the direct control of the BPMP firmware. They are configured via the BPMP device tree blob (which is distinct from the Linux device tree blob). CPU Power Management @@@@@@@@@@@@@@@@@@@@ The CPU power management strategy uses **dynamic frequency scaling** (DFS) with dynamic voltage scaling, idle power states, and core management tuned for the Jetson Xavier architecture. Frequency Management with cpufreq ################################# BSP implements CPU dynamic frequency scaling with the Linux ``cpufreq`` subsystem. The cpufreq subsystem comprises: - Platform drivers to implement the clock adjustment mechanism - Governors to implement frequency scaling policies - A core framework to connect governors to platform drivers The policy for frequency scaling depends on which ``cpufreq`` governor is selected at runtime. For details, see the information at:: /kernel/kernel-5.10/Documentation/admin-guide/pm/cpufreq.rst For each Jetson platform, NVIDIA selects a ``cpufreq`` governor and tunes it to achieve a balance between power and performance. When a governor requests a CPU frequency change, the ``cpufreq`` platform driver reconciles that request with constraints imposed by thermal or electrical limits, and updates the CPU clock speed. Jetson Xavier uses an NAFLL to clock each CPU. The NAFLLs are configured for Adaptive Voltage and Frequency Scaling (AVFS). Hardware, with the assistance of the BPMP firmware, ensures that the CPU voltage is appropriate for the NAFLL to deliver requested CPU frequencies. Idle Management with cpuidle ############################ The Linux ``cpuidle`` infrastructure supports the implementation of SoC-specific idle states for each CPU core. ``cpuidle`` lacks direct support for idle states that are applicable to an entire CPU cluster or that extend beyond a CPU cluster. For more information about the Linux ``cpuidle`` infrastructure, see:: /kernel/kernel-5.10/Documentation/admin-guide/pm/cpuidle.rst CPU Idle $$$$$$$$ NVIDIA provides an SoC-specific ``cpuidle`` driver that plugs into the ``cpuidle`` framework to enable CPU idle power management. For each core there is an idle task that is scheduled when no other runnable tasks are left in that core's run queue. This task places the core in a low-power state selected by the ``cpuidle`` governor. The core stays in that state until an interrupt wakes it up to process more work. When the last active core in a CPU cluster goes into an idle or offline state, the idle task puts the entire CPU cluster in a low-power state. Idle States $$$$$$$$$$$ The table below summarizes the CPU core and cluster idle states available on Jetson Xavier, and the BSP software support for them. Core states are denoted as C\ *x* states, and cluster states are denoted as CC\ *x* states. +-------------------+-------+------------------------------------+-----------+ | | | | Software | | Type of state | State | Meaning | support? | +===================+=======+====================================+===========+ | Core state | C1 | Clock gating | Yes | | +-------+------------------------------------+-----------+ | | C6 | Virtual retention (power gating | Yes \* | | | | and architecture state restored by | | | | | MTS) | | | +-------+------------------------------------+-----------+ | | C7 | Power gating | No | +-------------------+-------+------------------------------------+-----------+ | Cluster state | CC1 | Auto clock gating | Yes | | +-------+------------------------------------+-----------+ | | CC3 | f\ :sub:`max`\ @V\ :sub:`min` or | Yes | | | | specified idle frequency | | | +-------+------------------------------------+-----------+ | | CC6 | Cluster power gating (includes | Yes † | | | | non-CPU logic) | | +-------------------+-------+------------------------------------+-----------+ | \* C6 is disabled by default because the ``min-residency-us`` device tree | | property of C6 is set to ``0xffffffff``. | | | | † Because C6 is disabled by default, there is no change to enter CC6. | | To enable C6/CC6, see | | `To enable/disable a core/cluster power state at boot time | | <#to-enable-disable-a-core-cluster-power-state-at-boot-time>`__. | +----------------------------------------------------------------------------+ To enable CPU idle $$$$$$$$$$$$$$$$$$ To enable CPU idle you must enable the appropriate kernel configuration option and the appropriate device tree node. Enabling either one alone is not effective. - To enable CPU idle in the configuration file, set the option:: CONFIG_CPU_IDLE=y CONFIG_CPU_IDLE_TEGRA19X=y - To enable CPU idle in the device tree, enable the device tree node cpuidle:: cpuidle { compatible = "nvidia,tegra19x-cpuidle"; status = "okay"; }; To disable cpuidle at boot time $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Disable the device tree node ``cpuidle``. To display CPU idle status $$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter these commands to determine whether CPU idle is enabled by sysfs:: $ cat /sys/devices/system/cpu/cpuidle/current_driver If CPU idle is enabled, the command displays:: tegra19x_cpuidle_driver To enable/disable a core/cluster power state at boot time $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - To enable a core/cluster power state, set the following properties of the appropriate core/cluster state node: - status to ``"okay"`` - ``min-residency-us`` to a reasonable value For example, to enable power state C6 with ``min-residency-us`` = 50000:: c6 { compatible = "nvidia,tegra194-cpuidle-core"; idle-state-name = "Virtual core powergate"; wakeup-latency-us = <2000>; min-residency-us = <50000>; power = <0x3c>; pmstate = <0x6>; arm,psci-suspend-param = <0x6>; status = "okay"; phandle = <0x26d>; }; - To disable a core/cluster power state, use either of the following procedures. (Both procedures apply to the device tree ``tegra194-cpuidle.dtsi``.) - Remove or disable the appropriate core/cluster state node. or - Modify the appropriate core/cluster state node by setting the ``min-residency-us`` property to a high value, e.g., ``0xffffffff``. For example, to disable power state C6:: c6 { compatible = "nvidia,tegra194-cpuidle-core"; idle-state-name = "Virtual core powergate"; wakeup-latency-us = <2000>; min-residency-us = <0xffffffff>; power = <0x3c>; pmstate = <0x6>; arm,psci-suspend-param = <0x6>; status = "okay"; phandle = <0x26d>; }; To get and set a CPU core’s power state $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ The pathnames of the nodes that represent core power states are:: /sys/devices/system/cpu/cpu/cpuidle/state Where: - ```` is a core ID. - ```` is the index of the core power state: 0 for C1, or 1 for C6. .. note:: A core power state’s status is 1 if the state is disabled, and 0 if it is enabled\ |mdash|\ the *reverse* of the usual Boolean sense of 0 and 1. To get the status of core power state ```` on core ````, read the appropriate node. To set the status, write an ASCII 0 to 1 to the node. Following are several useful commands for getting and setting the core power state: - To display the name of the core power state with index ````, enter the command:: $ cat /sys/devices/system/cpu/cpu/cpuidle/state/name For example, this command displays the name of state0:: $ cat /sys/devices/system/cpu/cpu/cpuidle/state0/name - To get the status of core power state with index ```` on core ````:: $ cat /sys/devices/system/cpu/cpu/cpuidle/state/disable - To change the status of core power state with index ```` on CPU core ````:: $ echo > /sys/devices/system/cpu/cpu/cpuidle/state/disable .. note: Remember that a status of 1 *disables* the core power state, and 0 *enables* it. To get cluster states $$$$$$$$$$$$$$$$$$$$$ - To get the status of the cluster states enabled for each cluster, read this node:: /sys/kernel/debug/tegra_cpuidle/deepest_cc_state The value returned is: - 1: Only CC1 is enabled - 6: CC1 and CC6 are enabled To get the per-core state usage statistics $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - To get the number of times the kernel requested a specified core to enter a specified state, read this node:: $ cat /sys/devices/system/cpu/cpu/cpuidle/state/usage - To get the number of times a specified core actually entered a specified state, enter the command:: $ cat /sys/kernel/debug/tegra_mce/cstats For example, to get the number of times that core 2 has entered power state1, enter the command:: $ cat /sys/devices/system/cpu/cpu2/cpuidle/state1/usage - To get the total time in microseconds that a specified core has spent in a specified state since boot, read the following device:: $ cat /sys/devices/system/cpu/cpu/cpuidle/state/time Memory Power Management @@@@@@@@@@@@@@@@@@@@@@@ NVIDIA SoC chipsets include power saving features whose operation is largely invisible to software at runtime. Most of those features are statically enabled at boot, according to settings in the boot configuration table (BCT). Additionally, BSP implements Dynamic Voltage and frequency scaling for the memory controller (EMC/MC) and DRAM to save power. The EMC BCT and DVFS table are specific to the board design. The EMC DVFS table is included in the platform BPMP device tree file. EMC Frequency Scaling Policy ############################ The following factors affect EMC frequency scaling policy at runtime: - The entries in the EMC DVFS table - The average memory bandwidth used (as measured by hardware) - Requests made by various device drivers (cpufreq, graphics drivers, USB, |HDMI(r)|, and display) - Any limits dynamically imposed by thermal throttling Supported Modes and Power Efficiency @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ Jetson Xavier is designed with a high efficiency Power Management Integrated Circuit (PMIC), voltage regulators, and power tree to optimize power efficiency. It supports three optimized power budgets, such as 10 watts, 15 watts, and 30 watts. For each power budget, several configurations are possible with various CPU frequencies and number of cores online. Capping the memory, CPU, and GPU frequencies, and number of online CPU, GPU TPC, DLA and PVA cores at a prequalified level confines the module to the target mode. The configurations predefined by NVIDIA are as follows. .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/NvpModelClockConfigurationForJetsonXavierNx.htm .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/NvpModelClockConfigurationForJetsonAgxXavier.htm .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/NvpModelClockConfigurationForJetsonAgxXavierIndustrial.htm Power Mode Controls ################### You can display and change the power mode with the ``nvpmodel`` command. - To change the power mode, enter the command:: $ sudo /usr/sbin/nvpmodel -m Where ```` is the power mode ID (i.e. 0, 1, 2, 3, 4, 5, or 6). Alternatively, use the nvpmodel GUI front end. For more information, see `nvpmodel GUI <#nvpmodel-gui>`__, later in this topic. After you set a power mode, the module stays in that mode until you change it. The mode persists across power cycles and SC7. .. note:: GPU ``tpc_pg_mask`` can be set once before the GPU golden context is created. If the nvpmodel power mode change requires to set the different ``tpc_pg_mask`` value then the system reboot is required. - Example:: ubuntu@jetson:~$ sudo nvpmodel -m 1 [351953.975356] nvgpu: 17000000.gv11b tpc_pg_mask_store:1053 [ERR] golden image size already initialized NVPM ERROR: Error writing 5 to /sys/devices/gpu.0/tpc_pg_mask: 19 NVPM WARN: Reboot required for changing to this power mode: 1 NVPM WARN: DO YOU WANT TO REBOOT NOW? enter YES/yes to confirm: Type ``YES`` or ``yes`` to initiate reboot or press any other key to cancel. The settings will be in effect after the reboot. Ignore the ``NVPM ERROR: Error writing 5 to /sys/devices/gpu.0/tpc_pg_mask: 19`` statement as this is just for the information while change in GPU ``tpc_pg_mask``. - To display the current power mode, enter the command:: $ sudo /usr/sbin/nvpmodel -q Alternatively, see the mode displayed to the right of the NVIDIA icon in the nvpmodel window’s menu bar. For more information, see `nvpmodel GUI <#nvpmodel-gui>`__, later in this topic. - To add a custom power mode definition, edit this file:: /etc/nvpmodel.conf This is an example entry for mode 2:: < POWER_MODEL ID=2 NAME=MODE_15W > CPU_ONLINE CORE_0 1 CPU_ONLINE CORE_1 1 CPU_ONLINE CORE_2 1 CPU_ONLINE CORE_3 1 CPU_ONLINE CORE_4 0 CPU_ONLINE CORE_5 0 CPU_ONLINE CORE_6 0 CPU_ONLINE CORE_7 0 CPU_DENVER_0 MIN_FREQ 1200000 CPU_DENVER_0 MAX_FREQ 1200000 CPU_DENVER_1 MIN_FREQ 1200000 CPU_DENVER_1 MAX_FREQ 1200000 GPU MIN_FREQ 0 GPU MAX_FREQ 670000000 EMC MAX_FREQ 1331200000 DLA_CORE MAX_FREQ 750000000 DLA_FALCON MAX_FREQ 450000000 PVA_VPS MAX_FREQ 550000000 PVA_CORE MAX_FREQ 385000000 The unit of measure for CPU frequency is kilohertz. The unit for GPU and EMMC frequency is hertz. You must assign each custom mode a unique number in the ID field. Test your use case to determine: - How many active cores to use - The frequency for each CPU cluster, and the GPU and EMC frequencies The frequencies you select are subject to the MaxN limit defined in mode 0. - To learn about other options, enter the command:: $ /usr/sbin/nvpmodel -h Fan Profile Control @@@@@@@@@@@@@@@@@@@ Jetson Xavier supports two profiles of fan operation named “quiet” and “cool.” Userspace fan speed control daemon `nvfancontrol <#nvfancontrol>`__ manages fan speed based on the trip point temperatures configured for the selected profile. Fan Profile Configuration ######################### Every fan speed step is associated with the trip point temperature and corresponding hysteresis. The following table shows the configurations predefined by NVIDIA. .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/FanModeConfigurationForJetsonXavierNx.htm .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/FanModeConfigurationForJetsonAgxXavierSeries.htm The framework implements hysteresis to prevent frequent changes in fan speed. For Jetson Xavier, as an example, when fan profile is set to “quiet” with the default settings shown above, the framework performs these actions: - Turns on the fan when the temperature rises to 50\ |degC| - Turns off the fan when the temperature falls to 32\ |degC| - Turns on the fan again when the temperature rises to 50\ |degC|, and so on nvfancontrol ############ nvfancontrol is a userspace fan speed control daemon. This manages the fan speed based on the temperature-to-fan-speed mapping table in the nvfancontrol configuration file. There are some basic elements in the nvfancontrol service, including Tmargin, kickstart PWM, fan profile, fan control, and fan governor. All of these can be programmed via the configuration file based on the user's preferences. This chapter will explain each of them in the following sections. nvfancontrol.conf $$$$$$$$$$$$$$$$$ - Location:: /etc/nvfancontrol.conf - Please find below the example nvfancontrol.conf file for the Jetson Xavier:: POLLING_INTERVAL 2 TMARGIN DISABLED FAN_GOVERNOR pid { STEP_SIZE 10 } FAN_PROFILE quiet { #TEMP HYST PWM RPM 0 0 0 0 50 18 77 1000 63 8 120 2000 72 8 160 3000 81 8 255 4000 140 0 255 5000 150 0 255 6000 160 0 255 7000 170 0 255 10000 180 0 255 11000 } FAN_PROFILE cool { #TEMP HYST PWM RPM 0 0 0 0 35 9 77 1000 53 8 120 2000 62 8 160 3000 73 9 255 4000 140 0 255 5000 150 0 255 6000 160 0 255 7000 170 0 255 10000 180 0 255 11000 } THERMAL_GROUP 0 { GROUP_MAX_TEMP 108 #Thermal-Zone Coeffs Max-Temp CPU-therm 30,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 GPU-therm 30,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 AUX-therm 40,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 } FAN_DEFAULT_CONTROL open_loop FAN_DEFAULT_PROFILE quiet FAN_DEFAULT_GOVERNOR pid Default Fan Profile $$$$$$$$$$$$$$$$$$$ For Jetson Xavier the fan profile is set to “quiet” by default. It is defined as ``FAN_DEFAULT_PROFILE`` in the configuration file ``/etc/nvfancontrol.conf``. To change the default fan profile $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ To change the fan profile, complete the following steps: - Stop the ``nvfancontrol`` systemd service:: sudo systemctl stop nvfancontrol - Set the default fan profile by putting the following property in ``/etc/nvfancontrol.conf``:: FAN_DEFAULT_PROFILE Where ```` is ``quiet`` or ``cool``. - Remove the status file:: sudo rm /var/lib/nvfancontrol/status - Start the ``nvfancontrol`` systemd service:: sudo systemctl start nvfancontrol To identify the current fan profile $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo nvfancontrol -q - Example:: $ sudo nvfancontrol -q FAN1:FAN_PROFILE:quiet ... ... Once you set a fan profile, the module stays in that profile until you change it. The profile persists across power cycles and SC7. Fan Profile Table $$$$$$$$$$$$$$$$$ The fan profile table contains the mapping between temperature and the fan speed. It also contains the hysteresis value for each step and the fan RPM value. - Syntax:: FAN_PROFILE { } Where: : Fan Profile Name : Temperation step in degree celcius : Hysteresis step : Fan PWM value : Fan RPM value - Example:: FAN_PROFILE quiet { #TEMP HYST PWM RPM 0 0 0 0 50 18 77 1000 63 8 120 2000 72 8 160 3000 81 8 255 4000 140 0 255 5000 150 0 255 6000 160 0 255 7000 170 0 255 10000 180 0 255 11000 } TMARGIN $$$$$$$ TMARGIN temperature is the difference between the maximum allowable temperature and the current thermal zone temperature. For example, if the maximum allowable temperature of CPU-therm is 105 degree Celsius, and the current temperature of CPU-therm is 45 degree Celsius, the current TMARGIN temperature of CPU-therm is 60 degree Celsius (105 - 45). Kickstart PWM $$$$$$$$$$$$$ The minimal required PWM value to start the fan from complete stop state is called kickstart PWM. The fan might not start spinning if PWM value is lower than kickstart PWM. Thermal Group $$$$$$$$$$$$$ THERMAL_GROUP contains the list of thermal zones considered for calculating the trip temperature and the group max temperature for calculating the `TMARGIN <#tmargin>`__ temperature. This section contains: - Thermal Group Max temperature:: GROUP_MAX_TEMP This parameter is used only in case when TMARGIN is ENABLED. The Tmargin temperature is calculated as shown in `TMARGIN <#tmargin>`__ section. - Thermal zone name, coefficients and the thermal zone max temperature:: ,...., Where: : Thermal zone name : Coefficients used for calculating weighted average. Please note that only is taken into consideration as of now. : Thermal zone max temperature. This is used only when Tmargin is ENABLED. If GROUP_MAX_TEMP specified then this temperature will be ignored. - Here is an example for calculating weighted average temperature with Tmargin disabled. Consider that the current CPU-therm is 40 degree Celsius, GPU-therm is 40 degree Celsius, and AUX-therm is 38 degree Celsius, then weighted average temperature = 40 * 0.3 + 40 * 0.3 + 38 * 0.4 = 39 degree Celsius with below thermal group:: THERMAL_GROUP 0 { GROUP_MAX_TEMP 105 #Thermal-Zone Coeffs Max-Temp CPU-therm 30,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 GPU-therm 30,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 AUX-therm 40,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 0 } Fan Control $$$$$$$$$$$ Here are the fan control types in the nvfancontrol service: - open-loop: The open-loop fan control adjusts the fan speed by setting the desired PWM value based on the current trip temperature step. The RPM values in the profile are ignored. - closed-loop: The closed-loop fan control makes the fan spin close to the desired RPM value based on the current trip temperature step. The PWM values in the profile are ignored. To have the fan spin at the exact same speed as the target RPM, there will be a performance drop and the risk of shorter fan life due to the constant adjustment of the speed. So, there is a programmable tolerance value between the target RPM and the current RPM value (an rpm difference within 100 is acceptable in the below example):: FAN_CONTROL close_loop { RPM_TOLERANCE 100 } Fan Governor $$$$$$$$$$$$ The fan governor decides the fan speed control logic based on the fan profile. There are two kinds of fan governors in the nvfancontrol service: pid and cont. - The following profile with Tmargin disabled and open-loop control can be used to explain how different fan governors handle it:: TMARGIN DISABLED FAN_PROFILE quiet { #TEMP HYST PWM RPM 0 0 0 0 50 18 77 1000 63 8 120 2000 72 8 160 3000 81 8 255 4000 140 0 255 5000 150 0 255 6000 160 0 255 7000 170 0 255 10000 180 0 255 11000 } - pid: - The pid governor will change the fan speed only when the weighted average temperature crosses the trip temperature step. The curve between the weighted average temperature and fan speed resembles a stair. - For example, when a weighted average temperature increasing, and the current weighted average temperature is 50 degree Celsius, the PWM will be set to 77. Later even when the weighted average temperature goes to 62 degree Celsius, the PWM will still be set to 77. When the weighted average temperature goes to 63 degree Celsius, the PWM will be set to 120 until the next trip temperature step is crossed. - cont: - The cont governor will linearly interpolate the fan speed based on the upper and lower fan speed between the trip temperature steps. Compared to the pid governor, the curve between temperature and fan speed is more continuous. - For example, when the current weighted average temperature is 55 degree Celsius, the PWM will be set to 93 (77 + (55 - 50) * (120 - 77) / (63 - 50)). Hysteresis in nvfancontrol $$$$$$$$$$$$$$$$$$$$$$$$$$ In nvfancontrol, hysteresis is used to define the fan speed change temperature threshold when using pid governor. - Consider below profile with Tmargin enabled:: TMARGIN ENABLED FAN_PROFILE cool { #TEMP HYST PWM RPM 0 0 255 2900 18 9 255 2900 30 11 202 2300 45 11 149 1700 60 14 88 1000 105 0 0 0 } The fan will be turned on when the Tmargin temperature reaches 60 degree Celsius. Later when the Tmargin temperature keeps increasing, after the Tmargin temperature goes over 74 degree Celsius (60 + 14 = 74) the fan will be turned off. Polling Interval $$$$$$$$$$$$$$$$ nvfancontrol daemon polls the thermal zone temperatures at the time interval specified by POLLING_INTERVAL and sets the fan speed value specified as per TEMPERATURE - FAN SPEED mapping table. - Syntax:: POLLING_INTERVAL TMARGIN Configuration $$$$$$$$$$$$$$$$$$$$$ TMARGIN configuration needs to be specified in order for nvfancontrol daemon to depict the `Fan Profile Table <#fan-profile-table>`__ correctly. - **TMARGIN ENABLED Case:** - Formula to calculate the Tmargin temperature:: Tmargin_sensor_temp = GROUP_MAX_TEMP -OR- - - Formula to calculate Tmargin weighted average of the thermal group sensors:: Tmargin_thermgroup_weighted_average = Tmargin_sensor0_temp * sensor0_weight_ratio + Tmargin_sensor1_temp * sensor1_weight_Ratio + ... Where: Tmargin_sensor_temp - Tmargin sensor temperature calculated using above formula. sensor_wight_ratio - Currently only value is considered for weight ratio as mentioned in section "Thermal Group" x - sensor number - TMARGIN ENABLED Table:: TMARGIN ENABLED FAN_PROFILE quiet { #TEMP HYST PWM RPM 0 0 255 0 50 18 160 1000 63 8 120 2000 72 8 77 3000 100 8 0 4000 } Example: Temperature steps defined in the above table are the Tmargin temperatures calculated using the formula mentioned at the start of this section. Consider that the GROUP_MAX_TEMP is set as 108, the current fan governor is pid, and the current fan control is open-loop. So, as specified in the above temperature-to-fan-speed mapping table, the Tmargin trip temperature step 63 degree Celsius corresponds to (108 - 63) = 45 degree Celsius, which is the weighted average of the thermal zone temperature. When the weighted average of the thermal zone temperature reaches 46 degree Celsius, then nvfancontrol sets the fan PWM to 160. The fan PWM will stay at 160 till the weighted average of the thermal zone temperature reaches 58 degree Celsius (108 - 50 = 58) which is the Tmargin trip point step 50 degree Celsius as present in the above table. - **TMARGIN DISABLED Case:** - Formula to calculate weighted average of the thermal group sensors:: thermgroup_weighted_average = sensor0_temp * sensor0_weight_ratio + sensor1_temp * sensor1_weight_Ratio + ... Where: sensor_temp - Current thermal zone temperature. sensor_wight_ratio - Currently only value is considered for weight ratio as mentioned in section "Thermal Group" x - sensor number - TMARGIN DISABLED Table:: TMARGIN DISABLED FAN_PROFILE quiet { #TEMP HYST PWM RPM 0 0 0 0 50 18 77 1000 63 8 120 2000 72 8 160 3000 81 8 255 4000 } Example: Temperature steps defined in the above table are the weighted average of the actual thermal zone temperature. Consider that the current fan governor is pid, and the current fan control is open-loop. As specified in the above temperature-to-fan-speed mapping table, when the actual weighted average of the thermal zone temperature reaches 50 degree Celsius, then nvfancontrol sets the fan PWM to 77. The fan PWM will stay at 77 until the weighted average of the thermal zone temperature reaches 63 degree Celsius and so on. Thermal Management @@@@@@@@@@@@@@@@@@ Thermal management is essential for system stability and quality of user experience. Jetson Xavier thermal management provides the following capabilities: - **Sensing** for `on-board <#on-board-sensors>`__ and `on-chip <#on-chip-sensors>`__ thermal sensor temperature reporting - **Cooldown** for removing heat via the fan and for controlling heat via software clock throttling - **Slowdown** for hardware clock throttling - **Shutdown** for orderly software shutdown and hardware thermal shutdown Thermal management in Jetson Xavier is performed by: - The Linux kernel, which monitors on-board thermal sensors, performs cooldown, and supports software and hardware thermal shutdown - The Board and Power Management Processor (BPMP), which monitors on-chip thermal sensors, and performs slowdown and hardware thermal shutdown The following table identifies each thermal management action and the associated module for the SoC. +----------------------------------+------------------------+-------------------+ | Thermal Action | Linux Device Driver | Associated Module | +==================================+========================+===================+ | Sensing | ``soctherm.c`` | BPMP firmware | + +------------------------+-------------------+ | | ``aotag.c`` | BPMP firmware | + +------------------------+-------------------+ | | ``nct1008.c`` | Kernel software | +----------------------------------+------------------------+-------------------+ | Cooldown for software throttling | ``cpufreq_cooling.c`` | Kernel software | | | ``devfreq_cooling.c`` | | +----------------------------------+------------------------+-------------------+ | Cooldown for fan | ``pwm_fan.c`` | Kernel software | +----------------------------------+------------------------+-------------------+ | Slowdown for hardware throttling | ``soctherm.c`` | BPMP firmware | +----------------------------------+------------------------+-------------------+ | Software shutdown | ``thermal_core.c`` | Kernel software | +----------------------------------+------------------------+-------------------+ | Hardware shutdown | ``soctherm.c`` and | BPMP firmware | | | ``aotag.c`` | | + +------------------------+-------------------+ | | ``nct1008.c`` | Kernel software | +----------------------------------+------------------------+-------------------+ Linux Thermal Framework ####################### The Linux thermal framework provides generic user space and kernel space interfaces for working with devices that measure or control temperature. The central component of the framework is the **thermal zone**. For more information about the Linux thermal framework, see:: /kernel/kernel-5.10/Documentation/driver-api/thermal/sysfs-api.rst Thermal Zone ############ A **thermal zone** is a virtual object that represents an area on the die whose temperature is monitored and controlled. A thermal zone acts as an object with the following components: - Temperature sensor - Cooling device - Trip points - Governor BSP includes drivers that provide interfaces to these components. This topic introduces these components and demonstrates how they form a thermal zone on a Jetson device. Configuring a Thermal Zone Using the Device Tree $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ A thermal zone provides knobs to tune the thermal response of the zone. BSP provides several thermal zones tuned to provide optimum thermal performance. You can modify the provided thermal zones by editing the entries in the kernel device tree. Users can define sensors to use temperature limits and cooling actions on those limits. Device overheating can be resolved in most cases by tuning the thermal zone. The following code snippet provides an example of a thermal zone for Jetson Xavier. This thermal zone monitors the temperature of the THERMAL_ZONE_GPU sensor. Clock throttling is performed using the devfreq cooling device when the passive trip point, ``gpu-sw-throttle``, is crossed at 92.5\ |degC|:: GPU-therm { polling-delay = <0x0>; polling-delay-passive = <0x1f4>; thermal-sensors = <0x28d 0x3>; status = "okay"; thermal-zone-params { governor-name = "step_wise"; }; trips { trip_critical { temperature = <0x17ed0>; type = "critical"; hysteresis = <0x0>; writable; }; gpu-sw-throttle { temperature = <0x16954>; type = "passive"; hysteresis = <0x0>; writable; phandle = <0x298>; }; }; cooling-maps { map0 { trip = <0x298>; cooling-device = <0x299 0xffffffff 0xffffffff>; }; user-alert-map0 { trip = <0x298>; cooling-device = <0x29a 0x1 0x1>; }; }; }; For more information about thermal knobs, see:: /kernel/kernel-5.10/Documentation/devicetree/bindings/thermal/nvidia,tegra186-bpmp-thermal.txt Temperature Sensors $$$$$$$$$$$$$$$$$$$ A temperature sensor in a thermal zone is responsible for reporting the temperature in millidegrees Celsius. Jetson Xavier has several types of temperature sensors on the chip and board. For more information see `Thermal Sensing in Linux <#thermal-management-in-linux>`__. Trip Points and Cooling Devices $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ Thermal management uses **trip points** to communicate with thermal zones. A trip point describes the temperature at which cooling is recommended. Trip points are classified by the type of cooling device is triggered: - **Passive trip points** trigger **passive cooling devices**, which reduce the Jetson device's performance, and so reduce the amount of heat generated. Hardware or software clock throttling (reducing the frequency of a clock) is an example of a passive cooling device. - **Active trip points** trigger **active cooling devices**, which activates a device to remove the dissipated heat. A fan is an example of an active cooling device. - **Critical trip points** trigger a thermal shutdown. A **cooling map** specifies how a cooling device is associated with certain trip points. For more information, see `Thermal Cooling <#thermal-cooling>`__. Governors $$$$$$$$$ A **governor** implements a feedback control loop that keeps a Jetson device within a safe operating temperature range. While the Linux thermal framework provides many different governors, BSP provides a simple **Proportional Integral Derivative (PID) controller** for all passive throttling needs. BSP-Specific Thermal Zones $$$$$$$$$$$$$$$$$$$$$$$$$$ BSP defines platform-specific thermal zones. The zones are tuned to provide the best performance within the thermal constraints of the Jetson device. Each thermal zone uses a temperature sensor that is controlled by either the Linux kernel or the BPMP firmware, as described in the following table. +-----------------+------------------------------+-------------------+ | Thermal Zone | Thermal Sensor | Associated Module | +=================+==============================+===================+ | CPU-therm | ``THERMAL_ZONE_PLLX`` | BPMP firmware | +-----------------+------------------------------+-------------------+ | GPU-therm | ``THERMAL_ZONE_GPU`` | BPMP firmware | +-----------------+------------------------------+-------------------+ | AUX-therm | ``THERMAL_ZONE_AUX`` | BPMP firmware | +-----------------+------------------------------+-------------------+ | AO-therm | ``THERMAL_ZONE_AO`` | BPMP firmware | +-----------------+------------------------------+-------------------+ | Tdiode_tegra | ``tmp451`` | Linux kernel | +-----------------+------------------------------+-------------------+ | PMIC-Die | Power management integrated | Linux kernel | | | circuit (PMIC) | | +-----------------+------------------------------+-------------------+ | Tboard_tegra | ``tmp451`` | Linux kernel | +-----------------+------------------------------+-------------------+ For more information, see `Thermal Management in BPMP <#thermal-management-in-bpmp>`__. Gains achieved by tuning are limited by the Thermal Design Power (TDP) of the system. Tuning cannot remedy a faulty TDP. Removing all of the thermal zones does not guarantee maximum performance, and can cause resets and/or irreversible damage to the device. Thermal Management in Linux @@@@@@@@@@@@@@@@@@@@@@@@@@@ The Linux kernel provided by BSP includes several drivers for on-board and on-chip temperature sensing. Thermal Sensors ############### Jetson Xavier series has several types of sensors to support hardware and software cooling strategies. On-board Sensors $$$$$$$$$$$$$$$$$ BSP includes a driver for on-board sensor devices such as: - NCT1008 - NCT72 - TMP451 .. note:: Jetson Xavier NX does not have any on-board sensor. These devices can sense their own temperature as well as the temperature of a remote diode. Jetson platforms have these sensors set up as follows: ============ ============== =========================== Thermal Zone Thermal Sensor Sensed Location ============ ============== =========================== Tdiode_tegra Remote sensor Temperature on die near GPU Tboard_tegra Local sensor Temperature of the board ============ ============== =========================== BSP configures these sensors to operate in an extended mode to increase the temperature range to −64\ |degC| to 191\ |degC|. Operation in SC7 $$$$$$$$$$$$$$$$ The voltage rail that powers the on-board sensor is gated when the SoC enters the SC7 state on most Jetson Platforms. Consequently, the sensor is stopped when the SoC enters SC7 and restarted when it exits that state. Thermal Capabilities $$$$$$$$$$$$$$$$$$$$ The On-board sensors generate thermal events for: - Thermal zone trip points - Hardware thermal shutdown Correction Offset $$$$$$$$$$$$$$$$$ The on-board sensors allow software to program a static offset temperature for the remote sensor. This accounts for any inaccuracy that may be present in the sensor hardware. BSP reads the offset from the device tree and programs it into the offset register on boot. The offset is calculated and validated via oil bath experiments. On-chip Sensors $$$$$$$$$$$$$$$ The on-chip `SOC_THERM <#soc-therm>`__ and `AOTAG <#aotag>`__ thermal sensors are controlled by BPMP firmware and tegra-bpmp-thermal Linux kernel driver. The BPMP firmware exposes each on-chip thermal sensor using the **Application Binary Interface** (ABI), and has an ABI name shown in the table in `BSP-Specific Thermal Zones <#bsp-specific-thermal-zones>`__. The on-chip sensors, with the ``THERMAL_ZONE`` prefix, work as described in the following paragraphs. The BPMP firmware has one programmable temperature threshold (one trip) for each on-chip sensor, allocated for a Linux thermal zone trip point. The ``tegra_bpmp_thermal`` driver walks through the list of thermal trip points in a Linux thermal zone based on the current temperature. It then comes up with a trip to program the sensor temperature threshold in BPMP firmware. The driver then uses the following thermal message requests (MRQs) to communicate with the BPMP thermal framework. - ``CMD_THERMAL_QUERY_ABI`` - ``CMD_THERMAL_GET_TEMP`` - ``CMD_THERMAL_SET_TRIP`` - ``CMD_THERMAL_GET_NUM_ZONES`` The driver receives a ``CMD_THERMAL_HOST_TRIP_REACHED`` MRQ message when a particular sensor crosses a trip. The message is then relayed back to the Linux thermal framework. .. figure:: JetsonXavierNxAndJetsonAgxXavier/ThermalFrameworkArchitecture.svg :alt: Jetson Xavier termal framework architecture :figwidth: 650 px For more information on thermal management features provided as part of BSP, see `Thermal Management in BPMP <#hardware-thermal-shutdown>`__. Thermal Cooling ############### BSP provides thermal management using fan control and throttling of various clocks in the system. Fan Management $$$$$$$$$$$$$$ BSP provides active cooling by fan management through the ``pwm-fan`` driver, controlled by `nvfancontrol <#nvfancontrol>`__, which provides: - Fan speed control by programming the PWM controller - Ramp-up and ramp-down control to change the speed of the fan smoothly - Fan control during various power states SoC thermal management uses the fan as the first line of defense to delay clock throttling until a much higher temperature is reached. Software Clock Throttling $$$$$$$$$$$$$$$$$$$$$$$$$ BSP provides thermal cooling by throttling various clocks in the system. When a thermal sensor’s temperature rises above a throttling trip point, clock throttling employs the DVFS capabilities of the clocks to reduce their operating frequencies, and thereby the voltages of the rails that power the clocks. This reduction in frequency and voltage reduces power consumption which helps to control the temperature. Because BSP provides cooling by reducing the clock frequency, it directly impacts performance and the user experience. If a device feels warm and seems sluggish, it may be due to thermal throttling on the clocks. This can be remedied by tuning the trip points and cooling devices of thermal zones. BSP Provides following cooling devices for software clock throttling: - ``cpufreq_cooling`` - ``devfreq_cooling`` Each of these cooling devices provides several cooling states, each of which translates to a maximum allowable operating frequency for the CPU, GPU, and EMC clocks. These frequencies are optimized to provide the best possible performance at a given temperature. The frequency tables for these clocks are part of the device tree binary. The governor uses the current temperature of a thermal zone as an input to the feedback control loop. Similarly, it uses the output of the control loop to set a new cooling state for the thermal zone’s cooling device. As the device heats up the governor picks progressively higher cooling states, which result in higher frequency caps for all of the clocks, and potentially greater cooling. BSP performs this thermal throttling of the clocks to maintain the junction temperature of the die within the recommended safe limits. For software throttling trip temperatures, see the table in `Thermal Specifications <#thermal-specifications>`__. Software Thermal Shutdown $$$$$$$$$$$$$$$$$$$$$$$$$ A **critical trip point** triggers a software thermal shutdown. It allows the operating system to save its state and perform an orderly shutdown before a hardware thermal reset occurs. A software thermal shutdown is considered a rare event. It occurs after all other cooling strategies have failed. BSP defines one critical trip point per thermal zone. You can set the lower limit for the orderly shutdown. For software thermal shutdown trip temperatures, see the table in `Thermal Specifications <#thermal-specifications>`__. Hardware Thermal Shutdown $$$$$$$$$$$$$$$$$$$$$$$$$ The on-chip and on-board sensors can trigger hardware shutdown when all other cooling strategies have failed, and software shutdown has failed to occur when it should. For hardware shutdown limits, see the table in `Thermal Specifications <#thermal-specifications>`__. Thermal Management in BPMP @@@@@@@@@@@@@@@@@@@@@@@@@@ BSP thermal management features are part of the firmware running on BPMP for Jetson platforms running any host operating system (host OS) on the CPU. Thermal Sensing ############### The BPMP firmware hosts the soctherm and aotag drivers for the on-chip thermal sensors as follows: +----------------+----------+-------------------+-----------------------------------+ | Thermal Sensor | ABI Name | Sensed Location | | +================+==========+===================+===================================+ | AOTAG | AOTAG | THERMAL_ZONE_AO | Co-locate with TDIODE in pad-ring | +----------------+----------+-------------------+-----------------------------------+ | SOC_THERM | PLLX | THERMAL_ZONE_PLLX | Center of CPU cluster | | +----------+-------------------+-----------------------------------+ | | AUX (x3) | THERMAL_ZONE_AUX | Near CV cluster, SoC cluster | | +----------+-------------------+-----------------------------------+ | | CPU | THERMAL_ZONE_CPU | Center of CPU cluster | | +----------+-------------------+-----------------------------------+ | | GPU | THERMAL_ZONE_GPU | Center of GPU | +----------------+----------+-------------------+-----------------------------------+ SOC_THERM ######### ``SOC_THERM`` is the collection of on-chip ring oscillators whose frequency changes are based on temperature. To convert a measured frequency to a temperature, the oscillating frequency of the sensor, at a fixed temperature, must be known in advance and stored in the on-chip fuses. The BPMP firmware ``soctherm`` driver uses these fuses during boot and calibrates the sensor. Once the calibration is complete, the temperature sensor reports the temperature, in degrees Celsius, with a 0.5\ |degC| precision margin. Sensors and Sensor Groups $$$$$$$$$$$$$$$$$$$$$$$$$ The temperature sensors on the chip are logically classified in sensor groups, based on their proximity to certain hardware blocks. The sensor groups are represented as a single sensor to the host OS and the BPMP firmware. For example, Jetson Xavier has two temperature sensors in the SOC cluster and one near the CV cluster. These are grouped as AUX sensors that are represented as ``THERMAL_ZONE_AUX`` to the operating system running on the CPUs. The BPMP firmware reports the temperature of a given group by taking the maximum of all the sensors in the group. Thermal Event Detection $$$$$$$$$$$$$$$$$$$$$$$ Thermal sensors can report the temperature when the current temperature crosses a software-defined trip point. The sensors are capable of monitoring several of these software trip points to perform the following thermal actions: - Report when the thermal trip point has been crossed - Trigger a hardware thermal shutdown - Trigger hardware throttling Voltage Rail Dependencies $$$$$$$$$$$$$$$$$$$$$$$$$ To provide accurate temperature sensing, the sensors require a minimum voltage. Additionally, the sensors cannot operate when the rail is power-gated. When the system is in a low-power state, the firmware provides the following modes of operation: - **No temperature measurements during SC7:** Because the rail powering the sensor is power-gated in the SC7 state, the oscillator is not running. Therefore, the frequency-to-temperature conversion may result in inaccurate values. To avoid spurious temperature reports from the sensors, stop the sensors before entering the SC7 state. The firmware provides the ``AOTAG`` sensor for measuring temperature in the SC7 state. When the SC7 state is exited, the sensors are restarted. - **Fallback to PLLX sensor:** To ensure accurate temperature readings during minimum voltage, use the PLLX sensor’s oscillator. On platforms where the minimum voltage is not guaranteed, the firmware falls back on the PLLX sensor’s oscillator with a programmable offset. The result is that all the sensors invalidate their oscillators and use the PLLX sensor’s oscillator with the added offset. This fallback on the PLLX sensor’s oscillator allows for continuous temperature measurement, even at lower voltage levels. As a side effect of PLLX fallback, the programmable offset compensates for the fact that the PLLX sensor’s oscillator is farther away than the oscillator that it is replacing. The host OS continues to use all of the thermal zones without side effects. The offset ensures that the CPU sensor reports more accurate temperatures than the PLLX sensor. The host OS must therefore continue to use the right sensors for measuring the CPU temperatures. AOTAG ##### The Always-On Thermal Alert Generator (AOTAG) is a ring oscillator based temperature sensor. It is in the always-on power domain and can monitor temperatures even when the device is in the SC7 state. Apart from this distinction, the AOTAG sensor operates the same as any of the ``SOC_THERM`` sensors. Thermal Event Detection $$$$$$$$$$$$$$$$$$$$$$$ Just like the ``SOC_THERM`` sensor, the ``AOTAG`` sensor can generate interrupts. Additionally, it can monitor two software-controlled interrupt levels that BSP uses as: - Thermal zone trip points - Hardware thermal shutdown BPMP Thermal Framework ###################### The BPMP firmware hosts a thermal framework to: - Register thermal sensors as thermal zones as identified in `Thermal Sensing <#thermal-sensing>`__ - Allow BPMP modules to register trip points on the thermal zones - Allow the host OS to register trips using thermal MRQ messages - Provide trip management and reporting The thermal framework maintains a list of trips per sensor that includes the current trip from the host OS and various BPMP modules. As temperatures change, the framework examines the list of current trips and notifies the owners of the trips of the changes. The notification is sent using a callback for the BPMP owned trips and the thermal MRQ command ``CMD_THERMAL_HOST_TRIP_REACHED`` for trips that are owned by the host OS. The primary thermal MRQ requests handled by the framework are: - ``CMD_THERMAL_QUERY_ABI`` - ``CMD_THERMAL_GET_TEMP`` - ``CMD_THERMAL_SET_TRIP`` - ``CMD_THERMAL_GET_NUM_ZONES`` Since there can be several trips on a given sensor, the thermal framework must ensure that a notification is generated whenever a given trip is crossed. For example, if ``THERMAL_ZONE_CPU`` has trips at 55\ |deg|, 60\ |deg|, 65\ |deg|, and 70\ |degC|, the thermal framework sends a single notification when the temperature crosses 55\ |deg|, 60\ |deg|, 65\ |deg|, and 70\ |degC|. Additionally, the framework implements hysteresis to prevent sending too many notifications. Thus for the above example, the framework: - Sends one notification when the temperature reaches 55\ |degC| - Waits until the temperature drops below 54\ |degC| - Sends another notification when the temperature rises back to 55\ |degC| To generate these notifications, the thermal framework sets low trips on the sensors to receive events that the temperature has dropped below the limit. Hardware Throttling ################### Each element in a power delivery system includes limitations such as: - The amount of current a battery can supply without shutting down - The amount of current a regulator can provide before it fails to maintain its output voltage - The amount of ripple current an inductor in a switching regulator can tolerate without overheating These limitations can result in fast transient electrical and thermal events such as: - Overcurrent at the battery - Voltage drop at the PMIC - Temperature spikes The firmware refers to these events as **OC alarms**, and triggers clock hardware throttling to handle them. Impact $$$$$$ Like software throttling, hardware throttling may reduce performance. Because the triggering events are rare and transient in nature, though, the user experience is minimally impacted. The host OS is not notified of these events, but you can detect the drop in clock rates by using a performance measuring tool that samples the CPU cycle counters. While thermal management in the host OS seeks to control temperature on an ongoing basis, hardware throttling clamps down the clocks to handle events. Throttle Points and Vector Configuration $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ The BPMP device tree binary holds the various throttle points and the throttle settings that govern when and how throttling is performed. The soctherm driver in the BPMP firmware handles any interrupts resulting from these events. You can change the throttle points by changing the BPMP device tree. This table shows the hardware throttling levels: =================== ========================== Hardware throttling Clock throttled percentage =================== ========================== Heavy 87.5 Medium 75 Light 50 =================== ========================== Throttle vectors are optimized for limiting peak current consumption while maximizing performance. To manage peak current consumption, the firmware supports capping the CPU and GPU clocks at three levels (light, medium, and heavy), as described in the device tree bindings. Clock capping prevents the CPU and GPU from drawing more current than their voltage regulators can supply. For hardware throttling trip temperatures, see the table in `Thermal Specifications <#thermal-specifications>`__. Design Considerations $$$$$$$$$$$$$$$$$$$$$ Designing failsafe measures into Power Management Integrated Circuits (PMICs), or using the battery controller to shut down the device when the events described here occur, results in a bad user experience. Similarly, designing power delivery hardware for worst-case loads results in large and costly components. Consequently, NVIDIA SoCs are designed for use with power delivery systems that are adequate for common loads. NVIDIA SoCs actively manage their components to avoid exceeding their design limits. When events are transient, the advantage of this approach to power management becomes more compelling. Hardware Thermal Shutdown ######################### The final failsafe for firmware thermal management is a hardware thermal reset, or thermtrip. If software and hardware throttling are unable to control heat generation in the system, and the software becomes unresponsive, the SoC asserts the reset pin on the PMIC as the hardware shutdown mechanism. For hardware shutdown limits, see the table in `Thermal Specifications <#thermal-specifications>`__. Thermal Specifications @@@@@@@@@@@@@@@@@@@@@@ This table describes the supported power states. .. raw:: html :file: JetsonXavierNxAndJetsonAgxXavier/ThermalSpecifications~SupportedPowerStates.htm Software-Based Power Consumption Modeling @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ Jetson Xavier modules integrate a three-channel INA3221 power monitor whose information can be read using sysfs nodes. The following table shows the naming convention for sysfs nodes. +----------------------------------+----------------------------------+ | Command* | Description | +==================================+==================================+ | in_label | Sets/gets rail name. | +----------------------------------+----------------------------------+ | curr_input | Gets rail current in | | | milliamperes. | +----------------------------------+----------------------------------+ | in_input | Gets rail voltage in millivolts. | +----------------------------------+----------------------------------+ | curr_crit | Sets/gets rail instantaneous | | | current limit in milliamperes. | +----------------------------------+----------------------------------+ | curr_max | Sets/gets rail average current | | | limit in milliamperes. | +----------------------------------+----------------------------------+ | \* ```` is a channel number, 1-3. | +---------------------------------------------------------------------+ .. note:: The INA driver may also present other nodes. Do not modify any INA sysfs node value. Modifying these values can result in damage to the device. Jetson Xavier NX Series ####################### Jetson Xavier NX series has one INA3221 power monitor at I2C address ``0x40``. The sysfs nodes to read for rail names, voltage, current, and instantaneous and average current limit are at:: /sys/bus/i2c/drivers/ina3221/7-0040/hwmon/hwmon (Where is dynamic hwmon index) The rail names for I2C address 0x40 are: ============================= ================================== Rail Name Description ============================= ================================== Channel 1: ``VDD_IN`` System 5V power rail Channel 2: ``VDD_CPU_GPU_CV`` CPU + GPU + CV combined power rail Channel 3: ``VDD_SOC`` SoC power rail ============================= ================================== .. note:: The ``VDD_IN`` rail overcurrent thresholds for average current are 3\ |nbsp|\ A for 10W and 15W power modes, and 4\ |nbsp|\ A for 20W power modes. For instantaneous current they are 5\ |nbsp|\ A for all power modes. When module current consumption exceeds the configured limits, the INA3221 triggers CPU and GPU hardware clock throttling to prevent shutdown and physical damage. The ``nvpmodel`` GUI applet notifies user space processes of overcurrent events. For more details, see the section `Voltage and Current Monitor <#voltage-and-current-monitor>`__. Jetson AGX Xavier Series ######################## The Jetson AGX Xavier series modules have two 3-channel INA3221 power monitors at I2C addresses ``0x40`` and ``0x41``. The sysfs nodes to read for rail names, voltage, current, and instantaneous and average current limit are at:: /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon /sys/bus/i2c/drivers/ina3221/1-0041/hwmon/hwmon (Where and are dynamic hwmon indexes) The rail names for I2C address ``0x40`` are: ============== ============== Rail Name Description ============== ============== Channel 1: GPU GPU power rail Channel 2: CPU CPU power rail Channel 3: SOC SoC power rail ============== ============== The rail names for I2C address ``0x41`` are: ================ ==================== Rail Name Description ================ ==================== Channel 1: CV CV power rail Channel 2: VDDRQ DDR power rail Channel 3: SYS5V System 5V power rail ================ ==================== Examples ######## - To read INA3221 at 0x40, the channel-1 rail name, enter the command:: $ cat /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/in1_label - To read channel-1 voltage and current, enter the commands:: $ cat /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/in1_input $ cat /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/curr1_input - To read the channel-1 instantaneous current limit, enter the command:: $ cat /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/curr1_crit - To set the channel-1 instantaneous current limit, enter the command:: $ echo > /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/curr1_crit - To read the channel-1 average current limit, enter the command:: $ cat /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/curr1_max - To set the channel-1 average current limit, enter the command:: $ echo > /sys/bus/i2c/drivers/ina3221/1-0040/hwmon/hwmon/curr1_max Where ```` is the current limit to be set for the rail, in milliamperes. Related Tools and Techniques @@@@@@@@@@@@@@@@@@@@@@@@@@@@ This section describes the tools and techniques for managing power. CPU Hot Plug ############ You may use the following procedures to manage CPU hot plugging. To turn secondary CPUs on or off manually $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - To turn the secondary CPU on, enter the command:: $ echo 1 > /sys/devices/system/cpu/cpuX/online - To turn the secondary CPU off, enter the command:: $ echo 0 > /sys/devices/system/cpu/cpuX/online To check a CPU’s state $$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ cat /sys/devices/system/cpu/cpu/online Where ```` is the CPU core number. To check online CPU cores $$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ cat /sys/devices/system/cpu/online CPU Frequency Scaling ##################### The default CPU frequency governor is ``schedutil``. To list available CPU frequency governors $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ cat /sys/devices/system/cpu/cpu0/cpufreq/scaling_available_governors To select a CPU frequency governor $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ echo > /sys/devices/system/cpu/cpu/cpufreq/scaling_governor Where: - ```` is the name of the governor to be selected. - ```` is the CPU core number. GPU 3D Frequency Scaling ######################## GPU 3D frequency scaling is enabled by default. To disable 3D frequency scaling $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ echo 0 > /sys/devices/17000000.gv11b/enable_3d_scaling To enable 3D frequency scaling $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ echo 1 > /sys/devices/17000000.gv11b/enable_3d_scaling Getting and Setting Frequencies ############################### Use the following procedures to set frequencies and report current frequency settings. .. note:: In all of these procedures, ```` is a CPU core number. For example, to apply a command to CPU core 1, replace ``cpu`` with ``cpu1``. - To get system clock information, enter the command:: $ cat /sys/kernel/debug/bpmp/debug/clk/clk_tree - To print the CPU lower boundary, upper boundary, and current frequency, enter the commands:: $ cat /sys/devices/system/cpu/cpu/cpufreq/cpuinfo_min_freq $ cat /sys/devices/system/cpu/cpu/cpufreq/cpuinfo_max_freq $ cat /sys/devices/system/cpu/cpu/cpufreq/cpuinfo_cur_freq - To change the CPU upper boundary, enter the command:: $ echo > /sys/devices/system/cpu/cpu/cpufreq/scaling_max_freq - To change the CPU lower boundary, enter the command:: $ echo >/sys/devices/system/cpu/cpu/cpufreq/scaling_min_freq - To set the static CPU frequency, enter the commands:: $ echo >/sys/devices/system/cpu/cpu/cpufreq/scaling_min_freq $ echo >/sys/devices/system/cpu/cpu/cpufreq/scaling_max_freq Where: - ```` is the frequency value available at:: /sys/devices/system/cpu/cpu/cpufreq/scaling_available_frequencies - To print the GPU lower boundary, upper boundary, and current frequency, enter the commands:: $ cat /sys/devices/17000000.gv11b/devfreq/17000000.gv11b/min_freq $ cat /sys/devices/17000000.gv11b/devfreq/17000000.gv11b/max_freq $ cat /sys/devices/17000000.gv11b/devfreq/17000000.gv11b/cur_freq - To change the GPU upper boundary, enter the command:: $ echo >/sys/devices/17000000.gv11b/devfreq/17000000.gv11b/max_freq - To change the GPU lower boundary, enter the command:: $ echo >/sys/devices/17000000.gv11b/devfreq/17000000.gv11b/min_freq - To set the static GPU frequency, enter the commands:: $ echo >/sys/devices/17000000.gv11b/devfreq/17000000.gv11b/min_freq $ echo >/sys/devices/17000000.gv11b/devfreq/17000000.gv11b/max_freq Where ```` is the value available at:: /sys/devices/17000000.gv11b/devfreq/17000000.gv11b/available_frequencies - To print the EMC lower boundary, upper boundary, and current frequency, enter the commands:: $ cat /sys/kernel/debug/bpmp/debug/clk/emc/min_rate $ cat /sys/kernel/debug/bpmp/debug/clk/emc/max_rate $ cat /sys/kernel/debug/bpmp/debug/clk/emc/rate The EMC lower boundary and upper boundary can't be changed using bpmp debugfs node. - To set static EMC frequency, enter the commands:: $ echo 1 > /sys/kernel/debug/bpmp/debug/clk/emc/mrq_rate_locked $ echo 1 > /sys/kernel/debug/bpmp/debug/clk/emc/state $ echo > /sys/kernel/debug/bpmp/debug/clk/emc/rate Where ```` is a frequency value between EMC minimum and maximum frequencies. - To set the static VIC frequency, see the section :ref:`To set the static VIC frequency ` in the topic :ref:`Clocks `. Maximizing Jetson Xavier Performance #################################### The ``jetson_clocks.sh`` script maximizes a Jetson Xavier performance by setting the static maximum frequencies of the CPU, GPU and EMC clocks. You can also use the script to show current clock settings, store current clock settings into a file, and restore clock settings from a file. The script is available at:: /usr/bin/jetson_clocks To run the script, enter:: $ jetson_clocks [] Where ```` are zero or more of the command line options in the following table. +----------------------+------------------------------------------------+ | ``jetson_clocks.sh`` | | | command line option | Description | +======================+================================================+ | --show | Displays the current settings. | +----------------------+------------------------------------------------+ | --store [] | Stores the current settings to a file. The | | | default file is | | | ``${HOME}/.jetsonclocks_conf.txt``. | +----------------------+------------------------------------------------+ | --restore [] | Restores the saved settings from a file. The | | | default file is | | | ``${HOME}/.jetsonclocks_conf.txt``. | +----------------------+------------------------------------------------+ | --fan | Set maximum PWM fan speed. | +----------------------+------------------------------------------------+ To show the current settings $$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo /usr/bin/jetson_clocks --show To store the current settings $$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo /usr/bin/jetson_clocks --store To maximize Jetson Xavier performance $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo /usr/bin/jetson_clocks To maximize Jetson Xavier performance and fan speed $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo /usr/bin/jetson_clocks --fan .. note:: Starting with release 32.4, ``jetson_clocks`` no longer sets maximum fan speed by default. If you prefer the old behavior, use the ``--fan`` option. To restore the previous settings $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ - Enter the command:: $ sudo /usr/bin/jetson_clocks --restore Fan Speed Control ################# Jetson Linux affords means of getting and setting fan speed from the command line. - To set fan speed manually, enter the command:: $ echo > /sys/devices/platform/pwm-fan/hwmon/hwmon/pwm1 Where: - ```` is a value in the range [0,255]. - ```` is a kernel enumerated number for fan hwmon. - To get the fan speed measured by the tachometer, enter the command:: $ cat /sys/devices/generic_pwm_tachometer/hwmon/hwmon/rpm Where ```` is a kernel enumerated number for tachometer hwmon. nvpmodel GUI ############ The nvpmodel GUI is a GUI front end for the ``nvpmodel`` command line tool. It is an easy way to access power-related functionality and information. The nvpmodel GUI is represented by an NVIDIA icon on the right side the Ubuntu desktop’s top bar: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiNvidiaIcon.png :alt: The nvpmodel GUI is represented by an INVIDIA icon on the right side of the Ubuntu desktop's top bar :figwidth: 300 px The current power mode is displayed next to the NVIDIA icon. In the illustration above, the current mode is "`MODE 15W DESKTOP`". - To switch the current power mode, click the NVIDIA icon to open a dropdown menu from the icon. Click “Power mode” to open a submenu of power modes: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiPowerModeSubmenu.png :alt: The power mode submenu :figwidth: 150 px Click the power mode you want to set. .. note:: GPU ``tpc_pg_mask`` can be set once before the GPU golden context is created. If the nvpmodel power mode change requires to set the different ``tpc_pg_mask`` value then the system reboot is required. - Example: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiPowerModeReboot.png :alt: The power mode submenu :figwidth: 150 px .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiPowerModeRebootDialog.png :alt: The power mode submenu :figwidth: 400 px Press `OK` to do the system reboot. - To run ``tegrastats``, click the NVIDIA icon to open the dropdown menu: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiRunTegrastats.png :alt: The run tegrastats submenu :figwidth: 150 px Click “Run tegrastats” to spawn a terminal window and run ``tegrastats``: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiTegrastats.png :alt: The power mode submenu :figwidth: 500 px The ``tegrastats`` display is described in :ref:`Tegrastats Utility ` in the topic :ref:`Jetson Linux Development Tools `. It provides power-related information such as CPU, GPU, and EMC frequencies and the temperatures of thermal zones registered to the system. - If system input voltage drops below a safe level, the ``nvpmodel`` GUI displays a desktop notification to warn you that the system is being throttled back to avoid a shutdown due to insufficient power. When the system is thermally throttled, the GUI displays a similar notification to show that the device is operating at lowered speed to reduce heat generation. These are examples of notifications: .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiNotification1.png :alt: "System throttled due to Over-current" notification :figwidth: 270 px .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiNotification2.png :alt: "System throttled due to CPU-therm" notification :figwidth: 270 px .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiNotification3.png :alt: "Caution - Hot surface, do not touch" notification :figwidth: 270 px Jetson Power GUI ################ The Jetson Power GUI is a GUI tool for monitoring the power and thermal status of Jetson platforms. The tool reports various power and thermal related information which would help the user to understand power and thermal behavior of Jetson platforms. - To run ``Jetson Power GUI``: 1. Click the nvpmodel GUI represented by an NVIDIA icon on the right side the Ubuntu desktop’s top bar. 2. Click the "Run Jetson Power GUI" submenu. .. figure:: JetsonXavierNxAndJetsonAgxXavier/NvpmodelGuiRunJetsonPowerGUI.png :alt: The run Jetson Power GUI submenu :figwidth: 300 px Main tab $$$$$$$$ .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIMainTab.png :alt: The main tab of Jetson Power GUI :figwidth: 650 px - Here are the information / functionalities provided in the ``Main`` tab: +----------------------+------------------------------------------------+ | Frame name | Provided information / functionalities | +======================+================================================+ | Top | - Jetson platform name | | | - Current power mode | +----------------------+------------------------------------------------+ | CPU | CPU related information | | | - State | | | - Clock frequency | | | - Load percentage | +----------------------+------------------------------------------------+ | GPU | GPU related information | | | - State | | | - Clock frequency | | | - Load percentage | +----------------------+------------------------------------------------+ | EMC | EMC related information | | | - State | | | - Clock frequency | | | - Load percentage | | | - Memory usage (used size / total size) | | | - Swap usage (used size / total size) | +----------------------+------------------------------------------------+ | Engine | Engine related information | | | - State | | | - Clock frequency | +----------------------+------------------------------------------------+ | Sensor | Thermal sensor related information | | | - Temperature read by thermal sensor | +----------------------+------------------------------------------------+ | Power Monitor | Power monitor related information | | | - Instantaneous power read by power monitor | | | - Average power read by power monitor | | | | | | Power monitor related functionalities | | | - Reset average power calculation by | | | clicking the ``"reset avg"`` button | +----------------------+------------------------------------------------+ | Fan | Fan related information | | | - Fan profile | | | - PWM percentage | | | - RPM value | +----------------------+------------------------------------------------+ | Disk | Disk related information | | | - Disk usage (used size / total size) | +----------------------+------------------------------------------------+ | Record | Functionalities | | | - Allow the user to capture the log within | | | the specified duration. | | | - Click the "background" button to capture | | | the log in the background, which avoids the | | | system putting in extra effort on rendering | | | GUI. | | | - Allow the user to plot the power related | | | data. The user can plot the data from | | | captured log, or plot the real-time data. | +----------------------+------------------------------------------------+ Thermal / Power Monitor tab $$$$$$$$$$$$$$$$$$$$$$$$$$$ .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIThermalPowerMonitorTab.png :alt: The thermal and power monitor tab of Jetson Power GUI :figwidth: 650 px - Here are the information / functionalities provided in the ``Thermal / Power Monitor`` tab: +----------------------+------------------------------------------------+ | Frame name | Provided information / functionalities | +======================+================================================+ | Thermal | Thermal sensor related information | | | - Software throttling limit (if any) | | | - Software shutdown limit (if any) | | | - Temperature read by thermal sensor | +----------------------+------------------------------------------------+ | Fan | Fan related information | | | - PWM value | | | - RPM value | +----------------------+------------------------------------------------+ | Power Monitor | Power monitor related information | | | - Average current limit | | | - Instantaneous current limit | | | - Voltage read by power monitor | | | - Current read by power monitor | | | - Power read by power monitor | +----------------------+------------------------------------------------+ Functionalities provided in Record frame $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ The ``Record`` frame provides these functionalities: - Capture power related information to a log file within the user specified duration - Plot the power related information to graph. - Below steps illustrate how to capture the data to a log file: - Before clicking the ``"capture log..."`` button in the Record frame, please select the desired capture duration: .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUISelectDuration.png :alt: Select duration before capturing log :figwidth: 650 px - After selecting the desired capture duration, the user can click the ``"capture log..."`` button, then a file dialog will be popped out to let the user select the path to save the captured log. - There are two kinds of supported formats, the ``.csv`` and the ``.txt`` file format. - If the user wants to capture the log in the background, the ``"background"`` checkbox should be checked before clicking the ``"capture log..."`` button. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIFileDialog.png :alt: Select the path to save the captured log :figwidth: 650 px - Once the path to save the captured log selected, the capturing process starts. .. note:: - If the user wants to stop the capturing process earlier during the capturing process, the user can click the ``"stop capturing"`` button to interrupt the capturing process. The captured log will still be saved to the specified path. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIStopCapture.png :alt: The user can click the ``"stop capturing"`` button to interrupt the capturing process :figwidth: 650 px - A message box will be popped out to notify the user once the capturing process finished. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUICaptureDone.png :alt: A message box will be prompted to notify the user the capturing process finished :figwidth: 650 px - Here is the preview of the captured log. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUICapturedLog.png :alt: Preview of the captured log :figwidth: 650 px - Below steps illustrate how to visualize the data: - The ``"plot graph..."`` button provides the data visualization functionality. Click the button to pop out a window which lets the user select the desired power channels to plot. Click the ``"select all"`` button to select all power channels with single click. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIPowerChannels.png :alt: Power channel window :figwidth: 650 px - After selecting the desired power channels, the user can either plot the data from the captured log or in real time. - Clicking the ``"plot from log..."`` button will pop out a file dialog, which lets the user choose which log file to plot. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIChooseFile.png :alt: File dialog to select which file to be plotted :figwidth: 650 px - The data will be plotted once the log file is selected. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIPlotFile.png :alt: Plot the log file :figwidth: 650 px - Clicking the ``"plot dynamically"`` button will plot the last 120 seconds real-time data. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIPlotDyn.png :alt: Plot the real-time data :figwidth: 650 px - If the user wants to stop the real-time plotting process, the ``"stop plotting"`` button can be clicked to stop. .. figure:: JetsonXavierNxAndJetsonAgxXavier/JetsonPowerGUIStopPlotDyn.png :alt: Stop plotting the real-time data :figwidth: 650 px