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 page.title=Measuring Component Power
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 <p>You can determine individual component power consumption by comparing the current drawn by the
 device when the component is in the desired state (on, active, scanning, etc.) and when the
 component is off. Measure the average instantaneous current drawn on the device at a
 nominal voltage using an external power monitor, such as a bench power supply or specialized
 battery-monitoring tools (such as Monsoon Solution Inc. Power Monitor and Power Tool software).</p>

 <p>Manufacturers often supply information about the current consumed by an individual component.
 Use this information if it accurately represents the current drawn from the device battery in
 practice. However, validate manufacturer-provided values before using those values in your device
 power profile.</p>

 <h2 id="control-consumption">Controlling power consumption</h2>

 <p>When measuring, ensure the device does not have a connection to an external charge source, such
 as a USB connection to a development host used when running Android Debug Bridge (adb). The device
 under test might draw current from the host, thus lowering measurements at the battery. Avoid USB
 On-The-Go (OTG) connections, as the OTG device might draw current from the device under test.</p>

 <p>Excluding the component being measured, the system should run at a constant level of power
 consumption to avoid inaccurate measurements caused by changes in other components. System
 activities that can introduce unwanted changes to power measurements include:</p>

 <ul>
 <li><strong>Cellular, Wi-Fi, and Bluetooth receive, transmit, or scanning activity</strong>. When
 not measuring cell radio power, set the device to airplane mode and enable Wi-Fi or Bluetooth as
 appropriate.</li>
 <li><strong>Screen on/off</strong>. Colors displayed while the screen is on can affect power draw
 on some screen technologies. Turn the screen off when measuring values for non-screen components.</li>
 <li><strong>System suspend/resume</strong>. A screen off state can trigger a system suspension,
 placing parts of the device in a low-power or off state. This can affect power consumption of the
 component being measured and introduce large variances in power readings as the system periodically
 resumes to send alarms, etc. For details, see <a href="#control-suspend">Controlling system
 suspend</a>.</li>
 <li><strong>CPUs changing speed and entering/exiting low-power scheduler idle state</strong>.
 During normal operation, the system makes frequent adjustments to CPU speeds, the number of online
 CPU cores, and other system core states such as memory bus speed and voltages of power rails
 associated with CPUs and memory. During testing, these adjustments affect power measurements:
 <ul>
 <li>CPU speed scaling operations can reduce the amount of clock and voltage scaling of memory buses
 and other system core components.</li>
 <li>Scheduling activity can affect the percentage of the time CPUs spend in low-power idle states.
 For details on preventing these adjustments from occurring during testing, see
 <a href="#control-cpu">Controlling CPU speeds</a>.</li>
 </ul>

 </li>
 </ul>

 <p>For example, Joe Droid wants to compute the <code>screen.on</code> value for a device. He
 enables airplane mode on the device, runs the device at a stable current state, holds the CPU
 speed constant, and uses a partial wakelock to prevent system suspend. Joe then turns the device
 screen off and takes a measurement (200mA). Next, Joe turns the device screen on at minimum
 brightness and takes another measurement (300mA). The <code>screen.on</code> value is 100mA (300 -
 200).</p>

 <p class="note">
 <strong>Note</strong>: For components that don’t have a flat waveform of current consumption when
 active (such as cellular radio or Wi-Fi), measure the average current over time using a power
 monitoring tool.</p>

 <p>When using an external power source in place of the device battery, the system might experience
 problems due to an unconnected battery thermistor or integrated fuel gauge pins (i.e. an invalid
 reading for battery temperature or remaining battery capacity could shut down the kernel or Android
 system). Fake batteries can provide signals on thermistor or fuel gauge pins that mimic temperature
 and state of charge readings for a normal system, and may also provide convenient leads for
 connecting to external power supplies. Alternatively, you can modify the system to ignore the
 invalid data from the missing battery.</p>

 <h2 id="control-suspend">Controlling system suspend</h2>

 <p>This section describes how to avoid system suspend state when you don’t want it to interfere
 with other measurements, and how to measure the power draw of system suspend state when you do
 want to measure it.</p>

 <h3 id="prevent-suspend">Preventing system suspend</h3>

 <p>System suspend can introduce unwanted variance in power measurements and place system components
 in low-power states inappropriate for measuring active power use. To prevent the system from
 suspending while the screen is off, use a temporary partial wakelock. Using a USB cable, connect
 the device to a development host, then issue the following command:</p>

 <pre>
 $ adb shell "echo temporary &gt; /sys/power/wake_lock"
 </pre>

 <p>While in <code>wake_lock</code>, the screen off state does not trigger a system suspend.
 (Remember to disconnect the USB cable from the device before measuring power consumption.)</p>

 <p>To remove the wakelock:</p>

 <pre>
 $ adb shell "echo temporary &gt; /sys/power/wake_unlock"
 </pre>

 <h3 id="measure-suspend">Measuring system suspend</h3>

 <p>To measure the power draw during the system suspend state, measure the value of
 <code>cpu.idle</code> in the power profile. Before measuring:

 <ul>
 <li>Remove existing wakelocks (as described above).</li>
 <li>Place the device in airplane mode to avoid concurrent activity by the cellular radio, which
 might run on a processor separate from the SoC portions controlled by the system suspend.</li>
 <li>Ensure the system is in suspend state by:
 <ul>
 <li>Confirming current readings settle to a steady value. Readings should be within the expected
 range for the power consumption of the SoC suspend state plus the power consumption of system
 components that remain powered (such as the USB PHY).</li>
 <li>Checking the system console output.</li>
 <li>Watching for external indications of system status (such as an LED turning off when not in
 suspend).</li>
 </ul>
 </li>
 </ul>

 <h2 id="control-cpu">Controlling CPU speeds</h2>

 <p>Active CPUs can be brought online or put offline, have their clock speeds and associated
 voltages changed (possibly also affecting memory bus speeds and other system core power states),
 and can enter lower power idle states while in the kernel idle loop. When measuring different CPU
 power states for the power profile, avoid the power draw variance when measuring other parameters.
 The power profile assumes all CPUs have the same available speeds and power characteristics.</p>

 <p>While measuring CPU power, or while holding CPU power constant to make other measurements, keep
 the number of CPUs brought online constant (such as having one CPU online and the rest
 offline/hotplugged out). Keeping all CPUs except one in scheduling idle may product acceptable
 results. Stopping the Android framework with <code>adb shell stop</code> can reduce system
 scheduling activity.</p>

 <p>You must specify the available CPU speeds for your device in the power profile <code>cpu.speeds</code> entry. To get a list of available CPU speeds, run:</p>

 <pre>
 adb shell cat /sys/devices/system/cpu/cpu0/cpufreq/stats/time_in_state
 </pre>

 <p>These speeds match the corresponding power measurements in value <code>cpu.active</code>.</p>

 <p>For platforms where number of cores brought online significantly affects power consumption, you
 might need to modify the cpufreq driver or governor for the platform. Most platforms support
 controlling CPU speed using the userspace cpufreq governor and using sysfs interfaces to set the
 speed. For example, to set speed for 200MHz on a system with only 1 CPU or all CPUs sharing a
 common cpufreq policy, use the system console or adb shell to run the following commands:</p>

 <pre>
 echo userspace &gt; /sys/devices/system/cpu/cpu0/cpufreq/scaling_governor
 echo 200000 &gt; /sys/devices/system/cpu/cpu0/cpufreq/scaling_max_freq
 echo 200000 &gt; /sys/devices/system/cpu/cpu0/cpufreq/scaling_min_freq
 echo 200000 &gt; /sys/devices/system/cpu/cpu0/cpufreq/scaling_setspeed
 cat /sys/devices/system/cpu/cpu0/cpufreq/scaling_cur_freq
 </pre>

 <p class="note">
 <strong>Note</strong>: The exact commands differ depending on the platform cpufreq implementation.
 </p>

 <p>These commands ensure the new speed is not outside the allowed bounds, set the new speed, then
 print the speed at which the CPU is actually running (for verification). If the current
 minimum speed prior to execution is higher than 200000, you might need to reverse the order
 of the first two lines, or execute the first line again to drop the minimum speed prior to
 setting the maximum speed.</p>

 <p>To measure current consumed by a CPU running at various speeds, use the system console to place
 the CPU in a CPU-bound loop using the command:</p>
 <pre>
 # while true; do true; done
 </pre>

 <p>Take the measurement while the loop executes.</p>

 <p>Some devices can limit maximum CPU speed while performing thermal throttling due to a high
 temperature measurement (i.e. after running CPUs at high speeds for sustained periods). Watch for
 such limiting, either using the system console output when taking measurements or by checking the
 kernel log after measuring.</p>

 <p>For the <code>cpu.awake</code> value, measure the power consumed when the system is not in
 suspend and not executing tasks. The CPU should be in a low-power scheduler <em>idle loop
 </em>, possibly executing an ARM Wait For Event instruction or in an SoC-specific low-power state
 with a fast-exit latency suitable for idle use.</p>

 <p>For the <code>cpu.active</code> value, measure power when the system is not in suspend mode and not executing tasks. One CPU (usually the primary CPU) should run the task while all other CPUs
 should be in an idle state.</p>

 <h2 id="screen-power">Measuring screen power</h2>

 <p>When measuring screen on power, ensure that other devices normally turned on when the screen is
 enabled are also on. For example, if the touchscreen and display backlight would normally be on
 when the screen is on, ensure these devices are on when you measure to get a realistic example of
 screen on power usage.</p>

 <p>Some display technologies vary in power consumption according to the colors displayed, causing
 power measurements to vary considerably depending on what is displayed on the screen at the time of
 measurement. When measuring, ensure the screen is displaying something that has power
 characteristics of a realistic screen. Aim between the extremes of an all-black screen (which
 consumes the lowest power for some technologies) and an all-white screen. A common choice is a view
 of a schedule in the calendar app, which has a mix of white background and non-white elements.</p>

 <p>Measure screen on power at <em>minimum</em> and <em>maximum</em> display/backlight brightness.
 To set minimum brightness:</p>

 <ul>
 <li><strong>Use the Android UI</strong> (not recommended). Set the Settings > Display Brightness
 slider to the minimum display brightness. However, the Android UI allows setting brightness only to
 a minimum of 10-20% of the possible panel/backlight brightness, and does not allow setting
 brightness so low that the screen might not be visible without great effort.</li>
 <li><strong>Use a sysfs file</strong> (recommended). If available, use a sysfs file to control
 panel brightness all the way down to the minimum brightness supported by the hardware.</li>
 </ul>

 <p>Additionally, if the platform sysfs file enables turning the LCD panel, backlight, and
 touchscreen on and off, use the file to take measurements with the screen on and off. Otherwise,
 set a partial wakelock so the system does not suspend, then turn on and off the
 screen with the power button.</p>

 <h2 id="wifi-power">Measuring Wi-Fi power</h2>

 <p>Perform Wi-Fi measurements on a relatively quiet network. Avoid introducing additional work
 processing high volumes of broadcast traffic that is unrelated to the activity being measured.</p>

 <p>The <code>wifi.on</code> value measures the power consumed when Wi-Fi is enabled but not
 actively transmitting or receiving. This is often measured as the delta between the current draw in
 system suspend (sleep) state with Wi-Fi enabled vs. disabled.</p>

 <p>The <code>wifi.scan</code> value measures the power consumed during a Wi-Fi scan for access
 points. Applications can trigger Wi-Fi scans using the WifiManager class
 <a href ="http://developer.android.com/reference/android/net/wifi/WifiManager.html">
 <code>startScan()</code>API</a>. You can also open Settings &gt; Wi-Fi, which performs access point
 scans every few seconds with an apparent jump in power consumption, but you must subtract screen
 power from these measurements.</p>

 <p class="note">
 <strong>Note</strong>: Use a controlled setup (such as
 <a href="http://en.wikipedia.org/wiki/Iperf">iperf</a>) to generate network receive and transmit
 traffic.</p>
	page.title=Measuring Component Power
	@jd:body

	<!--
	Copyright 2015 The Android Open Source Project

	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License.
	-->
	<div id="qv-wrapper">
	<div id="qv">
	<h2>In this document</h2>
	<ol id="auto-toc"></ol>
	</div>
	</div>


	<p>You can determine individual component power consumption by comparing the current drawn by the
	device when the component is in the desired state (on, active, scanning, etc.) and when the
	component is off. Measure the average instantaneous current drawn on the device at a
	nominal voltage using an external power monitor, such as a bench power supply or specialized
	battery-monitoring tools (such as Monsoon Solution Inc. Power Monitor and Power Tool software).</p>

	<p>Manufacturers often supply information about the current consumed by an individual component.
	Use this information if it accurately represents the current drawn from the device battery in
	practice. However, validate manufacturer-provided values before using those values in your device
	power profile.</p>

	<h2 id="control-consumption">Controlling power consumption</h2>

	<p>When measuring, ensure the device does not have a connection to an external charge source, such
	as a USB connection to a development host used when running Android Debug Bridge (adb). The device
	under test might draw current from the host, thus lowering measurements at the battery. Avoid USB
	On-The-Go (OTG) connections, as the OTG device might draw current from the device under test.</p>

	<p>Excluding the component being measured, the system should run at a constant level of power
	consumption to avoid inaccurate measurements caused by changes in other components. System
	activities that can introduce unwanted changes to power measurements include:</p>

	<ul>
	<li><strong>Cellular, Wi-Fi, and Bluetooth receive, transmit, or scanning activity</strong>. When
	not measuring cell radio power, set the device to airplane mode and enable Wi-Fi or Bluetooth as
	appropriate.</li>
	<li><strong>Screen on/off</strong>. Colors displayed while the screen is on can affect power draw
	on some screen technologies. Turn the screen off when measuring values for non-screen components.</li>
	<li><strong>System suspend/resume</strong>. A screen off state can trigger a system suspension,
	placing parts of the device in a low-power or off state. This can affect power consumption of the
	component being measured and introduce large variances in power readings as the system periodically
	resumes to send alarms, etc. For details, see <a href="#control-suspend">Controlling system
	suspend</a>.</li>
	<li><strong>CPUs changing speed and entering/exiting low-power scheduler idle state</strong>.
	During normal operation, the system makes frequent adjustments to CPU speeds, the number of online
	CPU cores, and other system core states such as memory bus speed and voltages of power rails
	associated with CPUs and memory. During testing, these adjustments affect power measurements:
	<ul>
	<li>CPU speed scaling operations can reduce the amount of clock and voltage scaling of memory buses
	and other system core components.</li>
	<li>Scheduling activity can affect the percentage of the time CPUs spend in low-power idle states.
	For details on preventing these adjustments from occurring during testing, see
	<a href="#control-cpu">Controlling CPU speeds</a>.</li>
	</ul>

	</li>
	</ul>

	<p>For example, Joe Droid wants to compute the <code>screen.on</code> value for a device. He
	enables airplane mode on the device, runs the device at a stable current state, holds the CPU
	speed constant, and uses a partial wakelock to prevent system suspend. Joe then turns the device
	screen off and takes a measurement (200mA). Next, Joe turns the device screen on at minimum
	brightness and takes another measurement (300mA). The <code>screen.on</code> value is 100mA (300 -
	200).</p>

	<p class="note">
	<strong>Note</strong>: For components that don’t have a flat waveform of current consumption when
	active (such as cellular radio or Wi-Fi), measure the average current over time using a power
	monitoring tool.</p>

	<p>When using an external power source in place of the device battery, the system might experience
	problems due to an unconnected battery thermistor or integrated fuel gauge pins (i.e. an invalid
	reading for battery temperature or remaining battery capacity could shut down the kernel or Android
	system). Fake batteries can provide signals on thermistor or fuel gauge pins that mimic temperature
	and state of charge readings for a normal system, and may also provide convenient leads for
	connecting to external power supplies. Alternatively, you can modify the system to ignore the
	invalid data from the missing battery.</p>

	<h2 id="control-suspend">Controlling system suspend</h2>

	<p>This section describes how to avoid system suspend state when you don’t want it to interfere
	with other measurements, and how to measure the power draw of system suspend state when you do
	want to measure it.</p>

	<h3 id="prevent-suspend">Preventing system suspend</h3>

	<p>System suspend can introduce unwanted variance in power measurements and place system components
	in low-power states inappropriate for measuring active power use. To prevent the system from
	suspending while the screen is off, use a temporary partial wakelock. Using a USB cable, connect
	the device to a development host, then issue the following command:</p>

	<pre>
	$ adb shell "echo temporary > /sys/power/wake_lock"
	</pre>

	<p>While in <code>wake_lock</code>, the screen off state does not trigger a system suspend.
	(Remember to disconnect the USB cable from the device before measuring power consumption.)</p>

	<p>To remove the wakelock:</p>

	<pre>
	$ adb shell "echo temporary > /sys/power/wake_unlock"
	</pre>

	<h3 id="measure-suspend">Measuring system suspend</h3>

	<p>To measure the power draw during the system suspend state, measure the value of
	<code>cpu.idle</code> in the power profile. Before measuring:

	<ul>
	<li>Remove existing wakelocks (as described above).</li>
	<li>Place the device in airplane mode to avoid concurrent activity by the cellular radio, which
	might run on a processor separate from the SoC portions controlled by the system suspend.</li>
	<li>Ensure the system is in suspend state by:
	<ul>
	<li>Confirming current readings settle to a steady value. Readings should be within the expected
	range for the power consumption of the SoC suspend state plus the power consumption of system
	components that remain powered (such as the USB PHY).</li>
	<li>Checking the system console output.</li>
	<li>Watching for external indications of system status (such as an LED turning off when not in
	suspend).</li>
	</ul>
	</li>
	</ul>

	<h2 id="control-cpu">Controlling CPU speeds</h2>

	<p>Active CPUs can be brought online or put offline, have their clock speeds and associated
	voltages changed (possibly also affecting memory bus speeds and other system core power states),
	and can enter lower power idle states while in the kernel idle loop. When measuring different CPU
	power states for the power profile, avoid the power draw variance when measuring other parameters.
	The power profile assumes all CPUs have the same available speeds and power characteristics.</p>

	<p>While measuring CPU power, or while holding CPU power constant to make other measurements, keep
	the number of CPUs brought online constant (such as having one CPU online and the rest
	offline/hotplugged out). Keeping all CPUs except one in scheduling idle may product acceptable
	results. Stopping the Android framework with <code>adb shell stop</code> can reduce system
	scheduling activity.</p>

	<p>You must specify the available CPU speeds for your device in the power profile <code>cpu.speeds</code> entry. To get a list of available CPU speeds, run:</p>

	<pre>
	adb shell cat /sys/devices/system/cpu/cpu0/cpufreq/stats/time_in_state
	</pre>

	<p>These speeds match the corresponding power measurements in value <code>cpu.active</code>.</p>

	<p>For platforms where number of cores brought online significantly affects power consumption, you
	might need to modify the cpufreq driver or governor for the platform. Most platforms support
	controlling CPU speed using the userspace cpufreq governor and using sysfs interfaces to set the
	speed. For example, to set speed for 200MHz on a system with only 1 CPU or all CPUs sharing a
	common cpufreq policy, use the system console or adb shell to run the following commands:</p>

	<pre>
	echo userspace > /sys/devices/system/cpu/cpu0/cpufreq/scaling_governor
	echo 200000 > /sys/devices/system/cpu/cpu0/cpufreq/scaling_max_freq
	echo 200000 > /sys/devices/system/cpu/cpu0/cpufreq/scaling_min_freq
	echo 200000 > /sys/devices/system/cpu/cpu0/cpufreq/scaling_setspeed
	cat /sys/devices/system/cpu/cpu0/cpufreq/scaling_cur_freq
	</pre>

	<p class="note">
	<strong>Note</strong>: The exact commands differ depending on the platform cpufreq implementation.
	</p>

	<p>These commands ensure the new speed is not outside the allowed bounds, set the new speed, then
	print the speed at which the CPU is actually running (for verification). If the current
	minimum speed prior to execution is higher than 200000, you might need to reverse the order
	of the first two lines, or execute the first line again to drop the minimum speed prior to
	setting the maximum speed.</p>

	<p>To measure current consumed by a CPU running at various speeds, use the system console to place
	the CPU in a CPU-bound loop using the command:</p>
	<pre>
	# while true; do true; done
	</pre>

	<p>Take the measurement while the loop executes.</p>

	<p>Some devices can limit maximum CPU speed while performing thermal throttling due to a high
	temperature measurement (i.e. after running CPUs at high speeds for sustained periods). Watch for
	such limiting, either using the system console output when taking measurements or by checking the
	kernel log after measuring.</p>

	<p>For the <code>cpu.awake</code> value, measure the power consumed when the system is not in
	suspend and not executing tasks. The CPU should be in a low-power scheduler <em>idle loop
	</em>, possibly executing an ARM Wait For Event instruction or in an SoC-specific low-power state
	with a fast-exit latency suitable for idle use.</p>

	<p>For the <code>cpu.active</code> value, measure power when the system is not in suspend mode and not executing tasks. One CPU (usually the primary CPU) should run the task while all other CPUs
	should be in an idle state.</p>

	<h2 id="screen-power">Measuring screen power</h2>

	<p>When measuring screen on power, ensure that other devices normally turned on when the screen is
	enabled are also on. For example, if the touchscreen and display backlight would normally be on
	when the screen is on, ensure these devices are on when you measure to get a realistic example of
	screen on power usage.</p>

	<p>Some display technologies vary in power consumption according to the colors displayed, causing
	power measurements to vary considerably depending on what is displayed on the screen at the time of
	measurement. When measuring, ensure the screen is displaying something that has power
	characteristics of a realistic screen. Aim between the extremes of an all-black screen (which
	consumes the lowest power for some technologies) and an all-white screen. A common choice is a view
	of a schedule in the calendar app, which has a mix of white background and non-white elements.</p>

	<p>Measure screen on power at <em>minimum</em> and <em>maximum</em> display/backlight brightness.
	To set minimum brightness:</p>

	<ul>
	<li><strong>Use the Android UI</strong> (not recommended). Set the Settings > Display Brightness
	slider to the minimum display brightness. However, the Android UI allows setting brightness only to
	a minimum of 10-20% of the possible panel/backlight brightness, and does not allow setting
	brightness so low that the screen might not be visible without great effort.</li>
	<li><strong>Use a sysfs file</strong> (recommended). If available, use a sysfs file to control
	panel brightness all the way down to the minimum brightness supported by the hardware.</li>
	</ul>

	<p>Additionally, if the platform sysfs file enables turning the LCD panel, backlight, and
	touchscreen on and off, use the file to take measurements with the screen on and off. Otherwise,
	set a partial wakelock so the system does not suspend, then turn on and off the
	screen with the power button.</p>

	<h2 id="wifi-power">Measuring Wi-Fi power</h2>

	<p>Perform Wi-Fi measurements on a relatively quiet network. Avoid introducing additional work
	processing high volumes of broadcast traffic that is unrelated to the activity being measured.</p>

	<p>The <code>wifi.on</code> value measures the power consumed when Wi-Fi is enabled but not
	actively transmitting or receiving. This is often measured as the delta between the current draw in
	system suspend (sleep) state with Wi-Fi enabled vs. disabled.</p>

	<p>The <code>wifi.scan</code> value measures the power consumed during a Wi-Fi scan for access
	points. Applications can trigger Wi-Fi scans using the WifiManager class
	<a href ="http://developer.android.com/reference/android/net/wifi/WifiManager.html">
	<code>startScan()</code>API</a>. You can also open Settings > Wi-Fi, which performs access point
	scans every few seconds with an apparent jump in power consumption, but you must subtract screen
	power from these measurements.</p>

	<p class="note">
	<strong>Note</strong>: Use a controlled setup (such as
	<a href="http://en.wikipedia.org/wiki/Iperf">iperf</a>) to generate network receive and transmit
	traffic.</p>