XO3 Tinderbox Power: Difference between revisions

From OLPC
Jump to navigation Jump to search
 
(9 intermediate revisions by the same user not shown)
Line 11: Line 11:
There are two types of measurement point in the above diagram. Most measure power passing through a particular point in the power distribution network, and are represented by a large X, along with an annotation of the voltmeter channel and measurement resistance. All measurement resistors have a tolerance (variation in resistance) of 1% or smaller.
There are two types of measurement point in the above diagram. Most measure power passing through a particular point in the power distribution network, and are represented by a large X, along with an annotation of the voltmeter channel and measurement resistance. All measurement resistors have a tolerance (variation in resistance) of 1% or smaller.


A smaller number of points (3005, 3010) measure the voltage at a particular point in the power network. These are indicated by an arrow, and annotated solely with the voltmeter channel.
A few points (3005) measure the voltage at a particular point in the power network. These are indicated by an arrow, and annotated solely with the voltmeter channel.


The definitive file describing this setup is the [http://dev.laptop.org/git/projects/tinderbox/tree/power/cl3_a1.csv tinderbox configuration file].
The definitive file describing this setup is the [http://dev.laptop.org/git/projects/tinderbox/tree/power/cl3_a1.csv tinderbox configuration file].
Line 22: Line 22:


==Measurement Error==
==Measurement Error==
It should be cautioned that using a multiplexed voltmeter for measurement of power in a dynamic system has its downsides. The voltmeter does perform averaging in generating a measurement, but with a time period on the order of milliseconds.


==Off Power==
It should be cautioned that using a multiplexed voltmeter for measurement of power in a dynamic system has its downsides.
The tinderbox version of the XO-3 tablet doesn't have a battery, so the EC never goes into sleep mode. When "turned off" but plugged into the wall, the tablet takes around 50 mW ([http://dev.laptop.org/~wad/cl3_a1/off.html off.html]).


==Display Power==
==Display Power==
Running the display (without the backlight) consumes 635 mW (not counting some inefficiencies in the power distribution network). This is broken down into:


{| border="1" align="center" cellpadding="6"
One attempt at measuring the power consumed by the display was to force the screen to blank using:
|+ '''XO-3 A1 Display Power'''
|- align="center"
|Frame memory
|70 mW
|- align="center"
|MMP2 Display Ctrl.
|70 mW
|- align="center"
|LVDS converter
|150 mW
|- align="center"
|LCD Module
|345 mW
|- align="center"
|Total
|635 mW
|}

The display backlight takes between 0 and 1.9 W to operate.

When comparing this to the [[XO1.75_Tinderbox_Power#Display_Power|power consumption of the display in an XO-1.75]], it should be remembered that the display resolution is lower on the XO-3 (1024 x 800 versus 1200 x 900), which reduces the memory power consumption.

===Using OFW===
The [http://dev.laptop.org/~wad/cl3_a1/ofw_nodisp3.html ofw_nodisp3.html] file was generated using OFW. After booting the system into OFW, issue the following commands:
screen-ih iselect sleep # turns off the display
backlight-off
d# 129 gpio-clr # turn off display digital power
d# 33 gpio-clr # turn off display analog power
d# 138 gpio-clr # just make sure (in case the ECO doesn't work)
d# 130 gpio-clr # prevent leakage to LCM
d# 135 gpio-clr # prevent leakage to LCM

This both stops the frame buffer in the SoC and disables power to the external components (DCON and LCD module). This file was compared with [http://dev.laptop.org/~wad/cl3_a1/ofw_idle3.html ofw_idle3.html] to obtain the above numbers.

===Using Linux===
The first attempt at measuring the power consumed by the display was to force the screen to blank using:
echo 1 > /sys/devices/platform/pxa168-fb.0/graphics/fb0/blank
echo 1 > /sys/devices/platform/pxa168-fb.0/graphics/fb0/blank


Line 34: Line 73:
==USB ULPI Interface==
==USB ULPI Interface==


The idle power consumption of this interface is around 15 mW ([http://dev.laptop.org/~wad/cl3_a1/linux_idle.html Idle]).
The idle power consumption of this interface is around 15 mW ([http://dev.laptop.org/~wad/cl3_a1/linux_idle.html Idle]). When reading from a USB stick (copying a large file into /dev/null), it consumes around 22 mW ([http://dev.laptop.org/~wad/cl3_a1/linux_usb.html usb read]) --- but there is significant power draw from +5V powering the USB device.

''Full power measurements to come''


[[Category:Hardware]]
[[Category:Hardware]]

Latest revision as of 19:27, 12 April 2012

This page describes the Tinderbox version of the XO-3 A1 tablet.

Power Distribution

The following diagram attempts to illustrate the XO-3 power distribution network, as well as the tinderbox measurement points:

XO 3 Tinderbox A1.png

Measurement Points

There are two types of measurement point in the above diagram. Most measure power passing through a particular point in the power distribution network, and are represented by a large X, along with an annotation of the voltmeter channel and measurement resistance. All measurement resistors have a tolerance (variation in resistance) of 1% or smaller.

A few points (3005) measure the voltage at a particular point in the power network. These are indicated by an arrow, and annotated solely with the voltmeter channel.

The definitive file describing this setup is the tinderbox configuration file.

Many of the system components are similar to those in the XO-1.75 laptop, and have been documented in the XO-1.75 Tinderbox.

Example Measurements

Example readings taken using this setup are available at http://dev.laptop.org/~wad/cl3_a1/. Some of these measurements are highlighted below.

Measurement Error

It should be cautioned that using a multiplexed voltmeter for measurement of power in a dynamic system has its downsides. The voltmeter does perform averaging in generating a measurement, but with a time period on the order of milliseconds.

Off Power

The tinderbox version of the XO-3 tablet doesn't have a battery, so the EC never goes into sleep mode. When "turned off" but plugged into the wall, the tablet takes around 50 mW (off.html).

Display Power

Running the display (without the backlight) consumes 635 mW (not counting some inefficiencies in the power distribution network). This is broken down into:

XO-3 A1 Display Power
Frame memory 70 mW
MMP2 Display Ctrl. 70 mW
LVDS converter 150 mW
LCD Module 345 mW
Total 635 mW

The display backlight takes between 0 and 1.9 W to operate.

When comparing this to the power consumption of the display in an XO-1.75, it should be remembered that the display resolution is lower on the XO-3 (1024 x 800 versus 1200 x 900), which reduces the memory power consumption.

Using OFW

The ofw_nodisp3.html file was generated using OFW. After booting the system into OFW, issue the following commands:

screen-ih iselect sleep  # turns off the display
backlight-off
d# 129 gpio-clr  # turn off display digital power
d# 33 gpio-clr    # turn off display analog power
d# 138 gpio-clr  # just make sure (in case the ECO doesn't work)
d# 130 gpio-clr  # prevent leakage to LCM
d# 135 gpio-clr  # prevent leakage to LCM

This both stops the frame buffer in the SoC and disables power to the external components (DCON and LCD module). This file was compared with ofw_idle3.html to obtain the above numbers.

Using Linux

The first attempt at measuring the power consumed by the display was to force the screen to blank using:

echo 1 > /sys/devices/platform/pxa168-fb.0/graphics/fb0/blank

The results can be seen at linux_nodisp.html. They show that no external components were powered down, as well as no reduction in power consumed by the SoC (compare it to linux_idle.html) which we expect to see. The backlight power is weird as well...

USB ULPI Interface

The idle power consumption of this interface is around 15 mW (Idle). When reading from a USB stick (copying a large file into /dev/null), it consumes around 22 mW (usb read) --- but there is significant power draw from +5V powering the USB device.