Difference between revisions of "BELK-AN-004: Interfacing BoraEVB/BoraXEVB to TFT LCD display"

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{{InfoBoxTop}}
 
{{InfoBoxTop}}
 
{{Applies To Bora}}
 
{{Applies To Bora}}
{{Applies To BoraLite}}
 
{{AppliesToBORA_AN}}
 
{{AppliesToBORA_Xpress_AN}}
 
{{AppliesToBORA Lite AN}}
 
 
{{Applies To BoraX}}
 
{{Applies To BoraX}}
 
{{InfoBoxBottom}}
 
{{InfoBoxBottom}}
{{WarningMessage|text=This application note was validated against specific versions of the kit only. It may not work with other versions. Supported versions are listed in the ''History'' section.}}
 
 
{{ImportantMessage|text=It is assumed to use ZYNQ SOC with <b><i>speed grade -1</i></b> (even using command line script or GUI). In any case, there are no issues using <b><i>speed grade -3</i></b> SOC provided with BELK kit}}
 
 
 
 
==History==
 
==History==
  
Line 17: Line 8:
 
!Version
 
!Version
 
!Date
 
!Date
!BELK/BXELK version
+
!BELK version
 
!Notes
 
!Notes
 
|-
 
|-
 
|1.0.0
 
|1.0.0
|September 2015
+
|15:03, 4 September 2015 (CEST)
 
|[[Bora_Embedded_Linux_Kit_(BELK)#BELK_software_components|2.2.0]]
 
|[[Bora_Embedded_Linux_Kit_(BELK)#BELK_software_components|2.2.0]]
 
|First release
 
|First release
|-
 
|2.0.0
 
|November 2015
 
|[[Bora_Embedded_Linux_Kit_(BELK)#BELK_software_components|2.2.0, 3.0.0]]
 
|Added support for BoraX/BoraXEVB platform
 
|-
 
|{{oldid|8292|2.0.1}}
 
|March 2017
 
|[[Bora_Embedded_Linux_Kit_(BELK)#BELK_software_components|2.2.0, 3.0.0]]
 
|Added info for installing Qt on rfs using <code>smart</code>
 
|-
 
|3.0.0
 
|January 2020
 
|[[Bora_Embedded_Linux_Kit_(BELK)#BELK_software_components|4.1.0 / 2.1.0]]
 
|AN migration to BELK 4.1.0 / BXELK 2.1.0
 
 
|-
 
|-
 
|}
 
|}
Line 49: Line 25:
 
* electrical interface: LVDS (3 pairs).
 
* electrical interface: LVDS (3 pairs).
  
Please, refer to the [[BELK-AN-004:_Interfacing_BoraEVB/BoraXEVB_to_TFT_LCD_display#History | History]] table for using the proper BELK version used on the AN.
+
This project is based on [[Bora_Embedded_Linux_Kit_%28BELK%29#BELK_software_components|BELK 2.2.0]] and [[Bora_Embedded_Linux_Kit_%28BELK%29#BELK_software_components|BELK 3.0.0]].
  
 
==Physical interfacing==
 
==Physical interfacing==
Line 61: Line 37:
 
Ampire AM-800480STMQW-TA1 part integrates resistive touch too. This is directly connected to BoraEVB's J25 connector. Resistive touch is managed by Texas Instruments TSC2003 controller (U27).
 
Ampire AM-800480STMQW-TA1 part integrates resistive touch too. This is directly connected to BoraEVB's J25 connector. Resistive touch is managed by Texas Instruments TSC2003 controller (U27).
  
Schematics of adapter board can be downloaded from this [https://www.dave.eu/system/files/area-riservata/BORA_LCD_ADAPTOR_ADBL7000C1R_1.0.0_0.pdf link].
+
Schematics of adapter board can be downloaded from this [http://www.dave.eu/system/files/area-riservata/BORA_LCD_ADAPTOR_ADBL7000C1R_1.0.0_0.pdf link].
  
 
===BoraXEVB===
 
===BoraXEVB===
In case of BoraXEVB, no adapter board is needed. LCD panel is directly connected to J26 connector where PL bank 13's signals implementing LVDS interface are routed (see [[BoraXEVB#Schematics|page 14]] of the schematics). I/O voltage of bank 13 is set to 2.5V by configuring [[BoraXEVB#BANK13_VDDIO_selector_-_JP25|JP25 ]] as shown in the following table.
+
In case of BoraXEVB, no adapter board is needed. LCD panel is directly connected to J22 connector where PL bank 13's signals implementing LVDS interface are routed (see [[BoraXEVB#Schematics|page 14]] of the schematics). I/O voltage of bank 13 is set to 2.5V by configuring [[BoraXEVB#BANK13_VDDIO_selector_-_JP25|JP25 ]] as follows:
{| class="wikitable" border="1"
 
!Pins
 
!Setting
 
|-
 
|1-2
 
|closed
 
|-
 
|3-4
 
|open
 
|-
 
|5-6
 
|closed
 
|-
 
|7-8
 
|open
 
|-
 
|9-10
 
|open
 
|-
 
|11-12
 
|open
 
|-
 
|}
 
  
 
==Block diagram and Vivado project==
 
==Block diagram and Vivado project==
The following pictures show simplified block diagram of the design.  
+
The following picture shows simplified block diagram of the design.  
  
[[File:An-belk-004-01.png|thumb|center|600px|Simplified block diagram of the design (Bora + BoraEVB)]]
+
[[File:An-belk-004-01.png|thumb|center|600px|Simplified block diagram of the design (BoraEVB)]]
[[File:An-belk-004-borax-01.png|thumb|center|600px|Simplified block diagram of the design (BoraX + BoraXEVB)]]
+
[[File:An-belk-004-01.png|thumb|center|600px|Simplified block diagram of the design (BoraXEVB)]]
[[File:an-belk-004-boralite-01.png|thumb|center|600px|Simplified block diagram of the design (BoraLite + Adapter + BoraXEVB)]]
 
  
 
LCD is driven by a controller implemented in PL that fetches pixel data from frame buffer and periodically refreshes physical screen.
 
LCD is driven by a controller implemented in PL that fetches pixel data from frame buffer and periodically refreshes physical screen.
Line 110: Line 62:
 
To implement frame buffer, a portion of main SDRAM is used. This area is allocated at runtime by linux frame buffer driver. Even if LCD is 18 bpp, each pixel is represented by 32-bit word in memory. In fact each pixel is in RGB666 format, so for each colour only the six most significant bits of the frame buffer RGB888 are used to drive the display.
 
To implement frame buffer, a portion of main SDRAM is used. This area is allocated at runtime by linux frame buffer driver. Even if LCD is 18 bpp, each pixel is represented by 32-bit word in memory. In fact each pixel is in RGB666 format, so for each colour only the six most significant bits of the frame buffer RGB888 are used to drive the display.
  
The Vivado project can also be build with the procedure explained [[Creating_and_building_example_Vivado_project_(BELK/BXELK)#Command_line_based_procedure|here]].
+
===BoraEVB===
 
 
===Bora + BoraEVB===
 
 
Here is the pinout assignment to drive the LCD:
 
Here is the pinout assignment to drive the LCD:
 
{| class="wikitable" |  
 
{| class="wikitable" |  
Line 137: Line 87:
 
|-
 
|-
 
|}
 
|}
 +
 +
The Vivado project can be downloaded from this [http://www.dave.eu/system/files/area-riservata/AN-BELK-004-xpr.zip link].
  
 
(*) This signal is used to control backlight. It is usually driven by a PWM signal whose duty cycle is proportional to backlight intensity. For the sake of simplicity, in this project this signal is driven by a GPIO, thus only two intensity levels are supported (0% and 100%).
 
(*) This signal is used to control backlight. It is usually driven by a PWM signal whose duty cycle is proportional to backlight intensity. For the sake of simplicity, in this project this signal is driven by a GPIO, thus only two intensity levels are supported (0% and 100%).
  
The Vivado project can also be build with the procedure explained [[Creating_and_building_example_Vivado_project_(BELK/BXELK)#Command_line_based_procedure|here]] with the following modifications:
+
===BoraXEVB===
*<code>export BASE_NAME bora_LVDS</code>
+
TBD
*<code>export U-BOOT_PS7_DIR bora</code>
 
 
 
===BoraLite + Adapter + BoraXEVB===
 
Here is the pinout assignment to drive the LCD:
 
{| class="wikitable" |
 
| align="center" style="background:#f0f0f0;"|'''LCD Signal'''
 
| align="center" style="background:#f0f0f0;"|'''BORA SOM Signal'''
 
|-
 
| BackLight (*)||IO_L6N_T0_VREF_13 (**)
 
|-
 
| LVDS_CLK_P||IO_L13P_T2_MRCC_13 (**)
 
|-
 
| LVDS_CLK_N||IO_L13N_T2_MRCC_13 (**)
 
|-
 
| LVDS_D0_P||IO_L12P_T1_MRCC_13 (**)
 
|-
 
| LVDS_D0_N||IO_L12N_T1_MRCC_13 (**)
 
|-
 
| LVDS_D1_P||IO_L15P_T2_DQS_13 (**)
 
|-
 
| LVDS_D1_N||IO_L15N_T2_DQS_13 (**)
 
|-
 
| LVDS_D2_P||IO_L11P_T1_SRCC_13 (**)
 
|-
 
| LVDS_D2_N||IO_L11N_T1_SRCC_13 (**)
 
|-
 
|}
 
 
 
(*) This signal is used to control backlight. It is usually driven by a PWM signal whose duty cycle is proportional to backlight intensity. For the sake of simplicity, in this project this signal is driven by a GPIO, thus only two intensity levels are supported (0% and 100%). This is a CMOS 2.5V level signal. Make sure that voltage levels of this signal are compatible with LCD backlight input.<br>
 
(**) On the adapter this signal is routed (via configurable 0R) to multiple pins of the EVB connector to meet all the features of the EVB. Please make sure to configure the Adapter for the use of the LVDS connector.
 
 
 
The Vivado project can also be build with the procedure explained [[Creating_and_building_example_Vivado_project_(BELK/BXELK)#Command_line_based_procedure|here]] with the following modifications:
 
*<code>export BASE_NAME boralite_LVDS</code>
 
*<code>export U-BOOT_PS7_DIR bora</code>
 
 
 
====  BoraLiteAdapter BLADP0000R0R ====
 
 
 
As the BoraLite SOM has fewer signals routed out as the other SOM, some signal are multiplexed via 0R resistors: the following table list these configurations:
 
{| class="wikitable" |
 
| align="center" style="background:#f0f0f0;"|'''Reference'''
 
| align="center" style="background:#f0f0f0;"|'''PmodA conn.'''
 
| align="center" style="background:#f0f0f0;"|'''LVDS conn.'''
 
|-
 
| R33 || 0R || DNP
 
|-
 
| R34 || 0R || DNP
 
|-
 
| R35 || 0R || DNP
 
|-
 
| R36 || 0R || DNP
 
|-
 
| R37 || 0R || DNP
 
|-
 
| R38 || 0R || DNP
 
|-
 
| R39 || 0R || DNP
 
|-
 
| R40 || x || DNP
 
|-
 
| R41 || 0R || DNP
 
|-
 
| R42 || x || 0R
 
|-
 
| R43 || DNP || 0R
 
|-
 
| R44 || DNP || 0R
 
|-
 
| R45 || DNP || 0R
 
|-
 
| R46 || DNP || 0R
 
|-
 
| R47 || DNP || 0R
 
|-
 
| R48 || DNP || 0R
 
|-
 
| R49 || DNP || 0R
 
|-
 
| R50 || DNP || 0R
 
|-
 
|}
 
 
 
===BoraX + BoraXEVB===
 
Here is the pinout assignment to drive the LCD:
 
{| class="wikitable" |
 
| align="center" style="background:#f0f0f0;"|'''LCD Signal'''
 
| align="center" style="background:#f0f0f0;"|'''BORA SOM Signal'''
 
|-
 
| BackLight (*)||IO_0_13
 
|-
 
| LVDS_CLK_P||IO_L13P_T2_MRCC_13
 
|-
 
| LVDS_CLK_N||IO_L13N_T2_MRCC_13
 
|-
 
| LVDS_D0_P||IO_L12P_T1_MRCC_13
 
|-
 
| LVDS_D0_N||IO_L12N_T1_MRCC_13
 
|-
 
| LVDS_D1_P||IO_L14P_T2_SRCC_13
 
|-
 
| LVDS_D1_N||IO_L14N_T2_SRCC_13
 
|-
 
| LVDS_D2_P||IO_L11P_T1_SRCC_13
 
|-
 
| LVDS_D2_N||IO_L11N_T1_SRCC_13
 
|-
 
|}
 
 
 
(*) This signal is used to control backlight. It is usually driven by a PWM signal whose duty cycle is proportional to backlight intensity. For the sake of simplicity, in this project this signal is driven by a GPIO, thus only two intensity levels are supported (0% and 100%). This is a CMOS 2.5V level signal. Make sure that voltage levels of this signal are compatible with LCD backlight input.
 
 
 
The Vivado project can also be build with the procedure explained [[Creating_and_building_example_Vivado_project_(BELK/BXELK)#Command_line_based_procedure|here]] with the following modifications:
 
*<code>export BASE_NAME borax_LVDS</code>
 
*<code>export U-BOOT_PS7_DIR borax</code>
 
  
 
==Enabling frame buffer driver in linux kernel==
 
==Enabling frame buffer driver in linux kernel==
  
U-boot:
+
To enable frame buffer driver user needs to:
* the default KIT binary files of u-boot (u-boot.img) and SPL (boot.bin) can be used.
+
* get the pre-built binaries [http://www.dave.eu/system/files/area-riservata/AN-BELK-004-sw_0.zip here].
* the variable <code>bootcmd</code> has to contain this string: <code>video=borafb:800x480-32 cma=32M</code>
 
** this can be achieved modifying the variable <code>addmisc</code> with the following command:
 
<pre>
 
setenv addmisc 'setenv bootargs ${bootargs} ${mtdparts} video=borafb:800x480-32 cma=32M'
 
</pre>
 
  
 
Kernel and device tree can also be built with the following procedure:
 
Kernel and device tree can also be built with the following procedure:
* update Bora kernel repository (as described [[BELK/BXELK_software_components#Updating_git_repositories|here]])
+
* update Bora kernel repository (as described [[Bora_Embedded_Linux_Kit_(BELK)#Updating_the_repositories_from_BELK_2.1.0_to_BELK_2.2.0|here]])
* the default KIT binary files of kernel (uImage) can be used.
+
* checkout ''bora-feat-lcd-support'' branch (using ''git checkout bora-feat-lcd-support'' command)
* build the <code>bora-an004.dtb</code> devicetree
+
* build the updated kernel source as usual.
  
Put the binaries on the first (FAT32) partition of your BELK SD card, overwriting the original one if needed. Please note that you need the following files:
+
Put the binaries on the first (FAT32) partition of your BELK 2.2.0 SD card, overwriting the original one if needed. Please note that you need the following files:
 
* boot.bin
 
* boot.bin
 
* bora.dtb
 
* bora.dtb
 
* uImage
 
* uImage
 
* fpga.bin
 
* fpga.bin
* u-boot.img
 
 
* uEnv.txt
 
* uEnv.txt
  
Install root file system on second (ext4) partition of your BELK SD card (firstly deleting all previous rfs files):
+
Insert the SD card into BoraEVB and turn on the board.
* get rfs image [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_dave-image-devel-bora.tar.bz2 here]
 
 
 
Insert the SD card into Bora/BoraX EVB and turn on the board.
 
  
 
During kernel bootstrap, the following messages are printed out on console, indicating framebuffer driver has been loaded succesfully:
 
During kernel bootstrap, the following messages are printed out on console, indicating framebuffer driver has been loaded succesfully:
Line 291: Line 122:
 
You will also see two [https://en.wikipedia.org/wiki/Tux Tuxes] on the top left corner of the LCD, indicating that this Linux system has two cores, as shown in the following picture:
 
You will also see two [https://en.wikipedia.org/wiki/Tux Tuxes] on the top left corner of the LCD, indicating that this Linux system has two cores, as shown in the following picture:
  
{|style="margin: 0 auto;"
+
[[File:An-belk-004-03.jpg|thumb|center|400px]]
| [[File:An-belk-004-03.jpg|thumb|center|400px|Bora/BoraEVB system with LCD panel]]
 
| [[File:An-belk-004-05.jpg|thumb|center|400px|BoraX/BoraXEVB system with LCD panel]]
 
|}
 
  
 
Once the kernel has completed boot, frame buffer can be accessed from user space applications via <code>/dev/fb0</code> device file (for more details please refer to https://www.kernel.org/doc/Documentation/fb/framebuffer.txt).
 
Once the kernel has completed boot, frame buffer can be accessed from user space applications via <code>/dev/fb0</code> device file (for more details please refer to https://www.kernel.org/doc/Documentation/fb/framebuffer.txt).
  
=== Pre-built binaries ===
+
The following picture shows Qt 4.8.3 ''Affine Transformations'' demo application running on top of it.
 
 
* For Bora SoM use:
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_uImage uImage]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_bora-an004.dtb dtb]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_bora_LVDS_fpga.bin fpga]
 
* For BoraLite SoM use:
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_uImage uImage]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_bora-an004.dtb dtb]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_boralite_LVDS_fpga.bin fpga]
 
* For BoraX SoM use:
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_uImage uImage]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_bora-an004.dtb dtb]
 
** [http://mirror.dave.eu/bora/belk-4.1.0/belk-4.1.0_borax_LVDS_fpga.bin fpga]
 
 
 
=== How to install test tools for LCD device ===
 
* configure BELK for downloading new packages using <code>smart</code>: a useful description for using smart can be found [[AN-XELK-003:_Package_Management_with_Yocto#Installing_packages_on_target |here]]
 
* configure network interface for accessing DAVE Yocto pre-built images. For example:
 
 
 
root@bora:~# ifconfig eth0 192.168.0.95                          ''<-- BELK IP address''
 
root@bora:~# echo "nameserver 192.168.0.1" > /etc/resolv.conf    ''<-- your DNS, otherwise select a public DNS like Google's one 8.8.8.8''
 
root@bora:~# route add default gw 192.168.0.254                  ''<-- your gateway address''
 
 
 
* check network connectivity
 
root@bora:~# ping www.dave.eu
 
PING www.dave.eu (147.123.240.198): 56 data bytes
 
64 bytes from 147.123.240.198: seq=0 ttl=49 time=72.510 ms
 
* add DAVE smart channel and update smart cache
 
root@bora:~# smart channel --add cortexa9hf_neon type=rpm-md baseurl=http://yocto.dave.eu/belk-4.1.0/cortexa9hf_neon/
 
root@bora:~# smart update
 
 
 
* install the <code>tslib</code> required packages using <code>smart</code>
 
 
 
root@bora:~# smart install tslib-calibrate-1.1-r0
 
...
 
 
 
root@bora:~# smart install tslib-tests-1.1-r0
 
...
 
 
 
root@bora:~# smart install fb-test-1.1.0-r0
 
...
 
 
 
* calibrate resistive touchscreen
 
 
 
root@bora:~# ts_calibrate
 
 
 
touch on the 5 points displayed in sequence (4 corner + center)
 
 
 
* test the alignment of touchscreen
 
 
 
root@bora:~# ts_test
 
 
 
this tool allow to ''drag'' a point or to ''draw'' a line
 
 
 
* display some test patterns
 
  
root@bora:~# fb-test
+
[[File:An-belk-004-04.jpg|thumb|center|400px]]

Revision as of 09:20, 9 November 2015

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Info Box
Bora5-small.jpg Applies to Bora
BORA Xpress.png Applies to BORA Xpress

History[edit | edit source]

Version Date BELK version Notes
1.0.0 15:03, 4 September 2015 (CEST) 2.2.0 First release

Introduction[edit | edit source]

This application note describes the interfacing of Ampire AM-800480STMQW-TA1 display to BoraEVB and BoraXEVB. Main characteristics of this 7" TFT LCD panel are:

  • 800x480 resolution
  • color depth: 18 bpp
  • electrical interface: LVDS (3 pairs).

This project is based on BELK 2.2.0 and BELK 3.0.0.

Physical interfacing[edit | edit source]

BoraEVB[edit | edit source]

To interface the display a small adapter board is needed. It interfaces J22 connector on BoraEVB side and provides a 20-pin connector to directly attach display cable.

The adapter board

  • is also equipped with a linear regulator generating 2.5V. This voltage is used as power supply for the VDDIO_BANK13 rail. This voltage is required to implement LVDS differential pairs that drive display.
  • integrates a pad (denoted as TP1) that is used to connect 5V power supply generated by MOD2 PSU of BoraEVB. This additional power rails is required by display backlight circuitry.

Ampire AM-800480STMQW-TA1 part integrates resistive touch too. This is directly connected to BoraEVB's J25 connector. Resistive touch is managed by Texas Instruments TSC2003 controller (U27).

Schematics of adapter board can be downloaded from this link.

BoraXEVB[edit | edit source]

In case of BoraXEVB, no adapter board is needed. LCD panel is directly connected to J22 connector where PL bank 13's signals implementing LVDS interface are routed (see page 14 of the schematics). I/O voltage of bank 13 is set to 2.5V by configuring JP25 as follows:

Block diagram and Vivado project[edit | edit source]

The following picture shows simplified block diagram of the design.

Simplified block diagram of the design (BoraEVB)
Simplified block diagram of the design (BoraXEVB)

LCD is driven by a controller implemented in PL that fetches pixel data from frame buffer and periodically refreshes physical screen. The LCD controller is composed of an AXI VDMA IP, the LCD controller itself and a parallel-to-LVDS serializer. AXI VDMA and the LCD controller provides configuration registers that are mapped in the following address range:

  • AXI VDMA: 0x43000000 - 0x4300FFFF
  • LCD Controller: 0x43C00000 - 0x43C0FFFF

The following picture shows the block diagram of the Vivado project with LCD controller:


An-belk-004-02.png


To implement frame buffer, a portion of main SDRAM is used. This area is allocated at runtime by linux frame buffer driver. Even if LCD is 18 bpp, each pixel is represented by 32-bit word in memory. In fact each pixel is in RGB666 format, so for each colour only the six most significant bits of the frame buffer RGB888 are used to drive the display.

BoraEVB[edit | edit source]

Here is the pinout assignment to drive the LCD:

LCD Signal BORA SOM Signal
BackLight (*) IO_L15P_T2_DQS_13
LVDS_CLK_P IO_L22P_T3_13
LVDS_CLK_N IO_L22N_T3_13
LVDS_D0_P IO_L21P_T3_DQS_13
LVDS_D0_N IO_L21N_T3_DQS_13
LVDS_D1_P IO_L19P_T3_13
LVDS_D1_N IO_L19N_T3_VREF_13
LVDS_D2_P IO_L18P_T2_13
LVDS_D2_N IO_L18N_T2_13

The Vivado project can be downloaded from this link.

(*) This signal is used to control backlight. It is usually driven by a PWM signal whose duty cycle is proportional to backlight intensity. For the sake of simplicity, in this project this signal is driven by a GPIO, thus only two intensity levels are supported (0% and 100%).

BoraXEVB[edit | edit source]

TBD

Enabling frame buffer driver in linux kernel[edit | edit source]

To enable frame buffer driver user needs to:

  • get the pre-built binaries here.

Kernel and device tree can also be built with the following procedure:

  • update Bora kernel repository (as described here)
  • checkout bora-feat-lcd-support branch (using git checkout bora-feat-lcd-support command)
  • build the updated kernel source as usual.

Put the binaries on the first (FAT32) partition of your BELK 2.2.0 SD card, overwriting the original one if needed. Please note that you need the following files:

  • boot.bin
  • bora.dtb
  • uImage
  • fpga.bin
  • uEnv.txt

Insert the SD card into BoraEVB and turn on the board.

During kernel bootstrap, the following messages are printed out on console, indicating framebuffer driver has been loaded succesfully: 

[    0.600840] borafb borafb.0: fb0: Virtual frame buffer device, using 16384K of video memory @ phys 2d900000

You will also see two Tuxes on the top left corner of the LCD, indicating that this Linux system has two cores, as shown in the following picture:

An-belk-004-03.jpg

Once the kernel has completed boot, frame buffer can be accessed from user space applications via /dev/fb0 device file (for more details please refer to https://www.kernel.org/doc/Documentation/fb/framebuffer.txt).

The following picture shows Qt 4.8.3 Affine Transformations demo application running on top of it.

An-belk-004-04.jpg
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