Hardware User's Guide

REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
BeagleBone Rev A6
System Reference Manual
Revision 0.0
May 9, 2012
Send all comments and errors to the author:
Gerald Coley [email protected]
Page 1 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
This device has been tested and verified to comply with Part 15, Class B, of
the FCC Rules. Operation is subject to the following two conditions: (1) this device
may not cause harmful interference, and (2) this device must accept any
interference received, including interference that may cause undesired operation.
NOTE:
NOTE: This equipment has been tested and found to comply with the limits for a Class B
digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide
reasonable protection against harmful interference in a residential installation. This
equipment generates, uses and can radiate radio frequency energy and, if not installed
and used in accordance with the instructions, may cause harmful interference to radio
communications. However, there is no guarantee that interference will not occur in a
particular installation. If this equipment does cause harmful interference to radio or
television reception, which can be determined by turning the equipment off and on, the
user is encouraged to try to correct the interference by one or more of the following
measures:
- Reorient or relocate the receiving antenna.
- Increase the separation between the equipment and receiver.
- Connect the equipment into an outlet on a circuit different from that to which the receiver
is connected.
- Consult the dealer or an experienced radio/TV technician for help.
Changes or modifications not expressly approved by this manual for compliance could void the
user’s authority to operate the equipment.
THIS DOCUMENT
This work is licensed under the Creative Commons Attribution-Share Alike 3.0 Unported
License. To view a copy of this license, visit http://creativecommons.org/licenses/bysa/3.0/ or send a letter to Creative Commons, 171 Second Street, Suite 300, San
Francisco, California, 94105, USA.
All derivative works are to be attributed to Gerald Coley of BeagleBoard.org.
For more information, see http://creativecommons.org/license/resultsone?license_code=by-sa
For any questions, concerns, or issues submit them to [email protected]
Page 2 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
BEAGLEBONE DESIGN
These design materials referred to in this document are
*NOT SUPPORTED* and DO NOT constitute a
reference design. Only “community” support is allowed via
resources at BeagleBoard.org/discuss.
THERE IS NO WARRANTY FOR THE DESIGN
MATERIALS, TO THE EXTENT PERMITTED BY
APPLICABLE LAW. EXCEPT WHEN OTHERWISE
STATED IN WRITING THE COPYRIGHT HOLDERS
AND/OR OTHER PARTIES PROVIDE THE DESIGN
MATERIALS “AS IS” WITHOUT WARRANTY OF
ANY KIND, EITHER EXPRESSED OR IMPLIED,
INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND
FITNESS FOR A PARTICULAR PURPOSE. THE
ENTIRE RISK AS TO THE QUALITY AND
PERFORMANCE OF THE DESIGN MATERIALS IS
WITH YOU. SHOULD THE DESIGN MATERIALS
PROVE DEFECTIVE, YOU ASSUME THE COST OF
ALL NECESSARY SERVICING, REPAIR OR
CORRECTION.
We mean it; these design materials may be totally
unsuitable for any purposes.
Page 3 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
BeagleBoard.org provides the enclosed product(s) under the following conditions:
This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR
EVALUATION PURPOSES ONLY and is not considered by BeagleBoard.org to be a finished end-product
fit for general consumer use. Persons handling the product(s) must have electronics training and observe
good engineering practice standards. As such, the goods being provided are not intended to be complete in
terms of required design-, marketing-, and/or manufacturing-related protective considerations, including
product safety and environmental measures typically found in end products that incorporate such
semiconductor components or circuit boards. This evaluation board/kit does not fall within the scope of the
European Union directives regarding electromagnetic compatibility, restricted substances (RoHS), recycling
(WEEE), FCC, CE or UL, and therefore may not meet the technical requirements of these directives or other
related directives.
Should this evaluation board/kit not meet the specifications indicated in the User’s Guide, the board/kit may
be returned within 30 days from the date of delivery for a full refund to the distributor form which you
purchased the board. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY
SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR
STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY
PARTICULAR PURPOSE.
The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user
indemnifies BeagleBoard.org from all claims arising from the handling or use of the goods. Due to the open
construction of the product, it is the user’s responsibility to take any and all appropriate precautions with
regard to electrostatic discharge.
EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE, NEITHER PARTY SHALL BE
LIABLE TO THE OTHER FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL
DAMAGES.
BeagleBoard.org currently deals with a variety of customers for products, and therefore our arrangement
with the user is not exclusive. BeagleBoard.org assumes no liability for applications assistance,
customer product design, software performance, or infringement of patents or services described
herein.
Please read the System Reference Manual and, specifically, the Warnings and Restrictions notice in the
User’s Guide prior to handling the product. This notice contains important safety information about
temperatures and voltages. For additional information on BeagleBoard.org environmental and/or safety
programs, please visit BeagleBoard.org.
No license is granted under any patent right or other intellectual property right of BeagleBoard.org covering
or relating to any machine, process, or combination in which such BeagleBoard.org products or services
might be or are used.
Mailing Address:
BeagleBoard.org
1380 Presidential Dr. #100
Richardson, TX 75081
U.S.A.
Page 4 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
WARRANTY: The BeagleBoard is warranted against defects in materials and workmanship for a
period of 90 days from purchase. This warranty does not cover any problems occurring as a result
of improper use, modifications, exposure to water, excessive voltages, abuse, or accidents. All
boards will be returned via standard mail if an issue is found. If no issue is found or express return
is needed, the customer will pay all shipping costs.
Before returning the board, please visit
BeagleBoard.org/support
For up to date SW images and technical information refer to
http://circuitco.com/support/index.php?title=BeagleBone
Please refer to Section 9 of this document for the board checkout procedures.
To return a defective board, please request an RMA at http://beagleboard.org/support/rma
Please DO NOT return the board without approval from the
RMA team first.
All boards received without RMA approval will not be worked
on.
Page 5 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
Table of Contents
FIGURES ...................................................................................................................................................... 9
TABLES .......................................................................................................................................................10
1.0
INTRODUCTION..............................................................................................................................11
2.0
CHANGE HISTORY .........................................................................................................................12
2.1 CHANGE HISTORY ............................................................................................................................12
2.2 REV A5 VS. A6.................................................................................................................................13
2.2.1
PCB Changes.........................................................................................................................13
2.2.2
Design Changes .....................................................................................................................13
2.3 REV A4 VS. A5.................................................................................................................................14
2.3.1
PCB Changes.........................................................................................................................14
2.3.2
Design Changes .....................................................................................................................14
2.3.3
Production Changes ..............................................................................................................14
2.4 REV A3 VS. A4.................................................................................................................................15
2.4.1
PCB Changes.........................................................................................................................15
2.4.2
Design Changes .....................................................................................................................15
2.5 KNOWN ISSUES ................................................................................................................................15
2.6 BEAGLEBONE OVERVIEW ................................................................................................................16
2.7 BEAGLEBONE EXPANSION ...............................................................................................................16
2.8 BEAGLEBONE DESIGN MATERIAL ...................................................................................................16
2.9 IN THE BOX .....................................................................................................................................16
3.0
BEAGLEBONE FEATURES AND SPECIFICATION .................................................................17
3.1
3.2
4.0
BOARD COMPONENT LOCATIONS.....................................................................................................18
BOARD CONNECTOR AND INDICATOR LOCATIONS ...........................................................................20
BEAGLEBONE DESIGN SPECIFICATION .................................................................................21
4.1 PROCESSOR ......................................................................................................................................21
4.2 MEMORY..........................................................................................................................................21
4.3 POWER MANAGEMENT.....................................................................................................................21
4.4 PC USB INTERFACE .........................................................................................................................21
4.4.1
Serial Debug Port ..................................................................................................................21
4.4.2
JTAG Port ..............................................................................................................................22
4.4.3
USB0 Port ..............................................................................................................................22
4.5 MICROSD CONNECTOR ....................................................................................................................22
4.6 USB1 PORT .....................................................................................................................................22
4.7 USB CLIENT PORT ...........................................................................................................................22
4.8 POWER SOURCES .............................................................................................................................22
4.9 RESET BUTTON ................................................................................................................................23
4.10
INDICATORS ................................................................................................................................23
4.11
CTI JTAG HEADER .....................................................................................................................23
5.0
EXPANSION INTERFACE..............................................................................................................24
5.1 MAIN BOARD EXPANSION HEADER .................................................................................................24
5.2 CAPE EXPANSION BOARDS ..............................................................................................................24
5.3 EXPOSED FUNCTIONS .......................................................................................................................25
5.3.1
LCD .......................................................................................................................................25
5.3.2
GPMC ....................................................................................................................................25
5.3.3
MMC1 ....................................................................................................................................25
5.3.4
SPI .........................................................................................................................................25
5.3.5
I2C .........................................................................................................................................26
5.3.6
Serial Ports ............................................................................................................................26
Page 6 of 92
REF: BBONE_SRM
5.3.7
5.3.8
5.3.9
5.3.10
5.3.11
6.0
BeagleBone System Reference
Manual
Rev A6.0.0
A/D Converters ......................................................................................................................26
GPIO......................................................................................................................................26
CAN Bus ................................................................................................................................26
TIMERS.............................................................................................................................26
PWM .................................................................................................................................26
DETAILED BOARD DESIGN .........................................................................................................28
6.1 SYSTEM BLOCK DIAGRAM ...............................................................................................................28
6.2 PROCESSOR ......................................................................................................................................28
6.2.1
Processor Block Diagram......................................................................................................29
6.3 SYSTEM POWER ...............................................................................................................................30
6.3.1
TPS65217B PMIC .................................................................................................................30
6.3.2
5V DC Power Input ...............................................................................................................33
6.3.3
USB Power ............................................................................................................................33
6.3.4
Power Source Selection .........................................................................................................34
6.3.5
Power Consumption ..............................................................................................................34
6.3.6
Power Sequencing .................................................................................................................35
6.3.7
TPS65217B Power Up ...........................................................................................................35
6.3.8
Voltage Rails..........................................................................................................................36
6.3.9
Power Indicator LED ............................................................................................................37
6.3.10
Expansion 3.3V LDO ........................................................................................................38
6.4 CURRENT MEASUREMENT................................................................................................................38
6.4.1
SYS_5V Connection ...............................................................................................................38
6.4.2
SYS_VOLT Connection ..........................................................................................................39
6.4.3
MUX_OUT Connection .........................................................................................................39
6.4.4
Current Calculation ...............................................................................................................39
6.5 TWO PORT USB HUB ......................................................................................................................40
6.5.1
Processor USB Port ...............................................................................................................40
6.5.2
HUB Power ...........................................................................................................................40
6.5.3
Crystal and Reset ...................................................................................................................41
6.5.4
FT2232H Serial Adapter .......................................................................................................41
6.5.5
Processor USB Port ...............................................................................................................41
6.6 FT2232H USB TO SERIAL ADAPTER ...............................................................................................42
6.6.1
EEPROM ...............................................................................................................................42
6.6.2
JTAG ......................................................................................................................................43
6.6.3
Serial Port .............................................................................................................................43
6.7 256MB DDR2 MEMORY .................................................................................................................43
6.7.1
DDR 2 Design ........................................................................................................................44
6.7.2
DDR VTP Termination Resistor ............................................................................................45
6.7.3
User LEDs .............................................................................................................................45
6.8 10/100 ETHERNET ............................................................................................................................46
6.8.1
Ethernet PHY Design .............................................................................................................46
6.8.2
Processor Signal Description ................................................................................................47
6.8.3
Clocking Mode .......................................................................................................................48
6.8.4
PHY Mode .............................................................................................................................48
6.8.5
MDIO Interface .....................................................................................................................49
6.8.6
PHY Reset ..............................................................................................................................49
6.8.7
Status LEDs ...........................................................................................................................49
6.8.8
Power .....................................................................................................................................49
6.9 USB HOST .......................................................................................................................................50
6.9.1
USB Host design ....................................................................................................................50
6.10
SD CONNECTOR ..........................................................................................................................51
6.11
EEPROM ....................................................................................................................................51
6.12
ADC INTERFACE .........................................................................................................................53
6.12.1
ADC Inputs .......................................................................................................................53
Page 7 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
6.12.2
VDD_ADC Interface .........................................................................................................53
6.13
EXPANSION HEADERS .................................................................................................................54
6.13.1
Expansion Header P8 .......................................................................................................54
6.13.2
P8 Signal Pin Mux Options..............................................................................................55
6.13.3
Expansion Header P9 .......................................................................................................59
6.13.4
PMIC Expansion Header ..................................................................................................64
6.13.5
Backlight Interface ............................................................................................................64
6.13.6
Battery Interface ...............................................................................................................65
7.0
CAPE BOARD SUPPORT ................................................................................................................66
7.1 EEPROM ........................................................................................................................................66
7.1.1
EEPROM Address .................................................................................................................67
7.1.2
I2C Bus ..................................................................................................................................67
7.1.3
EEPROM Write Protect .........................................................................................................68
7.1.4
EEPROM Data Format .........................................................................................................69
7.1.5
Pin Usage ..............................................................................................................................70
7.2 PIN USAGE CONSIDERATION ............................................................................................................74
7.2.1
Boot Pins ...............................................................................................................................74
7.3 EXPANSION CONNECTORS................................................................................................................75
7.3.1
Non-Stacking Headers-Single Cape .....................................................................................75
7.3.2
Battery Connector- Single .....................................................................................................76
7.3.3
Main Expansion Headers-Stacking .......................................................................................77
7.3.4
Battery Connector Stacking ...................................................................................................78
7.3.5
Stacked Capes w/Signal Stealing ...........................................................................................79
7.3.6
Retention Force .....................................................................................................................79
7.3.7
BeagleBone Female Connectors ............................................................................................80
7.4 SIGNAL USAGE ................................................................................................................................80
7.5 CAPE POWER....................................................................................................................................81
7.5.1
Main Board Power ................................................................................................................81
7.5.2
Expansion Board External Power .........................................................................................82
7.6 MECHANICAL ...................................................................................................................................82
7.6.1
Standard Cape Size ................................................................................................................82
7.6.2
Extended Cape Size ...............................................................................................................83
7.6.3
Enclosures .............................................................................................................................84
8.0
BOARD SETUP .................................................................................................................................85
8.1 CREATING A SD CARD ....................................................................................................................85
8.2 USB POWERED SETUP .....................................................................................................................85
8.3 DC POWERED SETUP .......................................................................................................................86
8.4 ADVANCED TEST .............................................................................................................................86
8.4.1
Equipment Needed .................................................................................................................87
8.4.2
Procedure ..............................................................................................................................87
8.4.3
Debugging .............................................................................................................................87
9.0
SOFTWARE SUPPORT ...................................................................................................................88
9.1
9.2
9.3
TUTORIALS ......................................................................................................................................88
REINSTALLING THE ANGSTROM IMAGE ...........................................................................................88
REBUILDING THE ANGSTROM IMAGE...............................................................................................89
10.0
BEAGLEBONE MECHANICAL SPECIFICATION ...............................................................91
11.0
DESIGN INFORMATION ...........................................................................................................92
Page 8 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
Figures
Figure 1.
Figure 2.
Figure 3.
Figure 4.
Figure 5.
Figure 6.
Figure 7.
Figure 8.
Figure 9.
Figure 10.
Figure 11.
Figure 12.
Figure 13.
Figure 14.
Figure 15.
Figure 16.
Figure 17.
Figure 18.
Figure 19.
Figure 20.
Figure 21.
Figure 22.
Figure 23.
Figure 24.
Figure 25.
Figure 26.
Figure 27.
Figure 28.
Figure 29.
Figure 30.
Figure 31.
Figure 32.
Figure 33.
Figure 34.
Figure 35.
Figure 36.
Figure 37.
Figure 38.
Figure 39.
Figure 40.
Figure 41.
Figure 42.
Top Side Components ................................................................................... 18
Bottom Side Components ............................................................................. 19
Board Connector and Indicators ................................................................... 20
Main Board Expansion Connector ................................................................ 24
System Block Diagram ................................................................................. 28
Processor Block Diagram ............................................................................. 29
Power Subsection Block Diagram ................................................................ 30
TPS65217B Block Diagram ......................................................................... 32
5V DC Power Input ...................................................................................... 33
USB Power Input ...................................................................................... 34
Power Sequencing ..................................................................................... 35
RTC_PORZ Control ................................................................................. 36
Expansion 3.3V Regulator ........................................................................ 38
Current Measurement................................................................................ 39
USB HUB Design ..................................................................................... 40
FT2232H Design ....................................................................................... 42
DDR Device Block Diagram .................................................................... 44
DDR Design .............................................................................................. 44
User LEDS ................................................................................................ 45
10/100 Ethernet PHY Design.................................................................... 47
10/100 Ethernet PHY Default Settings ..................................................... 48
USB Host Design ...................................................................................... 50
SD Connector Design ............................................................................... 51
EEPROM Design Rev A3,A4, and A5 ..................................................... 52
EEPROM Design Rev A6 ......................................................................... 53
PMIC Expansion Header .......................................................................... 64
Backlight Circuitry.................................................................................... 64
Battery Circuitry ....................................................................................... 65
Expansion Board EEPROM No Write Protect ......................................... 67
Expansion Board EEPROM Write Protect ............................................... 68
Expansion Boot Pins ................................................................................. 74
Single Expansion Connector ..................................................................... 75
Single Cape Expansion Connector............................................................ 76
Battery/Backlight Expansion Connector................................................... 77
Expansion Connector ................................................................................ 77
Stacked Cape Expansion Connector ......................................................... 78
Stacked Battery Expansion Connector...................................................... 79
Stacked w/Signal Stealing Expansion Connector ..................................... 79
Connector Pin Insertion Depth.................................................................. 80
Cape Board Dimensions .......................................................................... 83
Board Top Profile ..................................................................................... 91
Board Bottom Profile ................................................................................ 91
Page 9 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
Tables
Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 8.
Table 9.
Table 10.
Table 11.
Table 12.
Table 13.
Table 14.
Table 15.
Table 16.
Table 17.
Table 18.
Table 19.
Table 20.
Change History ............................................................................................. 12
BeagleBone Features .................................................................................... 17
BeagleBone Power Consumption(mA@5V) ................................................ 34
DDR Addressing ........................................................................................... 43
User LED Control ......................................................................................... 46
Processor Ethernet Signals ............................................................................ 47
EEPROM Contents ....................................................................................... 52
Expansion Header P8 Pinout ........................................................................ 54
P8 Mux Options Modes 0-3 .......................................................................... 55
P8 Mux Options Modes 4-7 .......................................................................... 57
Expansion Header P9 Pinout ........................................................................ 59
P9 Mux Options Modes 0-3 ......................................................................... 60
P9 Mux Options Modes 4-7 ......................................................................... 62
Expansion Board EEPROM .......................................................................... 69
EEPROM Pin Usage ..................................................................................... 71
Single Cape Connectors ................................................................................ 76
Single Cape Backlight Connectors ............................................................... 77
Stacked Cape Connectors ............................................................................. 78
Stacked Cape Connectors ............................................................................. 79
Expansion Voltages ...................................................................................... 81
Page 10 of 92
REF: BBONE_SRM
1.0
BeagleBone System Reference
Manual
Rev A6.0.0
Introduction
This document is the System Reference Manual for the BeagleBone. It covers revision
A3 thru A6. It is intended as a guide to assist anyone purchasing or who are considering
purchasing the board to understand the overall system design and the features of the
BeagleBone. It can also be used as a reference for the design for those who are
implementing this design into their own product.
This design is subject to change without notice as we will work to keep improving the
design as the product matures.
For support, the primary mailing list is [email protected]
For HW support use the mailing list and also refer to the HW support WIKI at
Page 11 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
2.0
Change History
2.1
Change History
Table 1.
Rev
0.1
0.2
A4.0.4
A5
A6
Rev A6.0.0
Change History
Changes
Original Release for review
1.
2.
3.
4.
1.
2.
3.
4.
5.
6.
1.
2.
3.
Added notch dimension to the Cape board outline.
Added power numbers to features table.
Corrected USB0 and USB1 numbering
Made correction on two signals on Tables 10 thru 12.
Rev A4 Release
Documented the changes.
Updated Figure 28 to show pullup resistors as 5.6K.
Added note to Cape section that mounting holes are not required.
Fixed link to the TPS65217B documentation.
Added section on ADC interface.
Added clarification on image creation process.
Added more detail on USB 5VDC supplied to Capes.
Corrected section 6.3.6 to reflect four UART ports instead of
five.
4. Updated Figure 36 with more hole dimensions.
5. Added section on the rev A4 to Rev A5 changes.
6. Made changes in Table 12.
7. Added note on polarity of Yellow Ethernet LED in section 7.8.7.
1. Added changes for rev A6 that covered fixing of the link LED,
JTAG Reset, and DHCP issue.
2. Added PRU information and two additional signals for the PRU.
3. Added write protection to EEPROM.
4. Updated Cape section. Added clarifications and more
information.
5. Fixed numbering of subsections in Section 7.0
6. Fixed error in Table 9 pin 6 to MMC1_DAT3.
7. Fixed error in Table 9 pin 22 Mode 1 should be MMC1_DAT5
and Mode 2 is now blank.
8. Fixed error in Table 9 pin 23Mode 1 should be MMC1_DAT4.
9. Updated Table 7 to show the revision number in the EEPROM
matches the revision of the board.
10. Corrected various typos.
11. Updated Battery Interface section to accurately document the
LDO dropout at 200mV.
12. Added SW Support section.
Page 12 of 92
Date
By
November 4,
2011
GC
November 11,
2011
GC
January 3, 2012
GC
GC
January 31, 2012
May 9, 2012
GC
REF: BBONE_SRM
2.2
BeagleBone System Reference
Manual
Rev A6.0.0
Rev A5 vs. A6
Rev A6 underwent several changes:






Fixed the Yellow Link LED and R219 issue by adding a pulldown to the SMSC
PHY.
Added two PRU signals top provide a full 8bit PRU interface when the LCD
board is installed.
Move the resistors that where too close to the standoff.
Removed connection to the VPP pin from the layout.
Fixed spurious reset issues on JTAG connect.
Addressed LAN8710 default mode.
There were no changes made that affect the operation of the board form a SW
perspective. Feature and operation wise the A6 is the same as an A3.
2.2.1
PCB Changes
Here are the changes that affected the PCB:
1) Added R220
2) Added R217, R218, R202, and R221.
3) Added etch to route the PRU signals to the expansion header using the above
resistors.
4) Moved R180 and R150.
5) Changed revision to C2.
2.2.2
Design Changes
1) Changed R219 is now installed.
2) Added R220 a 10K pulldown to pin 18 of the SMSC PHY to allow R219 addition
to work as expected.
3) Removed the connection to the VPP pin on the processor.
4) Added R221, R218, R217, R202 to facilitate the addition of two signals,
GPIO3_18 and GPIO3_19 to the expansion bus header to provide two more
signals for the PRU access.
5) Changed R210 to installed and added test point to allow the EEPROM to be
programmed but with added protection to prevent corruption. Also added Test
Point to enable programming.
6) Moved resistors R189 and R150 to provide more clearance around mounting hole.
7) Removed R122 which was not connected to the correct pin on the on the
LAN8710 for setting the HW default mode.
8) Removed R163 to disconnect the FT2232 reset out that was causing spurious
resets when connecting the JTAG on a running board.
9) Added above changes as needed to the BOM.
Page 13 of 92
REF: BBONE_SRM
2.3
BeagleBone System Reference
Manual
Rev A6.0.0
Rev A4 vs. A5
There was a key issue with rev A4 where R219 was causing some unintended issues with
the operation of the Ethernet interface.
2.3.1
PCB Changes
There were no PCB changes.
2.3.2
Design Changes
1) R219 was removed from the assembly. It was installed on Rev A6 with a PCB
change.
2.3.3
Production Changes
1) Changes were made in production testing to test for bad Reset switches
2) Reset switches are not being taken through the wash.
3) The FTDI VID was changed to 0403 and the PID was changed to 6010.
Description was changed to “BeagleBone/XDS100”
This version of the board returns the functionality of the board to that of the Rev A3 via
the removal of R219. It uses the same PCB revision as the A4. It also ships with an
updated version of the Angstrom image providing out of the box support for the DVI-D
and 7” LCD Capes.
There will be three possible versions of the Rev A5. One will be the new production
version that is built from the ground up as an A5, R219 not installed.
The second version will be a reworked Revision A4 that has R219 removed at the factory
and retested.
The third version will be a revision A3 that just has the updated SW added. All reworked
versions will have the reset switches double checked as well. All reworked boards will be
retested using the full production test process.
You will be able to identify these versions via the serial number. They all will be labeled
as revision A5. The two digits after the BB in the serial number, S/N: 5111BB000023,
will indicate the board. A fresh revision A5, will be 00, A4 reworked will be 01, and a
recertified A3 will be 02. There is no functional or operational difference between any of
these boards. They are all revision A5 and will ship with the same SW.
For those with Revision A3 and A4, you will be able to download the latest shipping
image from http://circuitco.com/support/index.php?title=BeagleBone and have all the
features of the Revision A5. For A4 users, you will need to remove R219 and instructions
are provided at http://circuitco.com/support/index.php?title=BeagleBone .
Page 14 of 92
REF: BBONE_SRM
2.4
BeagleBone System Reference
Manual
Rev A6.0.0
Rev A3 vs. A4
No functional changes were made to the board as it relates to its overall operation other
than the LED fix for the Speed indicator on the Ethernet connector. Main change was the
addition of a different SD connector.
2.4.1
PCB Changes
The following PCB changes were made to facilitate the acquisition of components to
meet the production schedule which required different footprints.



2.4.2
New microSD connector. PCB layout was changed to facilitate the change.
50 ohm resistor was changed to a 0402 footprint.
Changes C7 footprint to 0805.
Design Changes
Added a 10k pull down resistor, R219, to fix polarity of the speed LED on the Ethernet
connector.
NOTE: The pictures in this document were not changed to
reflect the A4/A5/A6 versions. The benefit of doing this is very
small. The only obvious difference is the big resistor below the
USB Host connector is no longer there.
2.5
Known Issues
For an up to date list of all known issue per revision, please refer to the HW WIKI
support page at http://circuitco.com/support/index.php?title=BeagleBone#Known_Issues
.
Page 15 of 92
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2.6
BeagleBone System Reference
Manual
Rev A6.0.0
BeagleBone Overview
The BeagleBone is the latest addition to the BeagleBoard.org family and like its’
predecessors, is designed to address the Open Source Community, early adopters, and
anyone interested in a low cost ARM Cortex A8 based processor. It has been equipped
with a minimum set of features to allow the user to experience the power of the processor
and is not intended as a full development platform as many of the features and interfaces
supplied by the processor are not accessible from the BeagleBone via onboard support of
some interfaces.
2.7
BeagleBone Expansion
By utilizing comprehensive expansion connectors, the BeagleBone is highly extensible to
add many features and interfaces via add-on boards or Capes. Capes refer to the shape of
the add-on boards and are discussed later in this document. A majority of the signals from
the processor are exposed via the expansion headers and can be accessed there, but may
require additional hardware in order to use them. This will be handled by the creation of
Capes in the future. Due to the deep multiplexing of the pins, there are limits as to how
many interfaces can coexist at any one time. Refer to the processor documentation for
more information.
2.8
BeagleBone Design Material
All of the design information is freely available and can be used as the basis for a product
or design. If the user decides to use the BeagleBone design in a product, they assume all
responsibility for such use and are totally responsible for all aspects of its use.
We do not sell BeagleBone boards for use in end products. We choose to utilize our
resources to create boards for the expressed purpose as previously stated. We will be
changing the design to improve it and will not continue to make older revisions as the
overall design matures.
There are programs available for someone to have the board built to their specifications
and then use that board in a product. All of the design information is freely available and
will be kept up to date. Anyone is free to use that information as previously stated.
2.9
In The Box
The BeagleBone ships in a box with the following components:



BeagleBone
USB Cable
4GB uSD card with SW and documentation
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3.0
BeagleBone System Reference
Manual
Rev A6.0.0
BeagleBone Features and Specification
This section covers the specifications and features of the BeagleBone and provides a high
level description of the major components and interfaces that make up the BeagleBone.
Table 2 provides a list of the BeagleBone’s features.
Table 2.
BeagleBone Features
Feature
Processor
Memory
PMIC TPS65217B
Debug Support
Power
PCB
AM3359
500MHZ-USB Powered
720MHZ-DC Powered
256MB DDR2 400MHZ (128MB Optional)
Power Regulators
LiION Single cell battery charger (via expansion*)
20mA LED Backlight driver, 39V, PWM (via expansion*)
*(Additional components required)
miniUSB connector
USB to Serial Adapter
On Board JTAG via USB
4 USER LEDs
Optional 20-pin CTI JTAG
5VDC External jack
USB
6 layers
3.4” x 2.1”
HS USB 2.0 Client Port
Power
4-User Controllable LEDs
Access to the USB1 Client mode
HS USB 2.0 Host Port
USB Type A Socket, 500mA LS/FS/HS
Ethernet
SD/MMC Connector
User Interface
Overvoltage Protection
5V Power
10/100, RJ45
microSD , 3.3V
1-Reset Button
Shutdown @ 5.6V MAX
Power 5V, 3.3V , VDD_ADC(1.8V)
3.3V I/O on all signals
McASP0, SPI1, I2C, GPIO(65), LCD, GPMC, MMC1, MMC2, 7
AIN(1.8V MAX), 4 Timers, 3 Serial Ports, CAN0,
EHRPWM(0,2),XDMA Interrupt, Power button, Battery Charger, LED
Backlight, Expansion Board ID (Up to 3 can be stacked)
USB or 5.0VDC to 5.2VDC
See Table 3 for power consumption numbers.
Weight
1.4 oz (39.68 grams)
Indicators
Expansion Connectors
*Board will boot to 500MHz under USB power.
NOTE: DUE TO MULIPLEXING ON THE PINS OF THE PROCESSOR, ALL OF THESE
EXPANSION SIGNALS CANNOT BE AVAILABLE AT THE SAME TIME.
NOTE: The battery configuration is not suitable to power the BeagleBone in its current
configuration.
The following sections provide more detail on each feature and are covered under each
section of this document.
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3.1
BeagleBone System Reference
Manual
Rev A6.0.0
Board Component Locations
The Figure 1 below shows the top side locations of the key components on the PCB
layout of the BeagleBone.
Figure 1.
Top Side Components
Figure 2 shows the key components mounted on the back side of the board.
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Manual
7
Figure 2.
Bottom Side Components
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3.2
BeagleBone System Reference
Manual
Rev A6.0.0
Board Connector and Indicator Locations
Figure 3 shows the key connector and LED locations of the BeagleBone.
Figure 3.
Board Connector and Indicators
NOTE: Be careful if you are considering using standoffs on the BeagleBone. The
mounting hole next to the DC power jack has resistors that are a little too close to the
hole and if you are not careful, you can damage those resistors when attaching the
standoff. Use as small a diameter standoff as possible.
Page 20 of 92
REF: BBONE_SRM
4.0
BeagleBone System Reference
Manual
Rev A6.0.0
BeagleBone Design Specification
This section provides a high level description of the design of the BeagleBone.
4.1
Processor
The board currently uses either the AM3359 or AM3358 processor in the 15x15
package. Actual processor speed will be determined by the actual devices supplied. The
board is being released prior to the processor being in full production and as a result, has
the AM3359 due to availability of those parts at this time. When changed to the AM3358,
no loss of features will be experienced.
4.2
Memory
As single x16 bit DDR2 memory device is used. The design supports 128MB or 256MB
of memory. The standard configuration is 256MB at 400MHz. A 128MB version may be
built later, but there are no definite plans for this.
A single 32KB EEPROM is provided on I2C0 that holds the board information. This
information includes board name, serial number, and revision information. Unused areas
can be used by SW applications if desired.
4.3
Power Management
The TPS65127B power management device is used along with a separate LDO to
provide power to the system.
4.4
PC USB Interface
The board will have an onboard USB HUB that concentrates two USB ports used on the
board to one to facilitate the use of a single USB connector and cable to the PC. Support
via this HUB includes:



USB to serial debug
USB to JTAG
USB processor port access
When connected to the PC each of these will show up as ports on the PC.
4.4.1
Serial Debug Port
Serial debug is provided via UART0 on the processor using a dual channel FT2232H
USB to serial device from FTDI to connect these signals to the USB port. Serial signals
include Tx, Rx, RTS, and CTS.
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Rev A6.0.0
A single EEPROM is provided on the FT2232H to allow for the programming of the
vendor information so that when connected, the board can be identified and the
appropriate driver installed.
4.4.2
JTAG Port
The second port on the FT2232H will be used for the JTAG port. Direct connection to the
processor is made from the FT2232H. There is a JTAG header provided on the board as
an option, but it is not populated.
4.4.3
USB0 Port
The HUB connects direct to the USB0 port on the processor. This allows that port to be
accessible from the same USB connector as the Serial and JTAG ports.
4.5
MicroSD Connector
The board is equipped with a single microSD connector to act as the primary boot source
for the board. A 4GB microSD card is supplied with each board. The connector will
support larger capacity SD cards.
4.6
USB1 Port
On the board is a single USB Type A connector with full LS/FS/HS Host support that
connects to USB1 on the processor. The port can provide power on/off control and up to
500mA of current at 5V. Under USB power, the board will not be able to supply the full
500mA, but should be sufficient to supply enough current for a lower power USB device.
You can use a wireless keyboard/mouse configuration or you can add a HUB for standard
keyboard and mouse interfacing if required.
4.7
USB Client Port
Access to USB0 is provided via the onboard USB Hub. It will show up on a PC as a
standard USB device.
4.8
Power Sources
The board can be powered from a USB port on a PC or from an optional 5VDC power
supply. The power supply is not provided with the board and must be a grounded power
supply. The USB cable is shipped with the board.
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BeagleBone System Reference
Manual
Rev A6.0.0
When powered from USB, the board is limited to 500 MHz. The onboard HUB +
FT2232H power consumption does not leave room in the 500mA budget for the boot
process. For 720 MHz operation, DC power is required. The lowest power mode is DC
w/o the USB port connected, even at 720MHz.
Power can be supplied via a 2.1mm x 5.5mm center connector when connected to a
positive power supply rated at 5VDC +/- .1V and 1A. This is similar to the power supply
as currently used on BeagleBoards and the board can be powered from a supply that was
used to power the BeagleBoard. Do not apply voltages in excess of 5V to the DC input.
The DC power supply must be grounded.
4.9
Reset Button
When pressed and released, causes a reset of the board. Due to the small size of the
switch, you will not experience a lot of travel when pushing the switch.
4.10
Indicators
There are five total green LEDs on the board. Four can be controlled by the user and one
static LED.
o One power LED indicates that power is applied.
o Four Green LEDs that can be controlled via the SW by setting GPIO ports.
4.11
CTI JTAG Header
An optional 20 pin CTI JTAG header can be provided on the board to facilitate the SW
development and debugging of the board by using various JTAG emulators. In order to
use the connector, series resistors must be removed to isolate the USB to JTAG feature.
This header is not supplied standard on the board and the typical user will not be able to
make the resistor changes.
Page 23 of 92
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5.0
BeagleBone System Reference
Manual
Rev A6.0.0
Expansion Interface
This section describes the expansion interface and the features and functions available
from the expansion header.
5.1
Main Board Expansion Header
Two 46 pin dual row .1 x .1 female headers are supplied on the board for access to the
expansion signals. Due to the number of pins, a low insertion force header has been
chosen to facilitate the removal of the Capes. However, due to the large number of pins,
removal can be difficult and care should be taken in the removal of the boards connected
to the expansion headers. Figure 4 below is a picture of the female header used.
Figure 4.
5.2
Main Board Expansion Connector
Cape Expansion Boards
Each expansion board or Cape will have 2 46 pin connectors. Their exact type and
configuration will vary depending on the method used. Refer to Section 8 for more
details. The connectors used will be thruhole connectors.
Up to four Capes can be stacked onto the BeagleBone. Each board will have the same
EEPROM as is found on the main board but will be at different addresses to allow for
scanning for expansion boards via the I2C bus. Each board will be equipped with a 2
position dipswitch to set the address of the board based on the stack position. It is up to
the user to insure the proper setting of this dipswitch to prevent a conflict on the I2C bus.
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Manual
Rev A6.0.0
Standard expansion board size is 3.4” x 2.1”. The board will have a notch in it to act as a
key to insure proper orientation. The key is around the Ethernet connector on the main
board.
Oversize boards, such as LCD panels, are allowed. The main board will extend out from
under these boards.
5.3
Exposed Functions
This section covers functionality that is accessible from the expansion header.
NOTE: Not all functionality is available at the same time due to the extensive pin
muxing of the signals on the processor.
Please refer to the processor documentation for detailed information on the uses and
functions of the pins listed in the following sections.
5.3.1
LCD
A full 24 bit LCD panel can be supported. With the main board having backlight and
touchscreen functionality, will simply and lower the cost of LCD expansion boards.
Backlight power is limited to 25mA, so this may not be enough for larger panels.
If other functions are needed on an expansion board, such as NAND support, the full 24
bit display may not be able to be supported due to the pin muxing.
You can also create 16 bit LCD boards. The advantage here is that this uses fewer pins on
the expansion connectors leaving more signals to be used by other expansion boards.
5.3.2
GPMC
Access to the GPMC bus is provided. Depending on the configuration needed, this may
result in the loss of the LCD interface. Support for a 16 bit wide NAND is provided by
the expansion board. This will limit the LCD display to 16Bits. Make sure you review
and understand the pin muxing option before doing a design.
5.3.3
MMC1
MMC1 signals are exposed on the expansion headers.
5.3.4
SPI
There are two SPI ports available on the expansion header. SPIO0 has one CS and SPI1
has two CS signals.
Page 25 of 92
REF: BBONE_SRM
5.3.5
BeagleBone System Reference
Manual
Rev A6.0.0
I2C
There are two I2C Ports on the expansion header, I2C1 and I2C2. I2C2 is used for the
EEPROMS on the expansion boards and must always be accessible. SW should never
mess with these signals. Other components on a Cape can use this bus as long as it does
not conflict with the base addresses of the Capes.
5.3.6
Serial Ports
There are four serial ports on the expansion headers. UART ports 1, 2, 4 ports have TX,
Rx, RTS and CTS signals while UART5 only has TX and RX. UART 3 is NOT available
for use.
5.3.7
A/D Converters
Seven 100K sample per second A to D converters are available on the expansion header.
NOTE: Maximum voltage is 1.8V. Do not exceed this voltage. Voltage dividers
should be used for voltages higher than 1.8V.
In order to use these signals, level shifters will be required. These signals connect direct
to the processor and care should be taken not to exceed this voltage.
The VDD_ADC voltage is 1.8V and is not to be used to power anything. It is only a
reference voltage and should be used to set the reference level for those interfaces added
to the CAPE and not used to supply power.
5.3.8
GPIO
A maximum of 66 GPIO pins are accessible from the expansion header. All of these pins
are 3.3V and can be configured as inputs or outputs. Any GPIO can be used as an
interrupt and is limited to two interrupts per GPIO Bank for a maximum of eight pins as
interrupts.
5.3.9
CAN Bus
There are two can bus interfaces available on the expansion header supporting CAN
version 2 parts A and B. The TX and RX digital signals are provided. The drivers and
connectors will need to be provided on a daughter card for use.
5.3.10 TIMERS
There are four timer outputs on the expansion header.
5.3.11 PWM
There are up to eight PWM outputs on the expansion header.
Page 26 of 92
REF: BBONE_SRM


BeagleBone System Reference
Manual
High Resolution Outputs- up to 6 single ended.
ECAP PWM- 2 outputs
Page 27 of 92
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REF: BBONE_SRM
6.0
Rev A6.0.0
Detailed Board Design
This section describes the detailed design of the BeagleBone. Please be sure to reference
the AM3359 datasheet and technical reference manual to gain a deeper understanding.
6.1
System Block Diagram
Figure 5 is the high level system block diagram of the BeagleBone.
Figure 5.
System Block Diagram
Each of these sections is discussed in more detail in the following sections.
6.2
Processor
The board is designed to use the AM3358 processor in the 15 x 15 package.
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REF: BBONE_SRM
6.2.1
BeagleBone System Reference
Manual
Rev A6.0.0
Processor Block Diagram
Figure 6 is a high level block diagram of the processor. For more information on the
processor, go to http://www.ti.com/product/am3359
Figure 6.
Processor Block Diagram
Page 29 of 92
REF: BBONE_SRM
6.3
BeagleBone System Reference
Manual
Rev A6.0.0
System Power
Figure 7 is a high level block diagram of the power section design of the BeagleBone.
Figure 7.
6.3.1
Power Subsection Block Diagram
TPS65217B PMIC
The main Power Management IC (PMIC) in the system is the TPS65217B. The
TPS65217B is a single chip power management IC consisting of a linear dual-input
power path, three step-down converters, four LDOs, and a high-efficiency boost
converter to power two strings of up to 10 LEDs in series. The system is supplied by a
USB port or DC adapter. Three high-efficiency 2.25MHz step-down converters are
targeted at providing the core voltage, MPU, and memory voltage for the board.
The step-down converters enter a low power mode at light load for maximum efficiency
across the widest possible range of load currents. For low-noise applications the devices
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Rev A6.0.0
can be forced into fixed frequency PWM using the I2C interface. The step-down
converters allow the use of small inductors and capacitors to achieve a small solution
size.
LDO1 and LDO2 are intended to support system-standby mode. In SLEEP state output
current is limited to 100uA to reduce quiescent current whereas in normal operation they
can support up to 100mA each. LDO3 and LDO4 can support up to 285mA each.
By default only LDO1 is always ON but any rail can be configured to remain up in
SLEEP state. Especially the DCDC converters can remain up in a low-power PFM mode
to support processor Suspend mode. The TPS65217B offers flexible power-up and
power-down sequencing and several house-keeping functions such as power-good output,
pushbutton monitor, hardware reset function and temperature sensor to protect the
battery.
For more information on the TPS65217B, refer to http://www.ti.com/product/tps65217b .
Figure 8 is the high level block diagram of the TPS65217B.
Page 31 of 92
REF: BBONE_SRM
Figure 8.
BeagleBone System Reference
Manual
TPS65217B Block Diagram
Page 32 of 92
Rev A6.0.0
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REF: BBONE_SRM
6.3.2
Rev A6.0.0
5V DC Power Input
Figure 9 is the design of the 5V DC input circuit to the TPS65217B.
VDD_5V
SY S_5V
U1
1
3
2
1
7
1
3
6
2
OUT1
OUT0
EN
FLAG
2
PJ-200A
IN0
IN1
GND
P5
U2
5
4
10
DC_IN
AC
SY S1
SY S2
7
8
3
TPS65217B
C1
NCP349
4.7uF,6.3V
DGND
DGND
DGND
Figure 9.
5V DC Power Input
A 5VDC supply can be used to provide power to the board. The power supply current
depends on how many and what type of add on boards are connected to the board. For
typical use, a 5VDC supply rated at 1A should be sufficient. If heavier use of the
expansion headers or USB host port is expected, then a higher current supply will be
required.
The connector used is a 2.1MM center positive x 5.5mm outer barrel. A NCP349 over
voltage device is used to prevent the plugging in of 7 to 12 V power supplies by mistake.
The NCP349 will shut down and the board will not power on. No visible indicator is
provided to indicate that an over voltage condition exists. The board will not power up.
The 5VDC rail is connected to the expansion header. It is possible to power the board via
the expansion headers from a add-on card. The 5VDC is also available for use by the
add-on cards when the power is supplied by the 5VDC jack on the board.
6.3.3
USB Power
The board can also be powered from the USB port. A typical USB port is limited to
500mA max. When powering from the USB port, the VDD_5V rail is not provided to
the expansion header. So Capes that require that rail will not have that rail available for
use. The 5VDC supply from the USB port is provided on the SYS_5V rail of the
expansion header for use by a Cape. Figure 10 is the design of the USB power input
section.
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Rev A6.0.0
9
G4
5
4
3
2
1
SY S_5V
U2
12
G2
G1
ID
D+
DVB
7
mini USB-B
6
G3
G5
8
REF: BBONE_SRM
P3
DC
SY S1
SY S2
7
8
DGND
C2
TPS65217B
4.7uF,6.3V
DGND
Figure 10. USB Power Input
6.3.4
Power Source Selection
The selection of either the 5VDC or the USB as the power source is handled internally to
the TPS65217B and automatically switches to 5VDC power if both are connected. SW
can change the power configuration via the I2C interface from the processor. In addition,
the SW can read the TPS65217B and determine if the board is running on the 5VDC
input or the USB input. This can be beneficial to know the capability of the board to
supply current for things like operating frequency and expansion cards.
It is possible to power the board from the USB input and then connect the DC power
supply. The board will switch over automatically to the DC input.
6.3.5
Power Consumption
The power consumption of the board varies based on power scenarios and the board boot
processes. Table 3 is an analysis of the power consumption of the board in these various
scenarios.
Table 3.
BeagleBone Power Consumption(mA@5V)
MODE
Reset
UBoot
Kernel Booting (Peak)
Kernel Idling
USB
180
363
502
305
DC
60
230
350
170
DC+USB
190
340
470
290
When the USB is connected, the FT2232 and HUB are powered up. This causes an
increase in current. When the USB is not connected, these devices are in a lower power
state. This is accounts for roughly 120mA of current and is the reason for the increased
current when the USB is connected.
The current will fluctuate as various activates occur, such as the LEDs on and SD card
accesses.
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6.3.6
Rev A6.0.0
Power Sequencing
The power up process is made up of several stages and events. Figure 11 is the events
that make up the power up process of the system.
Figure 11. Power Sequencing
6.3.7
TPS65217B Power Up
When voltage is applied, DC or USB, the TPS65217B connects the power to the SYS
output pin which drives the switchers and LDOS in the TP65217B.
At power up all switchers and LDOs are off except for the VRTC LDO (1.8V), provides
power to the VRTC rail. Once the RTC rail powers up, the RTC_PORZ pin of the
processor can be release. Figure 12 is the circuit that controls the RTC_PORZ pin.
Page 35 of 92
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REF: BBONE_SRM
Rev A6.0.0
VRTC
C21
VRTC
1
8
8
0.01uf ,16V
U17A
DGND
7
2
VRTC_DET
1.1K,1%
R17
5
VRTC_DETB
6
R141
U17B
10K,1%
LDO_PGOOD
2
R143
3
VRTC_DET_OUT
RTC_PORZ
0,1%,DNI
4
SN74AUP2G08
4
SN74AUP2G08
C22
0.01uf ,16V
DGND
R18
DGND
12.1K,1%
DGND
DGND
Figure 12. RTC_PORZ Control
There are actually two circuits in this design. One uses a pair of AND gates to create the
RTC_PORZ signal and the other uses the LDO_PGOOD signal form the TPS65217B.
In the case of the AND gate circuit, once the VRTC rail comes up the circuit delays the
RTC_PORZ which releases the RTC circuitry in the processor.
In the case of the LDO_PGOOD signal, it is provided by the TPS65217B. As this signal
is 3.3V and the RTC_PORZ signal is 1.8V, a voltage divider is used. Once the LDOs are
up on the TPS65217B, this signal goes active. The LDOs on the TPS65217B are used to
power the VRTC rail on the processor.
The LDO_PGOOD version the default circuit currently used on the A3 design. It is
possible on future revisions that the AND gate circuitry will be removed from the design.
Once the RTC block reset is released, the processor starts the initialization process. After
the RTC stabilizes, the processor launches the rest of the power up process by activating
the PMIC_PWR_EN signal. This starts the TPS65217B power up process.
A separate signal, PMIC_PGOOD, holds the processor reset for 20ms after all power
rails are up.
6.3.8
Voltage Rails
There are seven voltages supplied by the TPS65217B. Each of these are described in the
following sections.
6.3.8.1
VDD_1V8
VDD_1V8 defaults to 1.8V on power up. The TPS65217B can deliver up
to 1200mA on this rail. This rail only connects to the processor and the
DDR2 memory.
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Manual
Rev A6.0.0
VDD_MPU
VDD_MPU defaults to 1.1V on power up. This voltage can be changed
under software control up to 1.25V in order to support higher processor
frequencies. The TPS65217B can deliver up to 1200mA on this rail. This
rail only connects to the processor.
6.3.8.3
VDD_CORE
VDD_CORE defaults to 1.1V on power up. This voltage should always
be left at 1.1V. The TPS65217B can deliver up to 1200mA on this rail.
This rail only connects to the processor.
6.3.8.4
VDD_3V3A
VDD_3V3A is the first of two 3.3V rails on the TPS65217B. The
TPS65217B can deliver up to 225mA on this rail. This rail connects to the
processor I/O rail voltage, TPS65217B I/O rail, and the SD/MMC card.
6.3.8.5
VDD_3V3B
VDD_3V3B is the second of two 3.3V rails on the TPS65217B. The
TPS65217B can deliver up to 225 mA on this rail. This rail connects to the
LAN8710, EEPROM, USB2412HUB, and FT2232.
6.3.8.6
VRTC
VRTC is the first rail to turn on during power up and is a 1.8V rail. The
TPS65217B can deliver up to 100mA on this rail. This rail connects to the
processor.
6.3.8.7
VLDO2
VLDO2 is a 3.3V rail that drives the power LED. This can be turned off
via SW if a low current mode for the board, such as standby, is required.
6.3.9
Power Indicator LED
The board has a single power indicator LED. It is controlled via 3.3V VLDO2 power rail
on the TPS65217B. When the TPS65217B has initialized and all switchers are on, the
VLDO2 rail is activated turning on the LED. If the switchers are not initialized, for
example if the processor does not enable the PWR_EN signal, the LED will not turn on.
The power LED indicates that the TPS65217B is powered up. It is possible for the SW to
turn off this rail to conserve power.
Page 37 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
6.3.10 Expansion 3.3V LDO
A separate LDO provides the 3.3V rail to the expansion headers. Figure 13 below is the
design of the LDO.
VDD_3V3A
SY S_VOLT
VDD_3V3EXP
U8
8
2
5
9
4
C6
4.7uF,6.3V
IN
NC1
EN
PAD
GND
OUT
NC2
NC3
FB
1
6
7
3
3V3EXP_FB
TPS73701DRBR
R150
52.3K,1%
C166
0.1uf ,16V
R189
30.1K,1%
DGND
DGND
Figure 13. Expansion 3.3V Regulator
U8 is a TPS73710 adjustable regulator that creates the 3.3V for the expansion bus by the
values of R150 and R189. The allowable current for this rail is set to 500mA based on
the design of the PCB, but that depends upon the total amount of current available from
the main input supply. The LDO is cpapble of up to 1A of current.
6.4
Current Measurement
The BeagleBone has a method under which the current consumption of the board, not
counting the USB Host port and expansion boards, can be measured. The voltage drop
across a .1 ohm resistor is measured to determine the current consumption. Figure 14
shows the interface to the TPS65217B to measure the current. The following sections
describe this circuitry in more detail.
6.4.1
SYS_5V Connection
The SYS_5V rail is measured to determine the high side of the series resistor. The
SYS_5V rail is connected to the MUX_OUT pin. Prior to being connected to the internal
second multiplexer, the voltage is divided by 3. A 5V signal will result in a voltage of
1.66V at the MUX_OUT pin.
Page 38 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
Figure 14. Current Measurement
6.4.2
SYS_VOLT Connection
The SYS_VOLT rail is measured to determine the high side of the series resistor. The
SYS_VOLT rail is connected to the MUX_OUT by setting the registers inside the
TPS65217B. The resistors R2 and R1 are provided to keep the same voltage divider
configuration as found in the SYS_5V rail located internal to the TPS65217B. However,
a 5V rail will give you 1.41V as opposed to the 1.66V found internal to the TPS65217B.
This works out to a devisor of 2.8. Be sure and work this into your final calculations.
6.4.3
MUX_OUT Connection
The MUX_OUT connection is divided by 2 before being connected to the processor. The
reason for this is that if the battery voltage is connected, it has no voltage divider
internally. If connected it could damage the processor. When calculating the voltages for
either side of the resistors, that voltage is divided by 2. Be sure and include this in your
calculations.
6.4.4
Current Calculation
The calculation for the current is based on .1mV is equal to 1mA. You can use the
following formula to calculate the current using the voltage readings as read by the
processor.
(((SYS_5V*2)*3.3)-((SYS_VOLT*2)*3.54)))/.1=Total mA.
Page 39 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.5
Rev A6.0.0
Two Port USB HUB
In order to provide access from a single USB port to the FT2232 and the processor USB
port, a SMSC USB2412 dual port USB 2.0 HUB is provided. This device connects to the
host PC.
Figure 15 is the design of the USB HUB.
VBUS_DET
R151
100K,1%
Dow nstream 1USBDP_DN1
8
DGND
USBDM_DN1
OCS1
PRTPWR1
22
21
DGND
1
28
7
FT_DP
10
FT_DM
10
FT_VBUS
10
G1
ID
D+
DVB
P3
G5
G4
9
USBDP_UP
USBDM_DN
USB_DC
G3
VBUS_DET
USBDP_UP
USBDM_UP
G2
Upstream
18
5
4
3
2
1
USB2412_QFN28
7
U11
mini USB-B
6
USB_DC
R149
100K,1%
8
USB_DC
R152
4.75K,1%
U16B
3
Dow nstreamUSBDP_DN2
2
12
OCS2
USBDM_DN2
PRTPWR2
VDD_3V3B
NON_REM[0:1]/nc
NON_REM1
SUSP_IND/NON_REM0
R156
100K,1%
17
RESETn
6
C136
0.1uf ,16V
DGND
DGND
C137
R160
3
Y5
4
RESET
RBIAS
USB0_DP
2
11
USB0_DM
24
R154
10K,1%,DNI
13
19
NON_REM1
NON_REM2
26
HUB_BIAS
2
4
R155
10K,1%,DNI
TP7
R157
12.1K,1%
DGND
R158
R159
10K,1% 100K,1%
14
10
TESTPT1
DGND
DGND
C139
C140
0.1uf ,16V4.7uF,6.3V
XTALIN/CLKIN
VDD33
VDD33
VDDPLLREF/VDD33
USB0_VBUS
VDD_3V3B
USB0_VBUS_PWR
C138
24MHz
4
VDD_3V3B
TEST
4
SN74LVC2G07DCK
4
5
Common
VDD33
VDDCRREF/VDD33
XTALIN
18pF,50V
NC
3
4
20
27
DGND
DGND
0.1uf ,16V
DGND
1M,1%,DNI
C141
0.1uf ,16V
1
C144
XTALOUT
23
HS_IND
16
TP8
18pF,50V
TESTPT1
rsv d3
0,1%
DGND
R161
15
29
C142
0.1uf ,16V
C143
0.1uf ,16V
XTALOUT
CRFILT
9
CRFILT
HS_IND
DGND
VSS
PLLFILT
25
PLLFILT
C145
VSS(FLAG)
0.1uf ,10V,DNI
C146
0.1uf ,10V,DNI
DGND
DGND
DGND
Figure 15. USB HUB Design
6.5.1
Processor USB Port
The USB connection to the host is via a mini USB connector. The power from this
connector is connected to the TPS65217B to allow the board to be powered from the
USB Host port. The signal pins connect to the USB HUB.
6.5.2
HUB Power
The HUB is powered from the 3.3VB rail from the TPS65217B. The HUB will remain in
a low power mode until the USB port is connected. The USB2412 monitors the
VBUS_DET pin for logic high when the USB 5V supply is detected.
Page 40 of 92
REF: BBONE_SRM
6.5.3
BeagleBone System Reference
Manual
Rev A6.0.0
Crystal and Reset
The USB2412 uses a single 24MHZ crystal. The RESET signal is self generated from
the VDD_3V3B rail to an RC network.
6.5.4
FT2232H Serial Adapter
The first port of the HUB connected to the FT2232 which handles the processor serial
port and JTAG and is described in the next section. The DP and DM signals from the
USB2412 connect direct to the FT2232H. The FT_BUS signal is used by the FT2232H
to detect the presence of the host USB port. Once the HUB is connected to the Host, this
pin will go HI to indicate the presence of the USB port.
6.5.5
Processor USB Port
The second port of the HUB is connected to the processor USB port 0. In order for the
port to work on the processor it must first detect the presence of 5V on the VBUS pin.
The USB2412 puts out a 3.3V signal on the PRTPWR2 so U16 converts that signal to a
5V logic level as required by the processor.
Page 41 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.6
Rev A6.0.0
FT2232H USB to Serial Adapter
The FT2232H from FTDI provides the conversion from the USB port to the JTAG
interface and Serial port to the processor. Figure 16 is the design of the FT2232H circuit.
VDD_3V3B
2 FB6 VDD_FTVPLL
VDD_3V3B
2 FB7
VDD_FTVPHY
C147 0.1uf ,16V
2 FB8
VDD_FTREGIN
0.1uf ,16V
0.1uf ,16V0.1uf ,16V
U12
VDD_1V8FT
49
VREGIN
VREGOUT
ADBUS0
ADBUS1
ADBUS2
ADBUS3
ADBUS4
ADBUS5
ADBUS6
ADBUS7
DGND
9
9
12.1K,1% FT_REF
R167
6
7
8
FT_DM
FT_DP
XTIN
C153 27pF,50V
DGND
2
REF
USBDM
USBDP
ACBUS0
ACBUS1
ACBUS2
ACBUS3
ACBUS4
ACBUS5
ACBUS6
ACBUS7
OSCIN
Y6
12.000MHz
50ppm
VDD_3V3B
XTOUT
C155 27pF,50V
DGND
R175
R174
R173
U13
6
2
VCC
5
4
3
1
FT_RESETn
2.2K,1%
93LC56B_SOT23-6
DGND
3
14
63
62
61
F_EECS
F_EESK
F_EEDATA
F_EEDOUT
GND
10K,1%
10K,1%
CS
SK
DIN
DOUT
13
BDBUS0
BDBUS1
BDBUS2
BDBUS3
BDBUS4
BDBUS5
BDBUS6
BDBUS7
OSC0
RESET
BCBUS0
BCBUS1
BCBUS2
BCBUS3
BCBUS4
BCBUS5
BCBUS6
BCBUS7
EECS
EECLK
EEDATA
10
GND8
GND7
GND6
GND5
GND4
GND3
GND2
GND1
DGND
AGND
2.2K,1%
1
5
11
15
25
35
47
51
10K,1%
C150
0.1uf ,16V
C151
0.1uf ,16V
DGND
VDD_3V3B
16
17
18
19
21
22
23
24
F_ADBUS0
F_ADBUS1
F_ADBUS2
F_ADBUS3
F_ADBUS4
R164
R165
R166
R168
R169
0,1%
0,1%
0,1%
0,1%
0,1%
F_ADBUS6
R170
0,1%
26
27
28
29
30
32
33
34
F_ADBUS5
38
39
40
41
43
44
45
46
48
52
53
54
55
57
58
59
R172
F_ADBUS7
0,1%
R171
UART0_TX
UART0_RX
UART0_CTS
UART0_RTS
0,1%
4
4
4
4
DGND
VDD_3V3B
R181
10K,1%,DNI
FT_VBUS
9
TEST
PWREN
R188
R187
0.1uf ,16V
C164
50
DGND
C148
20
31
42
56
C163
VCCIOA
VCCIOB
VCCIOB
VCCIOD
C162
12
37
64
4.7uF,6.3V
DGND
VCOREC
VCOREB
VCOREA
C152
0.1uf ,16V
4
9
1
150OHM800mA
1
150OHM800mA
0.1uf ,16V
C158
VPHY
VPLL
1
150OHM800mA
C161
SUSPEND
60
36
FT2232LQFN64
DGND
Figure 16. FT2232H Design
6.6.1
EEPROM
U13 is a EEPROM that tells U12 the configuration of the device and the I/O pins. In
order for the FT2232H to operate properly, this device must be programmed. Using the
tools provided by FTDI makes this process straight forward.
Page 42 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.6.2
Rev A6.0.0
JTAG
Using a parallel I/O mode, the FT2232H can be used to access the JTAG signals on the
processor. At USB 2.0 speeds, the throughput is very good, and should provide
connectivity to several popular debug environments including Code Composer Studio.
On the Rev A6 the reset from the FT2232 has been disabled. This is due to spurious reset
signals being generated by the FT2232 on target connect when using Code Composer
Studio.
6.6.3
Serial Port
Access to UART0 is provided by the FT2232H via the USB port. Signals available are
TX, RX, RTS, and CTS.
6.7
256MB DDR2 Memory
The board comes standard with 256MB DDR SDRAM configured as a single 128M x 16
device. The design will also support a single 64M x 16 device for 128MB of memory.
The memory size cannot be extended past 256MB. The design uses a single
MT47H128M16RT-25E:C 400MHZ memory from Micron which comes in an 84-Ball
9.0mm x 12.5mm FBGA package. Table 4 below is the addressing configuration of the
device.
Table 4.
DDR Addressing
Figure 17 is the functional block diagram of the DDR2 memory device.
Page 43 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
Figure 17. DDR Device Block Diagram
6.7.1
DDR 2 Design
Figure 18 below is the schematic of the DDR implementation. The memory is placed as
close to the processor as possible to minimize layout and signal issues.
3
3
3
3
3
3
3
3
3
3
3
3
3
3
J8
K8
K2
L8
K7
L7
K3
DDR_CLK
DDR_CLKn
DDR_CKE
DDR_CSn
DDR_RASn
DDR_CASn
DDR_WEn
DDR_D[15..0]
DDR_D0
DDR_D1
DDR_D2
DDR_D3
DDR_D4
DDR_D5
DDR_D6
DDR_D7
DDR_D8
DDR_D9
DDR_D10
DDR_D11
DDR_D12
DDR_D13
DDR_D14
DDR_D15
G8
G2
H7
H3
H1
H9
F1
F9
C8
C2
D7
D3
D1
D9
B1
B9
B7
A8
B3
E8
F7
F3
DDR_DQS1
DDR_DQSN1
DDR_DQM1
DDR_DQSN0
DDR_DQS0
DDR_DQM0
A1
E1
M9
R1
J9
VDDS_DDR
E3
P9
J3
N1
A3
R7
R3
E2
A2
DDR_A[13..0]
U6
CK
CKn
CKE
CSn
RASn
CASn
WEn
DQ0
DQ1
DQ2
DQ3
DQ4
DQ5
DQ6
DQ7
DQ8
DQ9
DQ10
DQ11
DQ12
DQ13
DQ14
DQ15
UDQS
UDQSn
UDM
LDQSn
LDQS
LDM
VDD
VDD
VDD
VDD
VDD
VSS
VSS
VSS
VSS
VSS
RFU2
RFU1
NC1
NC2
A0
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
(RFU)A13
BA0
BA1
BA2
ODT
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VDDQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VSSQ
VDDL
VSSDL
VREF
M8
M3
M7
N2
N8
N3
N7
P2
P8
P3
M2
P7
R2
R8
L2
L3
L1
DDR_A0
DDR_A1
DDR_A2
DDR_A3
DDR_A4
DDR_A5
DDR_A6
DDR_A7
DDR_A8
DDR_A9
DDR_A10
DDR_A11
DDR_A12
DDR_A13R 0,1%
DDR_A13
R120
DDR_BA[2..0]
DDR_BA0
DDR_BA1
DDR_BA2
K9
DDR_ODT
A9
C1
C3
C7
C9
E9
G1
G3
G7
G9
VDDS_DDR
H8
B2
D2
F2
H2
A7
E7
B8
D8
F8
J1
VDDS_DDR
J7
J2
DDR_VREF
MT47H128M16RT-25E:C
DDR2 SDRAM
C118
0.01uf ,16V
DGND
DGND
Figure 18. DDR Design
Page 44 of 92
DGND
3
3
3
3
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
The DDR2 connects direct to the processor and no external interface devices are required.
Power is supplied to the DDR2 via the 1.8V rail on the TPS65217B.
6.7.2
DDR VTP Termination Resistor
There is a requirement for a 50 ohm 1% termination resistor, R76, on the DDR interface.
You will notice that the one used on the board design is a 50W wire wound resistor. The
reason for this is cost. This resistor can be expensive and at the time of the design, this
was the least expensive one package available. On the Rev A4 design, we added two
more resistors, R217 and R218, to allow for a 0603 and 0805 package for applications
where space is critical and to give us more options where parts availability is concerned.
6.7.3
User LEDs
Four user LEDS are provided via GPIO pins on the processor. Figure 19 below shows
the LED circuitry.
2
SY S_5V
FB4
150OHM800mA
1
VDD_LED
C100
D4
3
6
6
5
DMC56404
4
Q2B
DMC56404
47k
1
598-8170-107F
R119
100K,1%
DGND
DGND
DGND
DGND
3
3
3
Q2A
47k
R118
100K,1%
DGND
DGND
598-8170-107F
10k
2
DMC56404
10k
Q1B
R117
100K,1%
USR3
3
598-8170-107F
47k
DMC56404
47k
R116
100K,1%
5
Q1A
10k
USR0
10k
3
2
D5
USR2
GRN
598-8170-107F
USR1
GRN
GRN
USR0
R99
470,5%
LEDDC
D3
GRN
LEDAC
R98
470,5%
LEDCC
D2
LEDBC
DGND
R97
470,5%
4
R96
470,5%
1
4.7uF,6.3V
DGND
DGND
USR1
USR2
USR3
Figure 19. User LEDS
Q1 and Q2 provide level shifting from the processor to drive the LEDs that are connected
the SYS_5V rail. FB4 provides noise immunity to the system by the LEDS which can be
a source of noise back into the system rail. Each LED is controlled by setting the
appropriate GPIO bit HI. At power up all LEDs are off. Table 5 is the GPIO USER LED
assignments.
Page 45 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Table 5.
User LED Control
LED
User 0
User 1
User 2
User 3
6.8
Rev A6.0.0
GPIO
GPIO1_21
GPIO1_22
GPIO1_23
GPIO1_24
10/100 Ethernet
The 10/100 Ethernet uses a SMSC LAN8710A Ethernet PHY and interfaces to the
processor using the MII interface. This section covers that design.
6.8.1
Ethernet PHY Design
Figure 20 below is the design of the 10/100 PHY section of the board.
VDD_PHY A
VDD_3V3B
1
150OHM800mA
C119
0.1uf ,16V
2
FB5
DGND
C120
0.1uf ,16V
C121
4.7uF,6.3V
DGND
DGND
C122
0.1uf ,16V
RMII1_TXCLK
RMII1_TXEN
RMII1_TXD0
RMII1_TXD1
RMII1_TXD2
RMII1_TXD3
RMII1_COL
RMII1_CRS_DV
R205
R153
R132
R135
R208
R136
R137
100,1%
100,1%
100,1%
100,1%
100,1%
100,1%
100,1%
R206
100,1%
R207
R139
100,1%
100,1%
RXD3/PHY AD2
RXD2/RMIISEL
RXD1/MODE1
RXD0/MODE0
RXDV
REFCLKO
RXER/PHY AD0
TXCLK
COL/CRS_DV/MODE2
CRS_DV/MODE2
R200 0,1%,DNI
SY S_RESETn
R140
PHY _XTAL1
1M,1%,DNI
PHY _XTAL2
R199
0,1%
20
21
22
23
24
25
15
14
19
5
RCLKIN
4
R144
10,1%
VDDCR
TXP
TXN
RXP
RXN
29
28
TXP
TXN
31
30
RXP
RXN
C126
LED1/REGOFF
LED2/nINTSEL
nINT/TXER/TXD4
RBIAS
QFN32_5X5MM_EP3P3MM
3
2
DGND
PHY X
2
32
RBIAS
R145
12.1K,1%
1
25.000MHz
XTAL2_5X3P2_SMD
C132
DGND
DGND
30pF,50V
DGND
C128
C129
30pF,50V
DGND
Page 46 of 92
DGND
DGND
GRNA
Y ELA
18
Y4
C131
C127
15pF,DNI15pF,DNI15pF,DNI
15pF,DNI
DGND
nRST
XTAL2
49.9,1% R134
DGND
U15
TXCLK
TXEN
LAN8710A
TXD0
TXD1
TXD2
TXD3
COL/CRS_DV/MODE2
CRS
XTAL1/CLKIN
C125
1uF,10V
49.9,1% R130
6
1
27
VDD2A
VDD1A
MDIO
MDC
RXD3/PHY AD2
RXD2/RMIISEL
RXD1/MODE1
RXD0/MODE0
RXDV
RXCLK/PHY AD1
RXER/RXD4/PHY AD0
33
11,3
16
17
8
9
10
11
26
7
13
VDDIO
DGND
GND_EP
4
4
4
4
4
4
4
4
MDIO_DATA
MDIO_CLK
RMII1_RXD3
RMII1_RXD2
RMII1_RXD1
RMII1_RXD0
RMII1_RXDV
RMII1_RXCLK
RMII1_RXERR
10,1%,DNI
12
R131
4
4
4
4
4
4
4
4
4
R209
RMII1_REFCLK
1.5K,5%
4
C124
470pF
50V
5%
C123
0.1uf ,16V
49.9,1% R129
DGND
49.9,1% R133
VDD_PHY A
PHY _VDDCR
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
P11
5
3
6
1
2
4
TXP
TXN
RXP
RXN
R218 470,5%
Y EL_C
R219 470,5%
GRN_C
11
12
10
9
Y ELA
GRNA
TCT
TD+
TDRD+
RDRCT
7
NC
8
GND
13
14
Y ELC SHD1
Y ELA SHD2
GRNC
GRNA
DGND
WE_7499010211A
DGND
R217
ESD_RING
TCT_RCT
C167
VDD_PHY A
R202
0,1%
0.022uF,10V
.1,0805
DGND
DGND
Figure 20. 10/100 Ethernet PHY Design
6.8.2
Processor Signal Description
The Table 6 describes the signals between the processor and the LAN8710A. The BALL
column is the pin number on the processor. The SIGNAL name is the generic name of the
signal on the processor. The PHY column is the pin number of the PHY.
Table 6.
Processor Ethernet Signals
Page 47 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.8.3
Rev A6.0.0
Clocking Mode
The LAN8710A provides the clock to the processor and is generated by the onboard
25MHz crystal Y4. There are independent clocks for the transmit channel (MII
Transmit Clock) and for the receive channel (MII Receive clock).
6.8.4
PHY Mode
The PHY operates in the 10/100 mode with auto negotiation enabled. This is set via the
resistors as described in Figure 21 which are sampled by the PHY when coming out of
reset. It is possible for SW to override this setting if required by setting these bits via the
MDIO channel.
VDD_3V3B
10K,1%,DNI R215
R213
10K,1%,DNI
R124
10K,1% R123
10K,1%,DNI R211
RXD1/MODE1
MODE0 RMISEL PHYAD1 PHYAD0
10K,1%
RXD0/MODE0
10K,1%R122
10K,1%,DNI
R126
PHYAD0 MODE2 MODE1
CRS_DV/MODE2
RXER/PHY AD0
RXD2/RMIISEL
RXD3/PHY AD2
R212
R214
R216
10K,1%
10K,1%
10K,1%
10K,1%,DNI R198
R5
10K,1%,DNI
R127
10K,1%,DNI
10K,1%
R125
nINT/RXCLK/PHY AD1
DGND
Figure 21. 10/100 Ethernet PHY Default Settings
By adding pull up or pull down resistors, the default mode of the PHY can be set via HW.
Seven pairs of resistors are provided on the board to set the mode.
Pins MODE0-1 set the operating mode of the PHY. Default mode is intended to be set by
the populating of R122-124 to 111 enabling all operating modes and auto negotiation.
However, there is an error on that the CRS_DV/MODE2 signal is connected to pin 14 on
Page 48 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
the SMSC PHY. This is incorrect. It should be connected to pin 15. As a result the mode
is 011 which sets it to 100M and no auto negotiate. The SW should overwrite the register
in initial setup, so this should not cause any operational issues. This will be changed on
the next revision of the board assuming something else is required for a change. This
issue is not deemed sufficient to warrant another revision of the board at this time. No
operational issues have been identified as a result of this error.
PHYAD0-2 sets the default address of the PHY. Populating R124-R126 set the default of
0. It is not expected to be set to anything other than this, but the other option was enabled
just in case.
RMIISEL sets the mode to RMII if R211 is installed. MII is the default mode used in
this design, so R212 needs to be installed and R211 is not to be installed.
6.8.5
MDIO Interface
The MDIO interface is the control channel interface between the processor and the
LAN8710A. Via this interface all of the internal PHY registers can be read and set by the
processor and important status information can be read.
6.8.6
PHY Reset
The PHY reset signal is connected to the main board reset and is reset on power up.
6.8.7
Status LEDs
They Ethernet connector has a Yellow and Green LED. The Green LED will be on when
a link is established. It flashes off when data is transferred.
The Yellow status LED will work differently for each revision.
A3...The Yellow LED is OFF when the link is 100M and ON when it is 10M.
A4...The Yellow LED is ON when the link is 100M and OFF when it is 10M.
However, after removing R219 which is required, operation reverts back to the
same as A3.
A5… Yellow LED is OFF when the link is 100M and ON when it is 10M.
A6….. The Yellow LED is ON when the link is 100M and OFF when it is 10M
6.8.8
Power
The PHY is powered via the 3.3VB rail from the TPS65217B. A filter is provided
between the 3.3VB rail and the PHY. The internal LDO is used to power the internal
rails.
Page 49 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.9
Rev A6.0.0
USB Host
A single USB Host port is provided on the board. It is driven by USB port 1 of the
processor. The port can deliver up to 500mA of current provided that much current is
available from the power supply. In the scenario where the board is totally powered from
the USB input, the power supplied will be much less and dependent on how much current
is available after driving the board and any daughter cards that may be attached.
6.9.1
USB Host design
The board has a single USB host connector accessible via P2 a type A female connector.
Figure 22 below is the USB Host design.
P2
USB-A Conn. - 87520-xx1xx
4
4
4
1
VBUS
2 D3 D+
4
GND
USB1_DM
USB1_DP
USB1_ID
SHIELD
SHIELD
5
6
SY S_5V
DGND
U9
2
3
4
1
4 USB1_DRVVBUS
+
R147
C133
10K,1%100uF,6.3V
IN OUT
IN OUT
EN OUT
GND OC
PAD
8
7
6
5
9
USB1_VBUS
VDD_3V3B
R146
0,1%
D+
2
TPS2051 (DGN)
R148
10K,1% DGND
DGND
1
U10
NC
3
ID
GND
DGND
DGND
VBUS
D-
4
6
C134
0.01uf ,16V
5
4
TPD4S012
DGND
USB1_OC
3
DGND
Figure 22. USB Host Design
The USB port on the processor is an OTG port. In order to force the host function
needed, the ID pin, USB_ID, is grounded permanently by R146.
U9, a TPS2051, is the power switch that controls the 5VDC to the USB port. It is turned
on by the processor via USB1_DRVVBUS signal. The USB1_VBUS signal is a
confirmation back to the processor that the switch is activated and that 5V is connected to
the USB Host connector.
In the event of an over current condition, the switch will signal the processor of the event,
via USB1_OC, and the switch will shut down. R148 is a pullup to provide the HI voltage
level because the OC signal on U9 is an open drain pin. C133 provides extra current
when devices are inserted into the connector per the USB specification. The amount of
current the switch can provide is limited by the available current from the main power
source. In order to handle high current devices, you need to power the board from the DC
input connector and not USB. Powering from USB can in, most cases, supply enough
current to run a thumbdrive or low current device.
U10 is an ESD protection device intended to protect the processor.
Page 50 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.10
Rev A6.0.0
SD Connector
The board is populated with a microSD small form factor SD slot. It will support High
capacity cards. The voltage rail for the connector is 3.3VA. A card detector output is
provided from the connector to the CD/EMU4 signal. Figure 23 shows the connections
to the microSD connector.
3
3
3
3
3
3
R194
R193
R192
R191
R195
10K,1%
10K,1%
10K,1%
10K,1%
10K,1%
10K,1%
R190
VDD_3V3
MMC0_DAT2
MMC0_DAT3
MMC0_CMD
MMC0_CLKO
MMC0_DAT0
MMC0_DAT1
C159
10uF,10V
C160
0.1uf ,16V
DGND
1
2
3
4
5
6
7
8
P4
DAT2
GND
CD/DAT3
CD
CMD
GND3
VDD
GND4
CLOCK
GND5
VSS
GND6
DAT0
GND7
DAT1 microSD
GND8
9
10
11
12
13
14
15
16
DGND
SD_CD
R196
10K,1%
VDD_3V3
R197
0,1%
SCHA5B0200
DGND
10,4
uSD Connector
CD/EMU4
Figure 23. SD Connector Design
There are pullup resistors on all the signals to provide additional drive strength and to
increase the rise time of the signals. The SD_CD is the signal that indicates to the
processor that the card is inserted. The signal is a contact point on the connector and
R196 provides the logic hi signal that is grounded whenever there is no card inserted.
When the card is inserted, the signal will go high. R197 is provided as an option to allow
this signal to be removed from the processor for use as the EMU4 signal by the optional
JTAG connector.
The connector is located on the bottom side of the board and the card should be inserted
with the label side up and the contact pins down. This connector is a Push-Push
connector. To insert the card push the card in until it clicks and then release. To remove
the card, push the card in and the connector will release the card and eject the card.
WARNING: DO NOT PULL THE CARD OUT TO
REMOVE IT OR YOU MAY DAMAGE THE
CONNECTOR.
6.11
EEPROM
The BeagleBone is equipped with a single CAT24C256W EEPROM to allow the SW to
identify the board. Table 7 below defined the contents of the EERPOM.
Page 51 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Table 7.
Rev A6.0.0
EEPROM Contents
Name
Size (bytes)
Contents
Header
4
0xAA, 0x55, 0x33, EE
Board Name
8
Name for board in ASCII: A335BONE
Version
4
Hardware version code for board in ASCII:
A3 for Rev A3, 00A4 for Rev A4, 00A5 for Rev A5, 00A6 for Rev A6.
Serial Number
12
Serial number of the board. This is a 12 character string which is:
WWYY4P16nnnn
where: WW = 2 digit week of the year of production
YY = 2 digit year of production
nnnn = incrementing board number
Configuration
Option
32
Codes to show the configuration setup on this board.
0000000000000000000000000000000
RSVD
6
000000
RSVD
6
000000
RSVD
6
000000
Available
32702
Available space for other non-volatile codes/data
Figure 24 is the design of the EEPROM circuit as it is found on the Rev A3, A4, and A5
versions.
VDD_3V3B
2,4
2,4
6
5
I2C0_SCL
I2C0_SDA
1
2
3
U7
SCL
SDA
VCC
VSS
A0
A1
A2
WP
8
C102
0.1uf ,16V
4
7
WP
R210
10K,1%,DNIDGND
CAT24C256W
DGND
32KX8 (256Kb)
Figure 24. EEPROM Design Rev A3,A4, and A5
Figure 25 shows the new design on the Rev A6 where the WP is implemented and a test
point is provided to bypass it.
VDD_3V3B
2,4
2,4
6
5
I2C0_SCL
I2C0_SDA
1
2
3
U7
SCL
SDA
VCC
VSS
A0
A1
A2
WP
8
C102
0.1uf ,16V
4
7
WP
R210 10K,1%
CAT24C256W
DGND
256KX8
TP2
TESTPT1
Page 52 of 92
DGND
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
Figure 25. EEPROM Design Rev A6
The EEPROM is accessed by the processor using the I2C 0 bus. The EEPROM is not
write protected on Revision A3, A4, and A5. R210 is installed on Revision A6 which
invokes the write protection. The WP pin has an internal pulldown on it so that if
removed the pin is grounded. By grounding the test point, the write protection is
removed/
The first 48 locations should not be written to if you choose to use the extras storage
space in the EEPROM for other purposes. If you do, it could prevent the board from
booting properly as the SW uses this information to determine how to set up the board.
6.12
ADC Interface
The processor has 8 ADC (Analog to Digital) converter inputs. The signals are 1.8V only
interfaces. One of these, AD7, is connected to the TPS65217B and used for measuring
voltages and current via the TPS65217B.
6.12.1 ADC Inputs
The primary purpose of the ADC pins was intended for use as a Touchscreen controller
but can be used as a general purpose ADC. Each signal is a 12b successive approximation
register (SAR) ADC. Sample rate is 100K samples per second. There is only one ADC in
the processor and it can be connected to any of the 8 ADC pins.
6.12.2 VDD_ADC Interface
The signal VDD_ADC is provided via the expansion header, but is not a voltage rail that
is to be used to power anything on an expansion board. It is supplied from the 1.8V rail of
the TPS65217B and is run through an inductor for noise isolation. It is there if need for
external circuitry to have access to the VREF rail of the ADC or to add additional
filtering via a capacitor if needed.
Page 53 of 92
REF: BBONE_SRM
6.13
BeagleBone System Reference
Manual
Rev A6.0.0
Expansion Headers
The expansion interface on the board is comprised of two 46 pin connectors. All signals
on the expansion headers are 3.3V unless otherwise indicated.
NOTE: Do not connect 5V logic level signals to these pins or the board will be
damaged.
6.13.1 Expansion Header P8
Table 8 shows the default pinout of the P8 expansion header. Other signals can be
connected to this connector based on setting the pin mux on the processor, but this is the
default settings on power up. The SW is responsible for setting the default function of
each pin.
Table 8.
SIGNAL NAME
Expansion Header P8 Pinout
PROC
CONN
PROC
SIGNAL NAME
GND
1
2
GND
GPIO1_6
R9
3
4
T9
GPIO1_7
GPIO1_2
R8
5
6
T8
GPIO1_3
TIMER4
R7
7
8
T7
TIMER7
TIMER5
T6
9
10
U6
TIMER6
GPIO1_13
R12
11
12
T12
GPIO1_12
EHRPWM2B
T10
13
14
T11
GPIO0_26
GPIO1_15
U13
15
16
V13
GPIO1_14
GPIO0_27
EHRPWM2A
U12
17
18
V12
GPIO2_1
U10
19
20
V9
GPIO1_31
GPIO1_30
U9
21
22
V8
GPIO1_5
GPIO1_4
U8
23
24
V7
GPIO1_1
GPIO1_0
U7
25
26
V6
GPIO1_29
GPIO2_22
U5
27
28
V5
GPIO2_24
GPIO2_23
R5
29
30
R6
GPIO2_25
UART5_CTSN
V4
31
32
T5
UART5_RTSN
UART4_RTSN
V3
33
34
U4
UART3_RTSN
UART4_CTSN
V2
35
36
U3
UART3_CTSN
UART5_TXD
U1
37
38
U2
UART5_RXD
GPIO2_12
T3
39
40
T4
GPIO2_13
GPIO2_10
T1
41
42
T2
GPIO2_11
GPIO2_8
R3
43
44
R4
GPIO2_9
GPIO2_6
R1
45
46
R2
GPIO2_7
Page 54 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
6.13.2 P8 Signal Pin Mux Options
Table 9 shows the other signals that can be connected to each pin of P8 based on the
settings of the registers in the processor for modes 0-3.
Table 9.
PIN
PROC
NAME
P8 Mux Options Modes 0-3
MODE0
MODE1
R9
T9
R8
GND
GPIO1_6
GPIO1_7
GPIO1_2
gpmc_ad6
gpmc_ad7
gpmc_ad2
mmc1_dat6
mmc1_dat7
mmc1_dat2
6
T8
GPIO1_3
gpmc_ad3
mmc1_dat3
7
R7
TIMER4
gpmc_advn_ale
timer4
8
T7
TIMER7
gpmc_oen_ren
timer7
9
T6
TIMER5
gpmc_be0n_cle
timer5
1
GND
2
3
4
5
MODE2
MODE3
10
U6
TIMER6
gpmc_wen
11
R12
GPIO1_13
gpmc_ad13
lcd_data18
mmc1_dat5
timer6
mmc2_dat1
12
T12
GPIO1_12
GPMC_AD12
LCD_DATA19
MMC1_DAT4
MMC2_DAT0
13
T10
EHRPWM2B
gpmc_ad9
lcd_data22
mmc1_dat1
mmc2_dat5
14
T11
GPIO0_26
gpmc_ad10
lcd_data21
mmc1_dat2
mmc2_dat6
15
U13
GPIO1_15
gpmc_ad15
lcd_data16
mmc1_dat7
mmc2_dat3
16
V13
GPIO1_14
gpmc_ad14
lcd_data17
mmc1_dat6
mmc2_dat2
17
U12
GPIO0_27
gpmc_ad11
lcd_data20
mmc1_dat3
mmc2_dat7
18
V12
lcd_memory_clk
gpmc_wait1
mmc2_clk
U10
GPIO2_1
EHRPWM2A
gpmc_clk_mux0
19
gpmc_ad8
lcd_data23
mmc1_dat0
mmc2_dat4
20
V9
GPIO1_31
gpmc_csn2
gpmc_be1n
mmc1_cmd
21
U9
GPIO1_30
gpmc_csn1
gpmc_clk
mmc1_clk
22
V8
GPIO1_5
gpmc_ad5
mmc1_dat3
23
U8
GPIO1_4
gpmc_ad4
mmc1_dat4
24
V7
GPIO1_1
gpmc_ad1
mmc1_dat1
25
U7
GPIO1_0
gpmc_ad0
mmc1_dat0
26
V6
GPIO1_29
gpmc_csn0
27
U5
GPIO2_22
lcd_vsync
gpmc_a8
28
V5
GPIO2_24
lcd_pclk
gpmc_a10
29
R5
GPIO2_23
lcd_hsync
gpmc_a9
30
R6
GPIO2_25
lcd_ac_bias_en
gpmc_a11
31
V4
UART5_CTSN
lcd_data14
gpmc_a18
eQEP1_index
mcasp0_axr1
32
T5
UART5_RTSN
lcd_data15
gpmc_a19
eQEP1_strobe
mcasp0_ahclkx
33
V3
UART4_RTSN
lcd_data13
gpmc_a17
eQEP1B_in
mcasp0_fsr
34
U4
UART3_RTSN
lcd_data11
gpmc_a15
ehrpwm1B
mcasp0_ahclkr
35
V2
UART4_CTSN
lcd_data12
gpmc_a16
eQEP1A_in
mcasp0_aclkr
Page 55 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
PIN
PROC
NAME
MODE0
MODE1
MODE2
MODE3
36
U3
UART3_CTSN
lcd_data10
gpmc_a14
ehrpwm1A
mcasp0_axr0
37
U1
UART5_TXD
lcd_data8
gpmc_a12
ehrpwm1_tripzone_in
mcasp0_aclkx
38
U2
UART5_RXD
lcd_data9
gpmc_a13
ehrpwm0_synco
39
T3
GPIO2_12
lcd_data6
gpmc_a6
eQEP2_index
40
T4
GPIO2_13
lcd_data7
gpmc_a7
eQEP2_strobe
41
T1
GPIO2_10
lcd_data4
gpmc_a4
eQEP2A_in
42
T2
GPIO2_11
lcd_data5
gpmc_a5
eQEP2B_in
43
R3
GPIO2_8
lcd_data2
gpmc_a2
ehrpwm2_tripzone_in
44
R4
GPIO2_9
lcd_data3
gpmc_a3
ehrpwm0_synco
45
R1
GPIO2_6
lcd_data0
gpmc_a0
ehrpwm2A
46
R2
GPIO2_7
lcd_data1
gpmc_a1
ehrpwm2B
mcasp0_fsx
There are some signals that have not been listed here. Refer to the processor
documentation for more information on these pins and detailed descriptions of all of the
pins listed. In some cases there may not be enough signals to complete a group of signals
that may be required to implement a total interface.
The PROC column is the pin number on the processor.
The PIN column is the pin number on the expansion header.
The MODE columns are the mode setting for each pin. Setting each mode to align with
the mode column will give that function on that pin.
Page 56 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
Table 10 shows the other P8 signals for modes 4-7.
Table 10.
PIN
1
PROC
NAME
GND
2
GND
P8 Mux Options Modes 4-7
MODE4
MODE5
MODE6
MODE7
3
R9
GPIO1_6
gpio1[6]
4
T9
GPIO1_7
gpio1[7]
5
R8
GPIO1_2
gpio1[2]
6
T8
GPIO1_3
gpio1[3]
7
R7
TIMER4
gpio2[2]
8
T7
TIMER7
gpio2[3]
9
T6
TIMER5
gpio2[5]
10
U6
TIMER6
gpio2[4]
11
R12
GPIO1_13
eQEP2B_in
gpio1[13]
12
T12
GPIO1_12
EQEP2A_IN
gpio1[12]
13
T10
EHRPWM2B
ehrpwm2B
gpio0[23]
14
T11
GPIO0_26
ehrpwm2_tripzone_in
gpio0[26]
15
U13
GPIO1_15
eQEP2_strobe
gpio1[15]
16
V13
GPIO1_14
eQEP2_index
gpio1[14]
17
U12
GPIO0_27
ehrpwm0_synco
gpio0[27]
18
V12
19
U10
GPIO2_1
EHRPWM2A
20
V9
GPIO1_31
gpio1[31]
21
U9
GPIO1_30
gpio1[30]
22
V8
GPIO1_5
gpio1[5]
23
U8
GPIO1_4
gpio1[4]
24
V7
GPIO1_1
gpio1[1]
25
U7
GPIO1_0
gpio1[0]
26
V6
GPIO1_29
gpio1[29]
27
U5
GPIO2_22
gpio2[22]
28
V5
GPIO2_24
gpio2[24]
29
R5
GPIO2_23
gpio2[23]
30
R6
GPIO2_25
gpio2[25]
31
V4
UART5_CTSN
uart5_rxd
uart5_ctsn
gpio0[10]
32
T5
UART5_RTSN
mcasp0_axr3
uart5_rtsn
gpio0[11]
33
V3
UART4_RTSN
mcasp0_axr3
uart4_rtsn
gpio0[9]
34
U4
UART3_RTSN
mcasp0_axr2
uart3_rtsn
gpio2[17]
35
V2
UART4_CTSN
mcasp0_axr2
uart4_ctsn
gpio0[8]
36
U3
UART3_CTSN
uart3_ctsn
gpio2[16]
37
U1
UART5_TXD
uart2_ctsn
gpio2[14]
mcasp0_fsr
ehrpwm2A
uart5_txd
Page 57 of 92
gpio2[1]
gpio0[22]
REF: BBONE_SRM
BeagleBone System Reference
Manual
MODE5
Rev A6.0.0
PIN
PROC
NAME
MODE4
MODE6
MODE7
38
U2
UART5_RXD
uart5_rxd
uart2_rtsn
gpio2[15]
39
T3
GPIO2_12
40
T4
GPIO2_13
41
T1
GPIO2_10
gpio2[10]
42
T2
GPIO2_11
gpio2[11]
43
R3
GPIO2_8
gpio2[8]
44
R4
GPIO2_9
gpio2[9]
45
R1
GPIO2_6
gpio2[6]
46
R2
GPIO2_7
gpio2[7]
gpio2[12]
pr1_edio_data_out7
gpio2[13]
There are some signals that have not been listed here. Refer to the processor
documentation for more information on these pins and detailed descriptions of all of the
pins listed. In some cases there may not be enough signals to complete a group of signals
that may be required to implement a total interface.
The PROC column is the pin number on the processor.
The PIN column is the pin number on the expansion header.
The MODE columns are the mode setting for each pin. Setting each mode to align with
the mode column will give that function on that pin.
Page 58 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
6.13.3 Expansion Header P9
Table 11 lists the signals on connector P9. Other signals can be connected to this
connector based on setting the pin mux on the processor, but this is the default settings on
power up. Signals highlighted in yellow are changes from the previous revision of the
SRM.
Table 11.
SIGNAL NAME
Expansion Header P9 Pinout
PIN
CONN
PIN
GND
1
2
GND
VDD_3V3EXP
3
4
VDD_3V3EXP
VDD_5V
5
6
VDD_5V
SYS_5V
7
8
SYS_5V
PWR_BUT*
UART4_RXD
T17
UART4_TXD
U17
GPIO1_16
R13
I2C1_SCL
A16
I2C2_SCL
D17
UART2_TXD
B17
GPIO1_17
V14
GPIO3_21
A14
GPIO3_19
C13
SPI1_D0
B13
SPI1_SCLK
A13
AIN4
C8
AIN6
A5
AIN2
B7
AIN0
B6
CLKOUT2
D14
GND
GND
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
10
A10
12
U18
14
U14
16
T14
18
B16
20
D18
22
A17
24
D15
26
D16
28
C12
30
D12
32 VDD_ADC(1.8V)
GNDA_ADC
34
36
A5
38
A7
40
C7
C18
42
43
44
GND
45
46
GND
SIGNAL NAME
SYS_RESETn
GPIO1_28
EHRPWM1A
EHRPWM1B
I2C1_SDA
I2C2_SDA
UART2_RXD
UART1_TXD
UART1_RXD
SPI1_CS0
SPI1_D1
AIN5
AIN3
AIN1
GPIO0_7
*PWR_BUT is a 5V level as pulled up internally by the TPS65217B. It is activated by
pulling the signal to GND.
Page 59 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
6.13.3.1
Rev A6.0.0
Connector P9 Signal Pin Mux Options
Table 12 gives the pin mux options for the signals for connector P9 for modes 0-3.
Table 12.
PIN
PROC
SIGNAL NAME
1
GND
2
GND
3
DC_3.3V
4
DC_3.3V
5
VDD_5V
6
VDD_5V
7
SYS_5V
8
SYS_5V
9
PWR_BUT
P9 Mux Options Modes 0-3
MODE0
MODE1
MODE2
MODE3
10
A10
SYS_RESETn
RESET_OUT
11
T17
UART4_RXD
gpmc_wait0
mii2_crs
gpmc_csn4
rmii2_crs_dv
12
U18
GPIO1_28
gpmc_be1n
mii2_col
gpmc_csn6
mmc2_dat3
13
U17
UART4_TXD
gpmc_wpn
mii2_rxerr
gpmc_csn5
rmii2_rxerr
14
U14
EHRPWM1A
gpmc_a2
mii2_txd3
rgmii2_td3
mmc2_dat1
15
R13
GPIO1_16
gpmc_a0
gmii2_txen
rmii2_tctl
mii2_txen
16
T14
EHRPWM1B
gpmc_a3
mii2_txd2
rgmii2_td2
mmc2_dat2
17
A16
I2C1_SCL
spi0_cs0
mmc2_sdwp
I2C1_SCL
ehrpwm0_synci
18
B16
I2C1_SDA
spi0_d1
mmc1_sdwp
I2C1_SDA
ehrpwm0_tripzone
19
D17
I2C2_SCL
uart1_rtsn
timer5
dcan0_rx
I2C2_SCL
20
D18
I2C2_SDA
uart1_ctsn
timer6
dcan0_tx
I2C2_SDA
21
B17
UART2_TXD
spi0_d0
uart2_txd
I2C2_SCL
ehrpwm0B
22
A17
UART2_RXD
spi0_sclk
uart2_rxd
I2C2_SDA
ehrpwm0A
23
V14
GPIO1_17
gpmc_a1
gmii2_rxdv
rgmii2_rxdv
mmc2_dat0
24
D15
UART1_TXD
uart1_txd
mmc2_sdwp
dcan1_rx
I2C1_SCL
25
A14
GPIO3_21
mcasp0_ahclkx
eQEP0_strobe
mcasp0_axr3
mcasp1_axr1
26
D16
UART1_RXD
uart1_rxd
mmc1_sdwp
dcan1_tx
I2C1_SDA
27
C13
GPIO3_19
mcasp0_fsr
eQEP0B_in
mcasp0_axr3
mcasp1_fsx
28
C12
SPI1_CS0
mcasp0_ahclkr
ehrpwm0_synci
mcasp0_axr2
spi1_cs0
29
B13
SPI1_D0
mcasp0_fsx
ehrpwm0B
30
D12
SPI1_D1
mcasp0_axr0
ehrpwm0_tripzone
spi1_d1
31
A13
SPI1_SCLK
mcasp0_aclkx
ehrpwm0A
spi1_sclk
32
33
VADC
C8
AIN4
AGND
A8
AIN6
34
35
Page 60 of 92
spi1_d0
REF: BBONE_SRM
BeagleBone System Reference
Manual
PIN
PROC
SIGNAL
NAME
36
B8
AIN5
37
B7
AIN2
38
A7
AIN3
39
B6
AIN0
40
C7
AIN1
41
D14
CLKOUT2
xdma_event_intr1
GPIO0_7
eCAP0_in_PWM0_
out
42
C18
43
GND
44
GND
45
GND
46
GND
MODE0
MODE1
uart3_txd
MODE2
Rev A6.0.0
MODE3
tclkin
clkout2
spi1_cs1
pr1_ecap0_ecap_cap
in_apwm_o
There are some signals that have not been listed here. Refer to the processor
documentation for more information on these pins and detailed descriptions of all of the
pins listed. In some cases there may not be enough signals to complete a group of signals
that may be required to implement a total interface.
The PROC column is the pin number on the processor.
The PIN column is the pin number on the expansion header.
The MODE columns are the mode setting for each pin. Setting each mode to align with
the mode column will give that function on that pin.
Page 61 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
Table 13 gives the pin mux options for the signals for connector P9 for modes 4-7.
Table 13.
PIN
PROC
1
SIGNAL NAME
GND
2
GND
3
DC_3.3V
4
DC_3.3V
5
VDD_5V
6
VDD_5V
7
SYS_5V
8
SYS_5V
9
P9 Mux Options Modes 4-7
MODE4
MODE5
MODE6
MODE7
PWR_BUT
10
A10
SYS_RESETn
11
T17
UART4_RXD
mmc1_sdcd
uart4_rxd_mux2
gpio0[30]
12
U18
GPIO1_28
gpmc_dir
mcasp0_aclkr_mux3
gpio1[28]
13
U17
UART4_TXD
mmc2_sdcd
uart4_txd_mux2
gpio0[31]
14
U14
EHRPWM1A
gpmc_a18
ehrpwm1A_mux1
gpio1[18]
15
R13
GPIO1_16
gpmc_a16
ehrpwm1_tripzone_input
gpio1[16]
16
T14
EHRPWM1B
gpmc_a19
ehrpwm1B_mux1
gpio1[19]
17
A16
I2C1_SCL
gpio0[5]
18
B16
I2C1_SDA
gpio0[4]
19
D17
I2C2_SCL
spi1_cs1
gpio0[13]
20
D18
I2C2_SDA
spi1_cs0
gpio0[12]
21
B17
UART2_TXD
EMU3_mux1
gpio0[3]
22
A17
UART2_RXD
EMU2_mux1
gpio0[2]
23
V14
GPIO1_17
ehrpwm0_synco
gpio1[17]
24
D15
UART1_TXD
gpmc_a17
gpio0[15]
25
A14
GPIO3_21
26
D16
UART1_RXD
27
C13
GPIO3_19
EMU2_mux2
gpio3[19]
28
C12
SPI1_CS0
eCAP2_in_PWM2_out
gpio3[17]
29
B13
SPI1_D0
mmc1_sdcd_mux1
gpio3[15]
30
D12
SPI1_D1
mmc2_sdcd_mux1
gpio3[16]
31
A13
SPI1_SCLK
mmc0_sdcd_mux1
gpio3[14]
32
33
C8
AIN4
GNDA_ADC
A5
AIN6
gpio3[21]
gpio0[14]
VDD_ADC (1.8V_
34
35
EMU4_mux2
Page 62 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
PIN
PROC
SIGNAL NAME
36
A5
AIN5
37
B7
AIN2
38
A7
AIN3
39
B6
AIN0
40
C7
AIN1
41
D14
CLKOUT2
timer7_mux1
42
C18
GPIO0_7
spi1_sclk
43
GND
44
GND
45
GND
46
GND
MODE4
MODE5
mmc0_sdwp
MODE6
MODE7
EMU3_mux0
gpio0[20]
xdma_event_intr2
gpio0_7
Rev A6.0.0
There are some signals that have not been listed here. Refer to the processor
documentation for more information on these pins and detailed descriptions of all of the
pins listed. In some cases there may not be enough signals to complete a group of signals
that may be required to implement a total interface.
The PROC column is the pin number on the processor.
The PIN column is the pin number on the expansion header.
The MODE columns are the mode setting for each pin. Setting each mode to align with
the mode column will give that function on that pin.
Page 63 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
6.13.4 PMIC Expansion Header
There is an additional connector that brings out some additional signals from the
TPS65217B power management chip. Figure 25 shows the PMIC expansion connector.
P6
BAT
BAT_TEMP
BL_ISET1
BL_IN
BL_SINK2
2
4
6
8
10
1
3
5
7
9
BAT
BAT_SENSE
BL_ISET2
BL_OUT
BL_SINK1
HDR5x2
Figure 26. PMIC Expansion Header
6.13.5 Backlight Interface
The most useful interface provided is the backlight interface which is very useful for
powering the backlight of LCD panels. The Backlight circuit is a boost converter and two
current sinks capable of driving up to 2x10 LEDs at 25mA or a single string at 50mA of
current. Two current levels can be programmed using two external resistors and
brightness dimming is supported by an internal PWM signal under I2C control. Both
current sources are controlled together and cannot operate independently. The boost
output voltage is internally limited to 39V. LED current is selected through the ISEL bit
of the same register as is the PWM frequency. By default, the PWM frequency is set to
200Hz but can be changed to 100Hz, 500Hz, and 1000Hz. The PWM duty cycle can be
adjusted from 1% to 100% in 1% steps through the WLEDCTRL2 register. If only a
single WLED string is required, short both ISINK pins together and connect them to the
Cathode of the diode string. Note that the LED current in this case is doubled and to
compensate, the RSET resistors must be doubled as well. Figure 26 below shows the two
different circuits.
Figure 27. Backlight Circuitry
For more information on working with this interface, refer to the TPS65217B datasheet.
Page 64 of 92
REF: BBONE_SRM
BeagleBone System Reference
Manual
Rev A6.0.0
6.13.6 Battery Interface
There is also a battery charger interface. This interface can be used by anyone wanting to
experiment with batteries and battery charging. However, as a source for powering the
BeagleBone, this interface is not practical as there is no way to provide the 5V on the
board required for the USB host port. The reason for this is that the maximum battery
voltage is 3.7V, well short of 5V. The LDOs on the TPS65217B are 200mv, meaning
that the 3.7V battery LDOS can supply the needed 3.3V after the battery starts
discharging as long as it does not go below 3.5V, including any voltage drop for the
connections that may occur. If you are OK with not having a USB host function, then it is
possible to use the battery charger for the purpose of a battery powered system. If you
have an LCD, then most of the LCD Capes do require 5V as well to operate. This limits
the application for battery power as the BeagleBone is currently designed. There are no
plans to add an extra switcher on the BeagleBone to boost the 3.7V to 5V for this issue.
Figure 27 shows the battery circuitry inside the TPS65217B.
Figure 28. Battery Circuitry
Page 65 of 92
REF: BBONE_SRM
7.0
BeagleBone System Reference
Manual
Rev A6.0.0
Cape Board Support
The BeagleBone has the ability to accept up to four expansion boards or Capes that can
be stacked onto the expansion headers. The word Cape comes from the shape of the
board as it is fitted around the Ethernet connector on the main board. This notch acts as a
key to insure proper orientation of the Cape.
This section describes the rules for creating Capes to insure proper operation with the
BeagleBone and proper interoperability with other Capes that are intended to co-exist
with each other. Co-existence is not a requirement and is in itself, something that is
impossible to control or administer. But, people will be able to create Capes that operate
with Capes that are already available based on public information as it pertains to what
pins and features each Cape uses. This information will be able to be read from the
EEPROM on each Cape.
This section is intended as a guideline for those wanting to create their own Capes. Its
intent is not to put limits on the creation of Capes and what they can do, but to set a few
basic rules that will allow the SW to administer their operation with the BeagleBone. For
this reason there is a lot of flexibility in the specification that we hope most people will
find liberating and in the spirit of Open Source Hardware. I am sure there are others that
would like to see tighter control, more details, more rules and much more order to the
way Capes are handled.
Over time, this specification will change and be updated, so please refer to the latest
version of this manual prior to designing your own Capes to get the latest information.
7.1
EEPROM
Each Cape must have its own EEPROM containing information that will allow the SW to
identify the board and to configure the expansion headers pins as needed. The one
exception is proto boards intended for prototyping. They may or may not have an
EEPROM on them. EEPROMs are required for all Capes sold in order for them operate
correctly when plugged into the BeagleBone.
The address of the EEPROM will be set via either jumpers or a dipswitch on each
expansion board. Figure 28 below is the design of the EEPROM circuit.
The EEPROM used is the same one as is used on the BeagleBone, a CAT24C256. The
CAT24C256 is a 256 kb Serial CMOS EEPROM, internally organized as 32,768 words
of 8 bits each. It features a 64−byte page write buffer and supports the Standard (100
kHz), Fast (400 kHz) and Fast−Plus (1 MHz) I2C protocol.
Page 66 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
R142
R138
R128
6
5
SCL
SDA
SW1
SW1_A0
SW1_A1
SW1_A3
SW DIP-2
VCC
VSS
1
2
3
A0
A1
A2
WP
8
4
2
I2C2_SCL
I2C2_SDA
VDD_3V3
U18
1
2,4,6
2,4,6
4.75K
4.75K
4.75K
5.6K,5%
5.6K,5%
R220
R221
VDD_3V3
C130
0.1uF
7
DGND
CAT24C256W
DGND
Figure 29. Expansion Board EEPROM No Write Protect
The addressing of this device requires two bytes for the address which is not used on
smaller size EEPROMs, which only require one byte. Other compatible devices may be
used as well. Make sure the device you select supports 16 bit addressing. The part
package used is at the discretion of the Cape designer.
7.1.1
EEPROM Address
In order for each Cape to have a unique address, a board ID scheme is used that sets the
address to be different depending on the setting of the dipswitch or jumpers on the Capes.
A two position dipswitch or jumpers is used to set the address pins of the EEPROM.
It is the responsibility of the user to set the proper address for each board and the position
in the stack that the board occupies has nothing to do with which board gets first choice
on the usage of the expansion bus signals. The process for making that determination and
resolving conflicts is left up to the SW and as of this moment in time, this method is a
complete mystery.
Address line A2 is always tied high. This sets the allowable address range for the
expansion cards to 0x54 to 0x57. All other I2C addresses can be used by the user in the
design of their Capes. But, these addresses must not be used other than for the board
EEPROM information. This also allows for the inclusion of EEPROM devices on the
Cape if needed without interfering with this EEPROM. It requires that A2 be grounded
on the EEPROM not used for Cape identification.
7.1.2
I2C Bus
The EEPROMs on each expansion board is connected to I2C2 on connector P9 pins 19
and 20. For this reason I2C2 must always be left connected and should not be changed by
Page 67 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Rev A6.0.0
SW to remove it from the expansion header pin mux settings. If this is done, then the
system will be unable to detect the Capes.
The I2C signals require pullup resistors. Each board must have a 5.6K resistor on these
signals. With four Capes installed this will be an affective resistance of 1.4K if all Capes
were installed. As more Capes are added the resistance is increased to overcome
capacitance added to the signals. When no Capes are installed the internal pullup resistors
must be activated inside the processor to prevent I2C timeouts on the I2C bus.
The I2C2 bus may also be used by Capes for other functions such as I/O expansion or
other I2C compatible devices that do not share the same address as the Cape EEPROM.
7.1.3
EEPROM Write Protect
The design in Figure 28 has the write protect disabled. If the write protect is not enabled,
this does expose the EEPROM to being corrupted if the I2C2 bus is used on the Cape and
the wrong address written to. It is recommended that a write protection function be
implemented and a Test Point be added that when grounded, will allow the EEPROM to
be written to. Figure 29 shows the implementation of the EEPROM with write protect
bypass enabled. Whether or not Write Protect is provided is at the discretion of the Cape
designer.
Variable & MAC Memory
2,4
2,4
6
5
I2C0_SCL
I2C0_SDA
1
2
3
U7
SCL
SDA
VCC
VSS
A0
A1
A2
WP
VDD_3V3B
8
C102
0.1uf ,16V
4
7
WP
R210 10K,1%
DGND
CAT24C256W
DGND
256KX8
TP2
TESTPT1
Figure 30. Expansion Board EEPROM Write Protect
Page 68 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
7.1.4
Rev A6.0.0
EEPROM Data Format
Table 14 below shows the format of the contents of the expansion board EEPROM. Data
is stored in Big Endian with the least significant value on the right. All addresses read
single byte data from the EEPROM but are two byte addresses ASCII values are intended
to be easily read by the use when the EEPROM contents are dumped.
Table 14.
Name
Expansion Board EEPROM
Offset
Size
(bytes)
Contents
Header
0
4
0xAA, 0x55, 0x33, 0xEE
EEPROM Revision
4
2
Revision number of the overall format of this EEPROM in ASCII =A1
Board Name
6
32
Name of board in ASCII so user can read it when the EEPROM is dumped. Up to
developer of the board as to what they call the board..
Version
38
4
Hardware version code for board in ASCII. Version format is up to the developer.
i.e. 02.1…00A1....10A0
Manufacturer
42
16
ASCII name of the manufacturer. Company or individual’s name.
Part Number
60
16
ASCII Characters for the part number. Up to maker of the board.
Number of Pins
74
2
Number of pins used by the daughter board including the power pins used.
Decimal value of total pins 92 max, stored in HEX.
Serial number of the board. This is a 12 character string which is:
WWYY&&&&nnnn
where: WW = 2 digit week of the year of production
Serial Number
76
12
YY = 2 digit year of production
&&&&=Assembly code to let the manufacturer document the assembly number
or product. A way to quickly tell from reading the serial number what the board
is. Up to the developer to determine.
nnnn = incrementing board number for that week of production
Two bytes for each configurable pins of the 74 pins on the expansion
connectors
MSB
LSB
Bit order: 15 14 ……………1..0
Bit 15…………..Pin is used or not………...0=Unused by Cape 1=Used by Cape
Bit 14-13………Pin Direction…………..….1 0=Output 01=Input 11=BDIR
Bits 12-7………Reserved
Bit 6……….….Slew Rate …………………..0=Fast 1=Slow
Bit 5…….…….Rx Enable…………………..0=Disabled 1=Enabled
Bit 4……….….Pull Up/Dn Select…………..0=Pulldown 1=PullUp
Bit 3…………..Pull Up/DN enabled………..0=Enabled 1=Disabled
Bits 2-0 ………Mux Mode Selection………..Mode 0-7
Pin Usage
88
148
VDD_3V3EXP Current
236
2
Maximum current in milliamps. This is HEX value of the current in decimal
1500mA=0x05 0xDC 325mA=0x01 0x45
VDD_5V Current
238
2
Maximum current in milliamps. This is HEX value of the current in decimal
1500mA=0x05 0xDC 325mA=0x01 0x45
SYS_5V Current
240
2
Maximum current in milliamps. This is HEX value of the current in decimal
1500mA=0x05 0xDC 325mA=0x01 0x45
DC Supplied
242
2
Available
244
32543
Indicates whether or not the board is supplying voltage on the VDD_5V rail and
the current rating 000=No 1-0xFFFF is the current supplied storing the decimal
equivalent in HEX format
Available space for other non-volatile codes/data to be used as needed by
the manufacturer or SW driver. Could also store presets for use by SW.
Page 69 of 92
REF: BBONE_SRM
7.1.5
BeagleBone System Reference
Manual
Rev A6.0.0
Pin Usage
Table 15 is the locations in the EEPROM to set the I/O pin usage for the Cape. It
contains the value to be written to the Pad Control Registers. Details on this can be found
in section 9.2.2 of the AM335x Technical Reference Manual, The table is left blank as
a convenience and can be printed out and used as a template for creating a custom setting
for each Cape. The 16 bit integers and all 16 bit fields are to be stored in Big Endian.
format.
Bit 15
unused.
Bits 14-7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2-0
PIN USAGE is an indicator and should be a 1 if the pin is used or 0 if it is
RSERVED is not to be used and left as 0.
SLEW CONTROL 0=Fast 1=Slow
RX Enabled 0=Disabled 1=Enabled
PU/PD 0=Pulldown 1=Pullup.
PULLUP/DN 0=Pullup/pulldown enabled 1= Pullup/pulldown disabled
MUX MODE SELECT Mode 0-7. (refer to TRM)
Refer to the TRM for proper settings of the pin MUX mode based on the signal selection
to be used.
The AIN0-6 pins do not have a pin mux setting, but they need to be set to indicate if each
of the pins is used on the Cape. Only bit 15 is used for the AIN signals..
Page 70 of 92
BeagleBone System Reference
Manual
REF: BBONE_SRM
Table 15.
15
Off
set
Conn
Name
88
P9-22
UART2_RXD
90
P9-21
UART2_TXD
92
P9-18
I2C1_SDA
94
P9-17
I2C1_SCL
96
P9-42
GPIO0_7
98
P8-35
UART4_CTSN
100
P8-33
UART4_RTSN
102
P8-31
UART5_CTSN
104
P8-32
UART5_RTSN
106
P9-19
I2C2_SCL
108
P9-20
I2C2_SDA
110
P9-26
UART1_RXD
112
P9-24
UART1_TXD
114
P9-41
CLKOUT2
116
P8-19
EHRPWM2A
118
P8-13
EHRPWM2B
120
P8-14
GPIO0_26
122
P8-17
GPIO0_27
124
P9-11
UART4_RXD
126
P9-13
UART4_TXD
128
P8-25
GPIO1_0
130
P8-24
GPIO1_1
132
P8-5
GPIO1_2
134
P8-6
GPIO1_3
136
P8-23
GPIO1_4
138
P8-22
GPIO1_5
140
P8-3
GPIO1_6
142
P8-4
GPIO1_7
P8-12
GPIO1_12
146
P8-11
GPIO1_13
148
P8-16
GPIO1_14
150
P8-15
GPIO1_15
152
P9-15
GPIO1_16
144
Pin
Usage
EEPROM Pin Usage
14 13
Type
Rev A6.0.0
12
11 10
9
8 7 6 5 4 3
Reserved
P
P
S
U
U
L R
/
E X
D
P
W
E
D
N
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2
1
0
Mux Mode
BeagleBone System Reference
Manual
REF: BBONE_SRM
15
Off
set
Conn
Name
154
P9-23
GPIO1_17
156
P9-14
EHRPWM1A
158
P9-16
EHRPWM1B
160
P9-12
GPIO1_28
162
P8-26
GPIO1_29
164
P8-21
GPIO1_30
166
P8-20
GPIO1_31
168
P8-18
GPIO2_1
170
P8-7
TIMER4
172
P8-9
TIMER5
174
P8-10
TIMER6
176
P8-8
TIMER7
178
P8-45
GPIO2_6
180
P8-46
GPIO2_7
182
P8-43
GPIO2_8
184
P8-44
GPIO2_9
186
P8-41
GPIO2_10
188
P8-42
GPIO2_11
190
P8-39
GPIO2_12
192
P8-40
GPIO2_13
194
P8-37
UART5_TXD
196
P8-38
UART5_RXD
198
P8-36
UART3_CTSN
200
P8-34
UART3_RTSN
202
P8-27
GPIO2_22
204
P8-29
GPIO2_23
206
P8-28
GPIO2_24
208
P8-30
GPIO2_25
210
P9-29
SPI1_D0
212
P9-30
SPI1_D1
214
P9-28
SPI1_CS0
216
P9-27
GPIO3_19
218
P9-31
SPI1_SCLK
220
P9-25
GPIO3_21
Pin
Usage
14 13
Type
12
11 10
9
8 7 6 5 4 3
Reserved
P
P
S
U
U
L R
/
E X
D
P
W
E
D
N
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15
Off
set
Conn
Name
Pin
Usage
14 13
Type
0
222
P8-39
AIN0
224
P8-40
AIN1
226
P8-37
AIN2
228
P8-38
AIN3
230
P9-33
AIN4
232
P8-36
AIN5
234
P9-35
AIN6
12
0
0
11 10
9
8 7 6 5 4 3
Reserved
P
P
S
U
U
L R
/
E X
D
P
W
E
D
N
0
0
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0
0
0 0
0 0
0
Rev A6.0.0
2
1
0
Mux Mode
0
0
0
BeagleBone System Reference
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REF: BBONE_SRM
7.2
Rev A6.0.0
Pin Usage Consideration
This section covers things to watch for when hooking up to certain pins on the expansion
headers.
7.2.1
Boot Pins
There are 16 pins that control the boot mode of the processor that are exposed on the
expansion headers. Figure 31 below shows those signals:
R94
R95
100K,1%
SYS_BOOT0
SYS_BOOT1
SYS_BOOT2
SYS_BOOT3
SYS_BOOT4
SYS_BOOT5
SYS_BOOT6
SYS_BOOT7
SYS_BOOT8
SYS_BOOT9
SYS_BOOT10
SYS_BOOT11
SYS_BOOT12
SYS_BOOT13
SYS_BOOT14
SYS_BOOT15
GPIO2_6
GPIO2_7
GPIO2_8
GPIO2_9
GPIO2_10
GPIO2_11
GPIO2_12
GPIO2_13
UART5_TXD
UART5_RXD
UART3_CTSN
UART3_RTSN
UART4_CTSN
UART4_RTSN
UART5_CTSN
UART5_RTSN
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
11,4
Boot Configuration
100K,1%,DNI
42.2K,1%
R115
R93
100K,1%,DNI
R113
42.2K,1%,DNI R114
42.2K,1%
R92
100K,1%,DNI
R112
42.2K,1%
R91
100K,1%,DNI
R111
R90
42.2K,1%
R89
100K,1%,DNI
R110
42.2K,1%
100K,1%,DNI
R109
42.2K,1%
R88
100K,1%,DNI
R108
42.2K,1%
R87
100K,1%,DNI
R107
R86
42.2K,1%
R85
100K,1%,DNI
R106
100K,1%,DNI
R105
42.2K,1%
R84
100K,1%
42.2K,1%
R83
100K,1%,DNI
42.2K,1%
42.2K,1%,DNI R104
R82
100K,1%
R103
R81
100K,1%
42.2K,1%,DNI R102
42.2K,1%,DNI R101
R80
42.2K,1%,DNI R100
100K,1%
VDD_3V3A
DGND
Figure 31. Expansion Boot Pins
If you plan to use any of these signals, then on power up, these pins should not be driven.
If you do, it can affect the boot mode of the processor and could keep the processor from
booting or working correctly.
If you are designing a Cape that is intended to be used as a boot source, such as a NAND
board, then you should drive the pins to reconfigure the boot mode, but only at reset.
After the reset phase, the signals should not be driven to allow them to be used for the
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other functions found on those pins. You will need to override the resistor values in order
to change the settings. The DC pull-up requirement should be based on the AM335x Vih
min voltage 2 volts and AM335x maximum input leakage current of 18uA when plus any
other current leakage paths on these signals which you would be providing on your Cape
design. .
The DC pull-down requirement should be based on the AM335x Vil max voltage of 0.8
volts and AM335x maximum input leakage current of 18uA plus any other current
leakage paths on these signals.
7.3
Expansion Connectors
A combination of male and female headers is used for access to the expansion headers on
the main board. There are three possible mounting configurations for the expansion
headers:



Single-no board stacking but can be used on the top of the stack.
Stacking-up to four boards can be stacked on top of each other.
Stacking with signal stealing-up to three boards can be stacked on top of each
other, but certain boards will not pass on the signals they are using to prevent
signal loading or use by other cards in the stack.
The following sections describe how the connectors are to be implemented and used for
each of the different configurations.
NOTE: Be careful if you are considering using standoffs on the BeagleBone Rev A3
A4 or A5. The mounting hole next to the DC power jack has resistors that are a little
too close to the hole and if you are not careful, you can damage those resistors when
attaching the standoff. Use as small a diameter standoff as possible This issue has been
resolved on the Rev A6 version Typically the retention force of the expansion headers
is enough to secure the boards and standoffs are not needed..
7.3.1
Non-Stacking Headers-Single Cape
For non-stacking Capes single configurations or where the Cape can be the last board on
the stack, the two 46 pin expansion headers use the same connectors. Figure 29 is a
picture of the connector. These are dual row 23 position 2.54mm x 2.54mm connectors.
Figure 32. Single Expansion Connector
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The connector is typically mounted on the bottom side of the board as shown in Figure
30. These are very common connectors and should be easily located. You can also use
two single row 23 pin headers for each of the dual row headers.
Figure 33. Single Cape Expansion Connector
It is allowed to only populate the pins you need. As this is a non-stacking configuration,
there is no need for all headers to be populated. This can also reduce the overall cost of
the Cape. This decision is up to the Cape designer.
For convenience listed in Table 15 are some possible choices for part numbers on this
connector. They have varying pin lengths and some may be more suitable than others for
your use. It should be noted, that the longer the pin and the further it is inserted into the
BeagleBone connector, the harder it will be to remove due to the tension on 92 pins. This
can be minimized by using shorter pins or removing those pins that are not used by your
particular design. The first item in Table 15 is on the edge and may not be the best
solution. Overhang is the amount of the pin that goes past the contact point of the
connector on the BeagleBone.
Refer to Section 8.3 for more information on the connectors and the insertion force issue.
Table 16.
SUPPLIER
Major League
Major League
Major League
Single Cape Connectors
PARTNUMBER
TAIL LENGTH(in)
OVERHANG(in)
.145
.240
.255
.004
.099
.114
TSHC-123-D-03-145-GT-LF
TSHC-123-D-03-240-GT-LF
TSHC-123-D-03-255-GT-LF
The GT in the part number is a plating option. Other options may be used as well as long
as the contact area is gold. Other possible sources are Sullins and Samtec for these
connectors. You will need to insure the depth into the connector is sufficient
7.3.2
Battery Connector- Single
For non-stacking or single configuration this connector is a single 10 pin expansion
header. Figure 31 is a picture of the connector. This is a dual row 10 position 2.54mm x
2.54mm connectors. This is the same connector as the main connectors, only shorter.
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Figure 34. Battery/Backlight Expansion Connector
Table 18 below is the possible part numbers for this connector. The first item in Table
17 is on the edge and may not be the best solution. Overhang is the amount of the pin that
goes past the contact point of the connector on the BeagleBone.
Refer to Section 8.3 for more information on the connectors and the insertion force issue.
Table 17.
SUPPLIER
Major League
Major League
Major League
7.3.3
Single Cape Backlight Connectors
PARTNUMBER
TAIL LENGTH(in)
OVERHANG(in)
.145
.240
.255
.004
.099
.114
TSHC-105-D-03-145-GT-LF
TSHC-105-D-03-240-GT-LF
TSHC-105-D-03-255-GT-LF
Main Expansion Headers-Stacking
For stacking configuration, the two 46 pin expansion headers use the same connectors.
Figure 32 is a picture of the connector. These are dual row 23 position 2.54mm x
2.54mm connectors.
Figure 35. Expansion Connector
The connector is mounted on the top side of the board with longer tails to allow insertion
into the BeagleBone. Figure 33 is the connector configuration for the connector.
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Figure 36. Stacked Cape Expansion Connector
For convenience listed in Table 17 are some possible choices for part numbers on this
connector. They have varying pin lengths and some may be more suitable than others for
your use. It should be noted, that the longer the pin and the further it is inserted into the
BeagleBone connector, the harder it will be to remove due to the tension on 92 pins. This
can be minimized by using shorter pins. There are most likely other suppliers out there
that will work for this connector as well. If anyone finds other suppliers of compatible
connectors that work, let us know and they will be added to this document. The first item
in Table 18 is on the edge and may not be the best solution. Overhang is the amount of
the pin that goes past the contact point of the connector on the BeagleBone.
Please refer to Section 8.3 for more information on the connectors and the insertion force
issue. The third part listed in Table 18 will have insertion force issues.
Table 18.
Stacked Cape Connectors
SUPPLIER
PARTNUMBER
TAIL LENGTH(in)
OVERHANG(mm)
Major League
Major League
Major League
SSHQ-123-D-06-GT-LF
SSHQ-123-D-08-GT-LF
SSHQ-123-D-10-GT-LF
.190
.390
.560
0.049
0.249
0.419
There are also different plating options on each of the connectors above. Gold plating on
the contacts is the minimum requirement. If you choose to use a different part number for
plating or availability purposes, make sure you do not select the “LT” option.
Other possible sources are Sullins and Samtec but make sure you select one that has the
correct mating depth.
7.3.4
Battery Connector Stacking
This connector is a single two 10 pin expansion header. Figure 34 is a picture of the
connector. This is a dual row 10 position 2.54mm x 2.54mm connector and is the same as
the main connector except with less positions.
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Figure 37. Stacked Battery Expansion Connector
For convenience listed in Table 18 are some possible choices for part numbers on this
connector. They have varying pin lengths and some may be more suitable than others for
your use. . The first item in Table 19 is on the edge and may not be the best solution.
Overhang is the amount of the pin that goes past the contact point of the connector on the
BeagleBone.
Please refer to Section 8.3 for more information on the connectors and the insertion force
issue. The third part listed in Table 19 will have insertion force issues.
Table 19.
Stacked Cape Connectors
SUPPLIER
PARTNUMBER
TAIL LENGTH
OVER HANG
Major League
Major League
Major League
SSHQ-105-D-06-GT-LF
SSHQ-105-D-08-GT-LF
SSHQ-105-D-10-GT-LF
.190
.390
.560
0.049
0.249
0.419
Tail length does not include the thickness of the Cape PCB.
7.3.5
Stacked Capes w/Signal Stealing
Figure 35 is the connector configuration for stackable Capes that does not provide all of
the signals upwards for use by other boards. This is useful if there is an expectation that
other boards could interfere with the operation of your board by exposing those signals
for expansion. This configuration consists of a combination of the stacking and nonstacking style connectors.
Figure 38. Stacked w/Signal Stealing Expansion Connector
7.3.6
Retention Force
The length of the pins on the expansion header has a direct relationship to the amount of
force that is used to remove a Cape from the BeagleBone. The longer the pins extend into
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Rev A6.0.0
the connector the harder it is to remove. There is no rule that says that if longer pins are
used, that the connector pins have to extend all the way into the mating connector on the
BeagleBone, but this is controlled by the user and therefore is hard to control.
This section will attempt to describe the tradeoffs and things to consider when selecting a
connector and its pin length.
7.3.7
BeagleBone Female Connectors
Figure 36 below shows the key measurements used in calculating how much the pin
extends past the contact point on the connector, what we call overhang.
Figure 39. Connector Pin Insertion Depth
To calculate the amount of the pin that extends past the Point of Contact, use the
following formula:
Overhang=Total Pin Length- PCB thickness (.062) - contact point (.079)
The longer the pin extends past the contact point, the more force it will take to insert and
remove the board. Removal is a greater issue than the insertion.
7.4
Signal Usage
Based on the pin muxing capabilities of the processor, each expansion pin can be
configured for different functions. When in the stacking mode, it will be up to the user to
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insure that any conflicts are resolved between multiple stacked cards. When stacked, the
first card detected will be used to set the pin muxing of each pin. This will prevent other
modes from being supported on stacked cards and may result in them being inoperative.
In Section 7.12 of this document, the functions of the pins are defined as well as the pin
muxing options. Refer to this section for more information on what each pin is. To
simplify things, if you use the default name as the function for each pin and use those
functions, it will simplify board design and reduce conflicts with other boards.
Interoperability is up to the board suppliers and the user. This specification does not
specify a fixed function on any pin and any pin can be used to the full extent of the
functionality of that pin as enabled by the processor.
7.5
Cape Power
This section describes the power rails for the Capes and their usage.
7.5.1
Main Board Power
The Table 19 describes the voltages from the main board that are available on the
expansion connectors and their ratings. All voltages are supplied by connector P9. The
current ratings listed are per pin.
Table 20.
Expansion Voltages
Current
Name
P9
250mA
VDD_3V3EXP
1000mA
250mA
GND
Name
Current
2
GND
3
4
VDD_3V3EXP
250mA
VDD_5V
5
6
VDD_5V
1000mA
SYS_5V
7
8
SYS_5V
250mA
:
:
GND
43
44
GND
GND
45
46
GND
1
The VDD_3V3EXP rail is supplied by the LDO on the BeagleBone and is the primary
power rail for expansion boards.
VDD_5V is the main power supply from the DC input jack. This voltage is not present
when the board is powered via USB. The amount of current supplied by this rail is
dependent upon the amount of current available. Based on the board design, this rail is
limited to 1A per pin from the main board.
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The SYS_5V rail is the main rail for the regulators on the main board. When powered
from a DC supply or USB, this rail will be 5V. The available current from this rail
depends on the current available from the USB and DC external supplies.
7.5.2
Expansion Board External Power
A Cape can have a jack or terminals to bring in whatever voltages may be needed by that
board. Care should be taken not to let this voltage feedback into any of the expansion
header pins.
It is possible to provide 5V to the main board from an expansion board. By supplying a
5V signal into the VDD_5V rail, the main board can be supplied. This voltage must not
exceed 5V. You should not supply any voltage into any other pin of the expansion
connectors. Based on the board design, this rail is limited to 1A per pin to the
BeagleBone.
7.6
Mechanical
This section provides the guidelines for the creation of expansion boards from a
mechanical standpoint. Defined is a standard board size that is the same profile as the
BeagleBone. It is expected that the majority of expansion boards created will be of
standard size. It is possible to create boards of other sizes and in some cases this is
required, as in the case of an LCD larger than the BeagleBone board.
7.6.1
Standard Cape Size
Figure 40 is the outline of the standard Cape. The dimensions are in inches.
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Figure 40. Cape Board Dimensions
A slot is provided for the Ethernet connector to stick up higher than the Cape when
mounted. This also acts as a key function to insure that the Cape is oriented correctly.
Space is also provided to allow access to the user LEDs and reset button on the main
board.
Some people have inquired as to the difference in the radius of the corners of the
BeagleBone and why they are different. This is a result of having the BeagleBone fit into
the Altoids style Tin.
It is not required that the Cape be exactly like the BeagleBone board in this respect.
7.6.2
Extended Cape Size
Capes larger than the standard board size are also allowed. A good example would be an
LCD panel. There is no practical limit to the sizes of these types of boards. The notch for
the key is also not required, but it is up to the supplier of these boards to insure that the
BeagleBone is not plugged in incorrectly in such a manner that damage would be cause
to the BeagleBone or any other Capes that may be installed. Any such damage will be the
responsibility of the supplier of such a Cape to repair.
As with all Capes, the EEPROM is required and compliance with the power requirements
must be adhered to.
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7.6.3
BeagleBone System Reference
Manual
Rev A6.0.0
Enclosures
There are numerous enclosures being created in all different sizes and styles. The
mechanical design of these enclosures is not being defined by this specification.
The ability of these designs to handle all shapes and sizes of Capes, especially when you
consider up to four can be mounted with all sorts of interface connectors, it is difficult to
define a standard enclosure that will handle all Capes already made and those yet to be
defined.
If Cape designers want to work together and align with one enclosure and work around it
that is certainly acceptable. But we will not pick winners and we will not do anything that
impedes the openness of the platform and the ability of enclosure designers and Cape
designers to innovate and create new concepts.
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BeagleBone System Reference
Manual
Rev A6.0.0
Board Setup
This section describes how to setup the board and to make sure that it is operating. It also
provides an advanced section that allows you to run a self diagnostic test that does
require additional equipment to be purchased.
8.1
Creating A SD Card
If you need to create an SD card for the board that is the same as what ships with the
BeagleBone, you can follow the instructions found at the following location:
http://circuitco.com/support/index.php?title=BeagleBone
Other methods are also possible if you are familiar with Linux. Instructions are found at
the following link which also will have the latest image.
http://www.angstrom-distribution.org/demo/beaglebone/
You will need a 4GB microSD card.
8.2
USB Powered Setup
The board ships with everything you need for this configuration.



BeagleBone
microSD card with bootable SW
USB Type A to 5 pin connector
To setup the board:
1)
2)
3)
4)
5)
6)
Insert the SD card into the SD card connector
Plug the USB cable into the BeagleBone
Plug the other end of the USB cable into the PC USB port.
The power LED D1 should be on
After a few seconds, USER0 and USER1 LED should start flashing
After 10 seconds or so, the board should show up as a mass storage device on
your PC
7) Open the new drive and click on the Readme.html file.
8) The file should open in your browser.
9) Follow the instructions on the HTML page.
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BeagleBone System Reference
Manual
Rev A6.0.0
DC Powered Setup
The board ships with everything you need for this configuration except for a power
supply. The first three items below are provided and the power supply will need to be
provided by you.




BeagleBone
microSD card with bootable SW
USB Type A to 5 pin connector
5VDC 1A power supply w/2.1mm x 5.5mm connector, center positive.
To setup the board:
1)
2)
3)
4)
5)
6)
7)
Insert the SD card into the SD card connector
Plug the DC cable into the board.
The power LED D1 should be on
Plug the USB cable into the BeagleBone
Plug the other end of the USB cable into the PC USB port.
After a few seconds, USER0 and USER1 LED should start flashing
After 10 seconds or so, the board should show up as a mass storage device on
your PC
8) Open the new drive and click on the Readme.html file.
9) The file should open in your browser.
10) Follow the instructions on the HTML page.
8.4
Advanced Test
This test involves the purchase of a USB hub that is equipped with an Ethernet port or the
use of a USB Hub with a USB to Ethernet Dongle plugged in. The SW that ships with the
board is capable of running this test. You may need to load drivers for your particular
Hub or Ethernet dongle.
The following procedure will setup and test the board. The following items are tested on
the board:










USB Client Port
USB Host Port
Ethernet Port
DDR
PMIC
EEPROM
Processor
SD Slot
DC Power
USB HUB
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

8.4.1
BeagleBone System Reference
Manual
Rev A6.0.0
USB to Serial
LEDs
Equipment Needed
The following items are needed to perform this test:
1)
2)
3)
4)
5)
6)
8.4.2
USB Hub with Ethernet port
Ethernet Cable
USB A Male to 5pin male
BeagleBone
26 AWG jumper wire, stripped
5VDC 1A power supply, 2.1mm Center positive
Procedure
1)
2)
3)
4)
5)
Connect the USB HUB to the USB Host port of the BeagleBone.
Connect the HUB Ethernet port to the BeagleBone Ethernet port.
Connect one of the USB ports to USB connector on the BeagleBone.
Insert the SD card that came with the board into the SD connector.
Add a jumper wire between pin 2 and 3 of the P8. This tells the SW to run the
test.
6) Insert the DC power supply
7) The PWR LED should turn on.
8) Then D2 and D3 should start flashing indicating the boot process has begun.
9) After about a minute, D2 and D3 should turn off and D5 should start flashing.
10) D5 will continue to flash during the test process which should take about 2-3
minutes.
11) At the end of the test one of two things will happen:
a. If all the LEDS are on solid, then the board has passed the test.
b. If all LEDS are flashing, then the board has failed the test.
8.4.3
Debugging
It is possible to add a USB to serial cable to the external HUB for messages as the tests
run. This will tell you where the test fails. It will require a USB to serial adapter to also
be plugged into your PC and a Null modem female to female adapter be placed between
the two cables.
In order for this to work, the Linux driver needs to be installed on the BeagleBone for the
USB to serial adapter. For now, only one USB to serial adapter is supported. Others will
be added over time.
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Once you have the correct cable configuration, you can open up a terminal program set to
the serial port and set for 115KBaud, 8,n,1 and no handshaking. The results of the test as
run will be printed to the terminal.
9.0
Software Support
This section provides assistance in working with the Software that comes with the
Beaglebone. The primary support mailing list is [email protected]
9.1
Tutorials
Have a look at these websites to get an idea of what people have been working on. It
should prove helpful to you.
The Ångström website has links to various tutorials and projects, you can find it at
http://www.angstrom-distribution.org/
Limor Fried of adafruit.com fame has started a collection of Beaglebone related tutorials
of one which deals with wifi:
http://ladyada.net/products/beaglebone/index.html
Dan Watts has a number of tutorial on how to use the GPIOs and PWM pins:
http://www.gigamegablog.com/tag/beaglebone/
Graeme Gregory has published an example kernel development workflow:
http://www.slimlogic.co.uk/2011/05/openembeddedangstrom-kernel-workflow/
9.2
Reinstalling The Angstrom Image
To reinstall the SD card image you can completely reimage the SD card using Linux:
Visit http://downloads.angstrom-distribution.org/demo/beaglebone/ and get the img.xz
file you want. Then find out which drive corresponds with your SD card reader:
$ dmesg | grep sd
The output should look something like this:
sd 8:0:0:0: Attached scsi generic sg4 type 0
sd 8:0:0:0: [sde] 7626752 512-byte logical blocks: (3.90 GB/3.63 GiB)
sd 8:0:0:0: [sde] Write Protect is off
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sd 8:0:0:0: [sde] Mode Sense: 03 00 00 00
sd 8:0:0:0: [sde] No Caching mode page present
sd 8:0:0:0: [sde] Assuming drive cache: write through
sd 8:0:0:0: [sde] No Caching mode page present
sd 8:0:0:0: [sde] Assuming drive cache: write through
sde: sde1 sde2
This shows that it detected a 4GB card and assigned it to /dev/sde. In the next steps
replace /dev/sdX with the name from the previous step. Be very careful with this. Using
the wrong name can result in an erased hard drive.
To reimage the SD card do the following:
$ sudo -s
(type in your password)
# xz -dkc imagename.img.xz > /dev/sdX
# exit
This will take more than 20 minutes, usually 45-60 minutes, depending on the speed of
your card reader and SD card.
9.3
Rebuilding The Angstrom Image
The SD card image in the box is based on the Ångström distribution. All Ångström
binaries are built using OpenEmbedded. This section describes the steps necessary to
setup an environment where you can rebuild the images and packages yourself.
The build is managed by scripts to make things easier, so get the setup scripts:
$ git clone git://github.com/Angstrom-distribution/setup-scripts.git
If you are behind a firewalling proxy, have a look at the oebb.sh file, it has built-in proxy
handling.
Configure the setup scripts for the beaglebone:
$ MACHINE=beaglebone ./oebb.sh config beaglebone
Start with a kernel build:
$ MACHINE=beaglebone ./oebb.sh bitbake virtual/kernel
Or a small command line image:
$ MACHINE=beaglebone./oebb.sh bitbake systemd-image
Or rebuild the SD card image:
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$ MACHINE=beaglebone ./oebb.sh bitbake cloud9-gnome-image
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10.0 BeagleBone Mechanical Specification
Size:
Max height:
PCB Layers:
PCB thickness:
RoHS Compliant:
Weight:
3.5” x 2.1” (86.36mm x 53.34mm)
.187” (4.76mm)
6
.062”
Yes
1.4 oz
Figure 41. Board Top Profile
Figure 42. Board Bottom Profile
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11.0 Design Information
Design information can be found on the SD card that ships with board under the
documents/hardware directory when connected over the USB cable. Provided there is:






Schematic in PDF
Schematic in OrCAD (Cadence Design Entry CIS 16.3)
PCB Gerber
PCB Layout File (Allegro)
Bill of Material
System Reference Manual (This document).
You can also download the files from http://beagleboard.org/hardware/design .or from
the CircuitCo WIKI at http://circuitco.com/support/index.php?title=BeagleBone
ALL support for this design is through the BeagleBoard.org community at
[email protected] .
There are also some community members working to convert the schematics and PCB
files into other formats. Look for those to available in the future.
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