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EK-LM3S8962-08 Copyright © 2007–2010 Texas Instruments
User ’s Manual
Stellaris® LM3S8962 Evaluation Board
2 February 9, 2010
CopyrightCopyright © 2007–2010 Texas Instruments, Inc. All rights reserved. Stellaris and StellarisWare are registered trademarks of Texas Instruments. ARM and Thumb are registered trademarks, and Cortex is a trademark of ARM Limited. Other names and brands may be claimed as the property of others.
Texas Instruments108 Wild Basin, Suite 350Austin, TX 78746http://www.ti.com/stellaris
Stellaris® LM3S8962 Evaluation Board
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Table of ContentsChapter 1: Stellaris® LM3S8962 Evaluation Board Overview ...................................................................... 9Features............................................................................................................................................................ 10Block Diagram .................................................................................................................................................. 11Evaluation Kit Contents .................................................................................................................................... 12
Evaluation Board Specifications ................................................................................................................... 12Features of the LM3S8962 Microcontroller....................................................................................................... 12
Chapter 2: LM3S8962 Evaluation Board Hardware Description................................................................. 15LM3S8962 Evaluation Board ............................................................................................................................ 15
LM3S8962 Microcontroller Overview ............................................................................................................ 15Ethernet ........................................................................................................................................................ 15CAN Module.................................................................................................................................................. 15Clocking ........................................................................................................................................................ 15Reset............................................................................................................................................................. 16Power Supplies ............................................................................................................................................. 16Debugging..................................................................................................................................................... 16
USB Device Controller Functions ..................................................................................................................... 17USB Overview............................................................................................................................................... 17USB to JTAG/SWD....................................................................................................................................... 17Virtual COM Port........................................................................................................................................... 17Serial Wire Out.............................................................................................................................................. 17
Organic LED Display ........................................................................................................................................ 18Features........................................................................................................................................................ 18Control Interface ........................................................................................................................................... 18Power Supply................................................................................................................................................ 18Design Guidelines......................................................................................................................................... 18Further Reference......................................................................................................................................... 18
Other Peripherals.............................................................................................................................................. 18Speaker......................................................................................................................................................... 18MicroSD Card Slot ........................................................................................................................................ 19Push Switches .............................................................................................................................................. 19User LED ...................................................................................................................................................... 19
Bypassing Peripherals ...................................................................................................................................... 19Interfacing to the EVB....................................................................................................................................... 20Using the In-Circuit Debugger Interface ........................................................................................................... 20
Chapter 3: CAN Device Board Hardware Description ................................................................................. 21Device Overview............................................................................................................................................... 21
Power Supply................................................................................................................................................ 21Programming and Debugging ....................................................................................................................... 21Interfacing ..................................................................................................................................................... 21
Appendix A: Schematics................................................................................................................................ 23Appendix B: Connection Details ................................................................................................................... 29Component Locations....................................................................................................................................... 30
4 February 9, 2010
Evaluation Board Dimensions........................................................................................................................... 31I/O Breakout Pads ............................................................................................................................................ 32LM3S2110 CAN Device Board Connections .................................................................................................... 33Recommended Connectors .............................................................................................................................. 33ARM Target Pinout ........................................................................................................................................... 34References ....................................................................................................................................................... 35
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List of TablesTable 2-1. Stellaris LM3S8962 Evaluation Board Hardware Debugging Configurations................................ 16Table 2-2. Isolating On-Board Hardware........................................................................................................ 19Table B-1. I/O Breakout Pads ......................................................................................................................... 32Table B-2. Recommended Connectors........................................................................................................... 33Table B-3. 20-Pin JTAG/SWD Configuration .................................................................................................. 34
6 February 9, 2010
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List of FiguresFigure 1-1. Stellaris LM3S8962 Evaluation Board Layout ................................................................................. 9Figure 1-2. Stellaris LM3S2110 CAN Device Board ........................................................................................ 10Figure 1-3. LM3S8962 Evaluation Board Block Diagram ................................................................................ 11Figure 1-4. LM3S2110 CAN Device Block Diagram ........................................................................................ 11Figure 2-1. ICD Interface Mode ....................................................................................................................... 20Figure B-1. LM3S8962 Evaluation Board Component Locations..................................................................... 30Figure B-2. LM3S8962 Evaluation Board Dimensions..................................................................................... 31Figure B-3. LM3S2110 CAN Device Board Dimensions .................................................................................. 31
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Stellaris® LM3S8962 Evaluation Board OverviewThe Stellaris® LM3S8962 Evaluation Board is a compact and versatile evaluation platform for the Stellaris LM3S8962 ARM® Cortex™-M3-based microcontroller. The evaluation kit design highlights the LM3S8962 microcontroller's integrated CAN and 10/100 Ethernet controllers.
As well as implementing an embedded web server, the kit functions as a complete controller area network (CAN) by providing two boards each with a Stellaris microcontroller. The main evaluation board (EVB) is the CAN host. A small CAN device board, linked with a ribbon cable, uses a Stellaris LM3S2110 microcontroller. The function of each board is fully configurable in software.
You can use the EVB either as an evaluation platform or as a low-cost in-circuit debug interface (ICDI). In debug interface mode, the on-board microcontroller is bypassed, allowing connection of the debug signals to an external Stellaris microcontroller target. The kit is also compatible with high-performance external JTAG debuggers.
This evaluation kit enables quick evaluation, prototype development, and creation of application-specific designs for Ethernet and CAN networks. The kit also includes extensive source-code examples, allowing you to start building C code applications quickly.
Figure 1-1. Stellaris LM3S8962 Evaluation Board Layout
USB Device Interface
10/100baseT Ethernet Jack
microSD Card Memory Slot
30 pin I/O break-out header
30 pin I/O break-out header
Navigation Switches
Select switch
Status LED
Speaker
Debug -out LED
Reset switch
Power LED
OLED Graphics Display
JTAG/SWD input and output
StellarisTM
LM3S8962 Microcontroller
In-circuit Debug Interface
CAN Bus connector
C H A P T E R 1
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10 February 9, 2010
Figure 1-2. Stellaris LM3S2110 CAN Device Board
FeaturesThe Stellaris LM3S8962 Evaluation Kit includes the following features:
Stellaris LM3S8962 microcontroller with fully-integrated 10/100 embedded Ethernet controller and CAN module
Simple setup; USB cable provides serial communication, debugging, and power
OLED graphics display with 128 x 96 pixel resolution
User LED, navigation switches, and select pushbuttons
Magnetic speaker
MicroSD card slot
USB interface for debugging and power supply
Standard ARM® 20-pin JTAG debug connector with input and output modes
LM3S8962 I/O available on labeled break-out pads
Standalone CAN device board using Stellaris LM3S2110 microcontroller
User switches
CAN bus connector
I/O break-out headers
Power LED
Reset switch
Status LED
JTAG/SWD input
Stellaris® LM3S2110
Microcontroller
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Block DiagramFigure 1-3. LM3S8962 Evaluation Board Block Diagram
Figure 1-4. LM3S2110 CAN Device Block Diagram
USB
USB
USB
StellarisLM3S8962
Microcontroller
DualUSB
DeviceController
I/O S
igna
ls
OLED Display128 x 96
Debu
g
I/O Signal Break-out
JTAG/SWD Output/Input
USB Cable
Reset+3.3V
Regulator
SW
D/JT
AG M
ux
UART0
Targ
et
Cab
le
Debug
CAN PHY CAN0CAN
Switch
NavSwitch
Speaker
LED
LM3S8962 CAN Evaluation Board
I/O Signal Break-out
I/O Signal Break-outI/O Signal Break-out
RJ45Jack+
MagneticsCAT5 Cable
MicroSD card slot
1GB
USB
StellarisLM3S2110
Microcontroller
I/O S
igna
lsDebug
I/O Signal Break-out
I/O Signal Break-out
JTAG/SWDInput +3.3V
Regulator
CAN PHY CAN0CAN
Switch
LED
LM3S2110CAN Device
Board
Reset
Switch
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12 February 9, 2010
Evaluation Kit ContentsThe evaluation kit contains everything needed to develop and run applications for Stellaris microcontrollers including:
LM3S8962 evaluation board (EVB)
LM3S2110 CAN device board
USB cable
20-pin JTAG/SWD target cable
10-pin CAN cable
CD containing:
– A supported version of one of the following (including a toolchain-specific Quickstart guide):
• Keil™ RealView® Microcontroller Development Kit (MDK-ARM)
• IAR Embedded Workbench
• Code Sourcery GCC development tools
• Code Red Technologies development tools
• Texas Instruments’ Code Composer Studio™ IDE
– Complete documentation
– Quickstart application source code
– Stellaris® Firmware Development Package with example source code
Evaluation Board SpecificationsBoard supply voltage: 4.37–5.25 Vdc from USB connector
Board supply current: 240 mA typ (fully active, CPU at 50 MHz)
Break-out power output: 3.3 Vdc (60 mA max), 15 Vdc (15 mA max)
Dimensions: 4.55” x 2.45” x 0.7” (L x W x H)
RoHS status: Compliant
Features of the LM3S8962 Microcontroller32-bit RISC performance using ARM® Cortex™-M3 v7M architecture
– 50-MHz operation
– Hardware-division and single-cycle-multiplication
– Memory protection unit (MPU), provides a privileged mode for protected operating system functionality
– Integrated Nested Vectored Interrupt Controller (NVIC)
– 42 interrupt channels with eight priority levels
256-KB single-cycle Flash
64-KB single-cycle SRAM
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Four general-purpose 32-bit timers
Integrated Ethernet MAC and PHY
Controller area network (CAN) module
Three fully programmable 16C550-type UARTs
Four 10-bit ADC channels (inputs) when used as single-ended inputs
One integrated analog comparator
One I2C module
Two PWM generator blocks
– One 16-bit counter
– Two comparators
– Produces two independent PWM signals
– One dead-band generator
Two QEI modules with position integrator for tracking encoder position
Two synchronous serial interfaces (SSIs)
0 to 42 GPIOs, depending on user configuration
On-chip low drop-out (LDO) voltage regulator
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14 February 9, 2010
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LM3S8962 Evaluation Board Hardware DescriptionIn addition to a microcontroller, the Stellaris LM3S8962 evaluation board includes a range of useful peripherals and an integrated in-circuit debug interface (ICDI). This chapter describes how these peripherals operate and interface to the microcontroller.
LM3S8962 Evaluation BoardLM3S8962 Microcontroller Overview
The heart of the EVB is a Stellaris LM3S8962 ARM Cortex-M3-based microcontroller. The LM3S8962 offers 256-KB Flash memory, 50-MHz operation, an Ethernet controller, a CAN module, and a wide range of peripherals. Refer to the LM3S8962 data sheet (order number DS-LM3S8962) for complete device details.
The LM3S8962 microcontroller is factory-programmed with a quickstart demo program. The quickstart program resides in the LM3S8962 on-chip Flash memory and runs each time power is applied, unless the quickstart has been replaced with a user program.
EthernetA key feature of the LM3S8962 microcontroller is its fully integrated Ethernet controller. Only an RJ45 jack with integrated magnetics and a few passive components are needed to complete the 10/100baseT interface. The RJ45 jack incorporates LEDs that indicate traffic and link status. These are automatically managed by on-chip microcontroller hardware. Alternatively, the LEDs can be software-controlled by configuring those pins as general-purpose outputs.
The LM3S8962 supports automatic MDI/MDI-X so the EVB can connect directly to a network or to another Ethernet device without requiring a cross-over cable.
CAN ModuleA CAN module enables highly reliable communications at up to 1 Mbits/s. The LM3S8962 evaluation board includes a standard CAN transceiver and a 10-pin CAN connector whose signal assignments follow a commonly used CAN standard. A simple adaptor (not included in the kit) can be used to allow the use of standard DB-9 CAN cables (as specified by CAN in Automation CiA DS102).
An on-board 120-ohm resistor provides bus termination. This resistor can be removed if the board is not a network endpoint.
The CAN transceiver is configured in hardware to support speeds up to 1 Mbits/s. A resistor can be added to reduce the transceiver's drive slew-rate for slower data rates over longer distances.
ClockingThe LM3S8962 microcontroller has four on-chip oscillators, three are implemented on the EVB. An internal 12 MHz oscillator is the clock source the microcontroller uses during and following POR. An 8.0-MHz crystal completes the LM3S8962’s main internal clock circuit. An internal PLL, configured in software, multiplies this clock to 50-MHz for core and peripheral timing. The internal 12MHz oscillator is the primary clock source during start-up.
C H A P T E R 2
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16 February 9, 2010
A small, 25-MHz crystal is used by the LM3S8962 microcontroller for Ethernet physical layer timing and is independent of the main oscillator.
ResetThe LM3S8962 microcontroller shares its external reset input with the OLED display. In the EVB, reset sources are gated through the CPLD, though in a typical application a simple wired-OR arrangement is sufficient.
External reset is asserted (active low) under any one of three conditions:
Power-on reset
Reset push switch SW1 held down
Internal debug mode—By the USB device controller (U4 FT2232) when instructed by debugger
Power SuppliesThe LM3S8962 is powered from a +3.3-V supply. A low drop-out (LDO) regulator regulates +5-V power from the USB cable to +3.3-V. +3.3-V power is available for powering external circuits.
A +15-V rail is available when the OLED display power supply is active. The speaker and the OLED display boost-converter operate from the +5-V rail.
DebuggingStellaris microcontrollers support programming and debugging using either JTAG or SWD. JTAG uses the signals TCK, TMS, TDI, and TDO. SWD requires fewer signals (SWCLK, SWDIO, and, optionally, SWO for trace). The debugger determines which debug protocol is used.
Debugging ModesThe LM3S8962 evaluation board supports a range of hardware debugging configurations. Table 2-1 summarizes these configurations.
Modes 2 and 3 automatically detect the presence of an external debug cable. When the debugger software is connected to the EVB's USB controller, the EVB automatically selects Mode 2 and illuminates the red Debug Out LED.
Table 2-1. Stellaris LM3S8962 Evaluation Board Hardware Debugging Configurations
Mode Debug Function Use Selected by
1 Internal ICDI Debug on-board LM3S8962 microcontroller over USB interface.
Default mode
2 ICDI out to JTAG/SWD header
The EVB is used as a USB to SWD/JTAG interface to an external target.
Connecting to an external target and starting debug software. The red Debug Out LED will be ON.
3 In from JTAG/SWD header For users who prefer an external debug interface (ULINK, JLINK, etc.) with the EVB.
Connecting an external debugger to the JTAG/SWD header.
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Debug In ConsiderationsDebug Mode 3 supports evaluation board debugging using an external debug interface. Mode 3 is automatically selected when a device such as a Segger J-Link or Keil ULINK is connected.
Boards marked Revision B or later automatically configure pin 1 to be a 3.3-V reference, if an external debugger is connected. To determine the revision of your board, locate the product number on the bottom of the board; for example, EK-LM3S8962-B. The last character of the product number identifies the board revision.
A configuration or board-level change may be necessary when using an external debug interface with revision A of this evaluation board. Because the evaluation board supports both debug out and debug in modes, pin 1 of the 20-pin JTAG/SWD header is, by default, not connected to +3.3 V. Consequently, devices requiring a voltage on pin 1 to power their line buffers may not work.
Two solutions exist. Some debugger interfaces (such as ULINK) have an internal power jumper that, in this case, should be set to internal +3.3 V power. Refer to debugger interface documentation for full details. However, if your debugger interface does not have a selectable power source, it may be necessary to install a 0-Ω resistor on the evaluation board to route power to pin 1. Refer to the schematics and board drawing in the appendix of this manual for the location of this resistor.
USB Device Controller FunctionsUSB Overview
An FT2232 device from Future Technology Devices International Ltd. manages USB-to-serial conversion. The FT2232 is factory-configured to implement a JTAG/SWD port (synchronous serial) on channel A and a Virtual COM Port (VCP) on channel B. This feature allows two simultaneous communications links between the host computer and the target device using a single USB cable. Separate Windows drivers for each function are provided on the Documentation and Software CD.
A small serial EEPROM holds the FT2232 configuration data. The EEPROM is not accessible by the LM3S8962 microcontroller.
For full details on FT2232 operation, go to www.ftdichip.com.
USB to JTAG/SWDThe FT2232 USB device performs JTAG/SWD serial operations under the control of the debugger. A CPLD (U6) multiplexes SWD and JTAG functions and, when working in SWD mode, provides direction control for the bidirectional data line. The CPLD also implements logic to select between the three debug modes. The internal or external target selection is determined by multiplexing TCK/SWCLK and asserting TRST.
Virtual COM PortThe Virtual COM Port (VCP) allows Windows applications (such as HyperTerminal) to communicate with UART0 on the LM3S8962 over USB. Once the FT2232 VCP driver is installed, Windows assigns a COM port number to the VCP channel.
Serial Wire OutThe evaluation board supports the Cortex-M3 serial-wire output (SWO) trace capabilities. Under debugger control, the CPLD can route the SWO datastream to the virtual communication port (VCP) transmit channel. The debugger can then decode and interpret the trace information
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18 February 9, 2010
received from the VCP. The normal VCP connection to UART0 is interrupted when using SWO. Not all debuggers support SWO. Refer to the Stellaris LM3S8962 data sheet for additional information on the trace port interface unit (TPIU).
Organic LED DisplayThe EVB features an Organic LED (OLED) graphics display with 128 x 96 pixel resolution. OLED is a new technology that offers many advantages over LCD display technology. The display is protected by a thin protective plastic film. If desired the film can be removed using a pair of tweezers.
FeaturesRiT P14201 series display
128 columns by 96 rows
High-contrast (typ. 500:1)
Excellent brightness (120 cd/m2)
Fast 10 us response
Control InterfaceThe OLED display has a built-in controller IC with synchronous serial and parallel interfaces. Synchronous serial (SSI) is used on the EVB as it requires fewer microcontroller pins. Data cannot be read from the OLED controller; only one data line is necessary. Note that the SSI port is shared with the MicroSD card slot. The Stellaris® Firmware Development Package (included on the Documentation and Software CD) contains complete drivers with source-code for the OLED display.
Power SupplyA +15-V supply is needed to bias the OLED display. A FAN5331 device from Fairchild combines with a few external components to complete a boost converter. A GPIO (PA7) is assigned to turn on and off the controller as necessary for power rail sequencing. When the OLED display is operating, a small amount of power can be drawn from the +15-V rail to power other devices.
Design GuidelinesThe OLED display has a lifetime of about 13,000 hours. It is also prone to degradation due to burn-in, similar to CRT and plasma displays. The quickstart application includes both a screen saver and a power-down mode to extend display life. These factors should be considered when developing EVB applications that use the OLED display.
Further ReferenceFor additional information on the RiT OLED display, visit www.ritekdisplay.com.
Other PeripheralsSpeaker
A small, magnetic audio transducer connects through a MOSFET to PG1/PWM1, allowing a range of options for generating simple and complex tones. Use of the +5-V rail reduces switching noise on the +3.3-V rail.
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February 9, 2010 19
MicroSD Card SlotRemovable Flash cards are an ideal media for storing data such as web page content. The source code on the CD includes example code for reading data from standard FAT-formatted SD cards. All data and control transactions use the SD card's SPI mode. Note that the SD card specification does not require that a card supports the SPI mode, but most cards do so in practice. Cards from several vendors have been used with the EVB.
MicroSD cards are very small and require careful handling. The SD card slot on the EVB is a push-push type (push to insert; push again to eject).
NOTE: To avoid damage, remove power before inserting or removing cards.The EVB does not implement SD card power control.
Push SwitchesThe EVB has five general-purpose input switches. Four are arranged in a navigation-style configuration. The fifth functions as a Select switch.
User LEDA user LED (LED1) is provided for general use. The LED is connected to PF0/PWM0, allowing the option of either GPIO or PWM control (brightness control). Refer to the Quickstart Application source code for an example of PWM control.
Bypassing PeripheralsExcluding Ethernet and CAN, the EVB's on-board peripheral circuits require 16 GPIO lines. Two additional GPIO lines are assigned to Ethernet LEDs. This leaves 20 GPIO lines and 4 ADC channels immediately available for connection to external circuits. If an application requires more GPIO lines, the on-board hardware can be disconnected. The EVB is populated with 16 jumper links, which can be cut with a knife to isolate on-board hardware. The process can be reversed by installing 0603- 0-ohm chip resistors. Table 2-2 shows the microcontroller assignments and how to isolate specific pins.
Important: The quickstart application will not run if one or more jumpers are removed.
Table 2-2. Isolating On-Board Hardware
Microcontroller Pin EVB Function To Isolate, Remove...
Pin 26 PA0/U0RX Virtual COM port receive JP1
Pin 27 PA1/U0TX Virtual COM port transmit JP2
Pin 19 PG0 SD card chip select JP4
Pin 30 PA4/SSI0RX SD card data out JP5
Pin 31 PA5/SSI0TX SD card and OLED display data in JP6
Pin 28 PA2/SSI0CLK SD card and OLED display clock JP7
Pin 34 PA6/CCP1 OLED display data/control select JP8
Pin 19 PG0 OLED display chip select JP9
Pin 18 PG1/PWM1 Sound JP10
Pin 61 PF1/IDX1 Select switch JP11
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20 February 9, 2010
Interfacing to the EVBAn array of accessible I/O signals makes it easy to interface the EVB to external circuits. All LM3S8962 I/O lines (except those with both JTAG and SWD functions) are brought out to 0.1” pitch pads. For quick reference, silk-screened labels on the PCB show primary pin functions.
Most LM3S8962 I/O signals are +5-V tolerant. Refer to the LM3S8962 microcontroller data sheet for detailed electrical specifications.
Using the In-Circuit Debugger InterfaceThe Stellaris LM3S8962 Evaluation Kit can operate as an In-Circuit Debugger Interface (ICDI). ICDI acts as a USB to the JTAG/SWD adaptor, allowing debugging of any external target board that uses a Stellaris microcontroller. See “Debugging Modes” on page 16 for a description of how to enter Debug Out mode.
Figure 2-1. ICD Interface Mode
The debug interface operates in either serial-wire debug (SWD) or full JTAG mode, depending on the configuration in the debugger IDE.
The IDE/debugger does not distinguish between the on-EVB Stellaris microcontroller and an external Stellaris microcontroller. The only requirement is that the correct Stellaris device is selected in the project configuration.
Pin 72 PE0/PWM4 Up switch JP12
Pin 74 PE2/PHB1 Left switch JP13
Pin 75 PE3/PHA1 Right switch JP14
Pin 73 PE1/PWM5 Down switch JP15
Pin 47 PF0/PWM0 User LED JP16
Table 2-2. Isolating On-Board Hardware
Microcontroller Pin EVB Function To Isolate, Remove...
Evaluation Board Target Board
Stellaris MCU
Target Cable
`USB
PC with IDE/debugger
Stellaris MCU
TCK/SWCLK bypasses the on-board microcontroller
JTAG or SWD connects to the external microcontroller
Connecting Pin 18 to GND sets external debug mode
February 9, 2010 21
CAN Device Board Hardware DescriptionThe CAN device board uses a Stellaris LM3S2110 microcontroller to demonstrate a complete two-node network. The board can be used with the main LM3S8962 evaluation board or as a standalone board.
Device OverviewThe Stellaris LM3S2110 ARM Cortex-M3-based microcontroller has 64-KB Flash memory, 25-MHz operation, a CAN module, and a wide range of peripherals. For complete device details, see the LM3S2110 data sheet (order number DS-LM3S2110).
The LM3S2110 microcontroller is factory programmed with a quickstart demonstration program that adds a remote volume control feature to the quickstart application. The quickstart program resides in the LM3S2110 on-chip Flash memory and runs each time power is applied, unless the quickstart has been replaced with a user program.
Power SupplyThe CAN device board receives +5.0-V power from the CAN bus and should not be connected to a CAN bus that has a power wire voltage of greater than 10.0 V. If the bus is unpowered, a +5.0-V local power supply must be provided. The LM3S2110 microcontroller is powered from a +3.3-V rail, supplied by a low drop-out (LDO) regulator. +3.3-V power is available for powering external circuits.
Programming and DebuggingA standard 20-pin header supports both JTAG And SWD programming and debugging using either the main LM3S8962 board in ICDI out mode or a full-featured debug interface.
InterfacingTwo push switches and an LED implement a very simple user interface. The board’s capabilities are easily expanded using the I/O breakout headers. For breakout header signal assignments, see “LM3S2110 CAN Device Board Connections” on page 33.
C H A P T E R 3
CAN Device Board Hardware Description
22 February 9, 2010
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SchematicsThis section contains the schematics for the LM3S8962 Evaluation Board.
LM3S8962 Micro, Ethernet, and CAN on page 24
OLED Display, Switches, and Audio on page 25
USB, Debugger Interfaces, and Power on page 26
CAN Device using LM3S2110 on page 27
JTAG Logic with Auto Mode Detect and Hibernate on page 28
A P P E N D I X A
1
1
2
2
3
3
4
4
5
5
6
6
D D
C C
B B
A A
Document Number:
RevSheetDate: of9/25/2008 1 4
Drawing Title:
Page Title:
Size
Ethernet and CAN Evaluation Board
LM3S8962 Micro, Ethernet and CAN
B
C
EK-LM3S8962
Revision Date Description
0 Jul 24, 07 Prototype release
History
18PF
C8
18PF
C9
INT_TCKTMS/SWDIO
PC2/TDIPC3/TDO
ADC3ADC2ADC1ADC0
MCURSTn
6
5
8
4
2
3
1
7
1CT:1
TX+
TX-
RX+
RX-1CT:1
Y+
Y-
G+
G-
3
8
7
4
5
6
1112
21
GL
GR
910
NC
GND
P2
J3011G21DNL
R549.9
+3.3V
C130.01UF
R449.9
R849.9
R949.9
C4
0.1UF
+3.3V
C5
0.1UF
+3.3V
C710pF
C210pF
C310pF
C190.01UF
C140.01UF
C150.01UF
C170.1UF
C160.1UF
C120.1UF
+3.3V
+3.3V
R6
330
PA1/U0TxPA2/SSI0CLKPA3/SSI0FSSPA4/SSI0RXPA5/SSI0TX
PA0/U0Rx
R3
10K
+3.3V
R7
330
+3.3V
+3.3V
PA6/CCP1PA7
TMS/SWDIOPC2/TDIPC3/TDOPC4/PhA0PC5PC6/PhB0PC7
PE0/PWM4PE1/PWM5PE2/PhB1PE3/PhA1
PG0PG1/PWM1
PF1/IDX1PF0/PWM0
PD7/IDX0PD6/FAULTPD5PD4/CCP0PD3/U1TXPD2/U1RXPD1/CAN0TxPD0/CAN0Rx
PB6/C0+PB5/C0oPB4/C0-PB3/I2CSDAPB2/I2C0SCLPB1/PWM3PB0/PWM2
PF2/LED1PF3/LED0
C200.1UF
C214.7UF
C184.7UF
1 2Y1
25.00MHz
JP1
JP2
PA0/U0Rx
PA1/U0Tx
VCP_RX
VCP_TX
SSICLK
OLEDCSn
PA2/SSI0CLK
PA3/SSI0FSS
SSITXPA5/SSI0TX
On-board Peripheral Signals
free GPIO lines as required.
SELECT_SWn
LED
UP_SWn
DOWN_SWn
LEFT_SWn
RIGHT_SWn
Jumpers can be cut to
SOUND
SSIRXPA4/SSI0RX
OSC32INOSC32OUT
OLEDDC
CARDCSn
PF1/IDX1
PF0/PWM0
PE0/PWM4
PE1/PWM5
PE2/PhB1
PE3/PhA1
PG1/PWM1
PG0
PA6/CCP1
C610pF
R210K
+3.3V
1 2Y2
8.00MHz
18PF
C10
18PF
C11
10/100baseT Ethernet Jack
Stellaris LM3S8962 Microcontroller
1 23 45 67 89 10
P1
Header 5X2
+5V
R1120R
+5V
Pin-out enables straight-throughconnection to a CAN DB-9M.
+BUSPWR
CANHGND
GNDCANL
C10.1UF
D1
MBR0520
CANH 7
CANL 6TXD1
RXD4
RS8
GND2 VREF 5VCC 3
U2
SN65HVD1050D
JP17
CAN Port
PB7/TRST
EN+15VPA7
PB7/TRST
PD4/CCP0PD6/FAULT
12
32
36
31
59 60
ADC3ADC1
PD2/U1RXPG1/PWM1PC7PC5
PA1/U0TxPA3/SSI0FSSPA5/SSI0TXPA7
PB4/C0-
PD5PD7/IDX0ADC0ADC2
PD3/U1TXPG0PC6/PhB0
PC4/PhA0PA0/U0RxPA2/SSI0CLKPA4/SSI0RXPA6/CCP1
+3.3V
+15V
PB5/C0oPB6/C0+PB7/TRSTPC2/TDI
PC3/TDOPE3/PhA1PE2/PhB1
PE0/PWM4 PE1/PWM5PB2/I2C0SCL PB3/I2CSDAPB1/PWM3PF1/IDX1 PB0/PWM2PF3/LED0 PF2/LED1
OSC32OUTOSC32IN
+3.3VPF0/PWM0
I/O Break-out Headers
+5V
2930
Production ReleaseAug 11, 07A
Implement auto TVcc controlJan 28, 08B
Add R36 for future compatibility.May 12, 08C
R36
12.4K
Tie R8/R9 to +3.3V.
+3.3V
PA0/U0RX26
PA1/U0TX27
PA2/SSI0CLK28
PA3/SSI0FSS29
PA4/SSI0RX30
PA5/SSI0TX31
PC0/TCK/SWCLK80
PC1/TMS/SWDIO79
PC2/TDI78
PC3/TDO/SWO77
PC4/PhA025
PC524
PC6/PhB023
PC722
PD0/CAN0Rx 10
PD1/CAN0Tx 11
PD2/U1RX 12
PD3/U1TX 13
PD4/CCP0 95
PD5 96
PD6/FAULT 99
PD7/IDX0 100
GND9
GND15
GND21
GND33
RST64
LDO 7
MOSCin48
MOSCout49
PB0/PWM2 66
PB1/PWM3 67
PB2/I2C0SCL 70
PB3/I2C0SDA 71
PB4/C0- 92
PB5/C0o 91
PB6/C0+ 90
PB7/TRST 89
PE0/PWM472
PE1/PWM573
PE2/PhB174
PE3/PhA175
ADC36 ADC25
PA6/CCP134
PA735
ADC12 ADC01
PF0/PWM0 47
PF1/IDX1 61
PF2/LED1 60
PF3/LED0 59
MDIO 58
TXON 46
TXOP 43
GND42
PG019
PG1/PWM118
XTALNPHY17
XTALPPHY16
ERBIAS 41
RXIP 40
RXIN 37
VDD33 36
GND86 GND85
VDD33 84VDD33 83
AVDD 3
AVDD 98
AGND97 AGND4
VDD33 8
VDD33 20
VDD33 32
VDD33 44
VDD33 56
VDD33 68
VDD33 81
VDD33 93
GND39
GND45
GND54
GND57
GND63
GND69
GND82
GND87
GND94
VDD25 14
VDD25 38
VDD25 62
VDD25 88
WAKE50
HIB51
OSC32in52
OSC32out53
VBAT 55
CMOD065
CMOD176
U1
LM3S8962
compatibility with future LM3S8962 revisions12.4K 1% resistor required on Pin 41 for
See Product Change Notification PCN-08001Jul 10, 08 Fix labels for JP3-16
JP7
JP9
JP5
JP6
JP8
JP3
JP16
JP11
JP12
JP15
JP13
JP14
JP4
JP10
Sept 25, 08 Fix net names for some GPIO (Rev C1 PCB)
Schematic page 1
1
1
2
2
3
3
4
4
5
5
6
6
D D
C C
B B
A A
Document Number:
RevSheetDate: of9/25/2008 2 4
Drawing Title:
Page Title:
Size
Ethernet and CAN Evaluation Board
OLED Display, Switches and Audio
B
C
EK-LM3S8962
R16
330
R10
200K
SSITXSSICLK
+3.3V
DBGOUTLED
ResetSW1
SW-B3S1000
SELECT_SWn
UP_SWn
DOWN_SWn
LEFT_SWn
RIGHT_SWn
RESET_SWn
R1310K
+3.3V
Select
Up
Down
Left
Right
Debug Out
R14
330LED
Status
R18
330
Power
R112.2
+5V
Q1NDS331N
R1210K
SOUND
128x96 OLED Graphics Display
Speaker Circuit
Status LEDs
User Switches
+3.3V
C22
4.7UF
D2MBR0520
SW2
SW-B3S1000
SW3
SW-B3S1000
SW4
SW-B3S1000
SW5
SW-B3S1000
SW6
SW-B3S1000
MCURSTnOLEDDC
microSD Card Slot
12345678
9 10 11 12
P3
2908-05WB-MG+3.3V
C260.1UF
+3.3V
CARDCSnSSITX
SSICLK
SSIRX
R1510K
R1710K
+3.3V
+3.3V
12
BZ1
NFT-03C
LED1Green
LED2Red
LED3Green
C25OMIT
+15V
OLEDCSn
C230.1UF
C240.1UF
RGS13128096WH000
NC1
VCIR2
VCOMH3
LVSS4
VSS5
BS16
BS27
IREF8
CSn9
RESn10
D/Cn11
R/Wn12
E13
D0/SCLK14
D1/SDIN15
D216
D317
D418
D519
D620
D721
VDDIO22
VDD23
VCC24
NC25
U3
OLED-RIT-128X96
+3.3V
Schematic page 2
1
1
2
2
3
3
4
4
5
5
6
6
D D
C C
B B
A A
Document Number:
RevSheetDate: of9/25/2008 3 4
Drawing Title:
Page Title:
Size
Ethernet and CAN Evaluation Board
USB, Debugger Interfaces and Power
B
C
EK-LM3S8962
+3.3V+5V
USB +5V to +3.3V 500mA Power Supply
USB+5V JP19
C414.7UF
C274.7UF
+15V 50mA Power Supply for OLED Display
+15V
FB 3
VIN5
SHDNn4 GND 2
SW 1
U7
FAN5331
+5V
C434.7UF C40
4.7UF
D3
MBR0520
0.1UF
C39
120pF
C38R20200K
R3317.8KEN+15V
R1910K
FB1
60ohm @ 100 MHz
GND18
GND25
GND34
ADBUS0 24
ADBUS1 23
ADBUS2 22
ADBUS3 21
ADBUS4 20
ADBUS5 19
ADBUS6 17
ADBUS7 16
ACBUS0 15
ACBUS1 13
ACBUS2 12
ACBUS3 11
BDBUS0 40
BDBUS1 39
BDBUS2 38
BDBUS3 37
BDBUS4 36
BDBUS5 35
BDBUS6 33
BDBUS7 32
BCBUS0 30
BCBUS1 29
BCBUS2 28
BCBUS3 27
SI/WUA 10
SI/WUB 26
GND9
AGND45
VCC 3
VCC 42
VCCIOA 14
VCCIOB 31
AVCC 46
PWREN# 41
XTOUT44 XTIN43
EECS48
EESK1
EEDATA2
TEST47
RESET#4
RSTOUT#5
3V3OUT6
USBDM8
USBDP7
U4
FT2232D
+3.3v
USB+5V
R21 27
R22 27
1 23 45 67 89 1011 1213 1415 1617 1819 20
P5
Header 10X2
+3.3V
+3.3V
DBG_JTAG_EN
R2410K
R25
1.5K
R231.5K
R30
330
+5V
+5V
+5V+5V
XTDIXTMS
TCKTDI/DITDO/DOTMS/OUTEN
0.1UF
C370.1UF
C33
0.1UF
C34
0.1UF
C35
0.1UF
C36
0.1UF
C31
USB Device Controller
Channel A : JTAG / SW Debug
Channel B : Virtual Com PortR31
27
R29
27
R26
27
XTCK
R28
27
VCP_RX
VCP_TX
TCK/SWCLK
PC2/TDI
PC3/TDO
TMS/SWDIO
C32
0.01UF
5V D- D+ ID G
1 2 3 4
75
6
P4 54819-0519 +3.3V
SRSTN
TARGETCABLEn
XTDO
R27
27
TP4
TP3
TP2
TP1
TP5
TP6+3.3V
PLD JTAG TEST POINTS
PLD_TCK
PLD_TMS
PLD_TDI
PLD_TDO
R32
4.7K
+3.3v
Debug Interface Logic
PC3/TDO
TCK/SWCLK
TMS/SWDIO
PC2/TDI
JTAG/SWD InterfaceInput/Output
USB Interface
TDI
1
A52
A63
A74
GN
D (B
ank
0)5
VC
CO
(Ban
k 0)
6
A87
A98
A109
A1110
TCK
11
VC
C12
GN
D13
A1214
A13
15
A14
16
A15
17C
LK1/
I18
CLK
2/I
19
B0 20
B1 21
B2 22
B3 23
B4 24
TMS
25
B5 26
B6 27
B7 28
GN
D (B
ank
1)29
VC
CO
(Ban
k 1)
30
B8 31
B9 32
B10 33
B11 34
TDO
35
VC
C36
GN
D37
B12 38
B13
39B
1440
B15
/GO
E141
CLK
3/I
42
CLK
0/I
43
A0/GOE044
A145
A246
A347
A448
Bank 0 Bank 1
U6LC4032V-75TN48C
+3.3V
PC2/TDI
MCURSTn
DBGOUTLED
TARGETCABLEnPC3/TDO
RESET_SWn
0.1UFC29
+3.3V
TMS/SWDIOTCK/SWCLK
JP18USBSH
CS 1
SK 2
DI 3
DO 4GND5 ORG6 NC7 VCC8
1K 64X16
U5
CAT93C46
1 2Y3
6.00MHz
18PF
C28
18PF
C30
PB7/TRST
0.1UF
C42
R344.7K
+3.3V
INT_TCK
SWO_EN
VCP_TX_SWO
MODE
MODE is reserved for future use.
10uH
L1
NR4018T100M
VOUT 4
SENSE 5VIN26
GND2
NC 3
GND 7
VIN11U8
LP8345ILD-3.3
R354.7K
+3.3V
+3.3V
TVCC
Schematic page 3
1
1
2
2
3
3
4
4
5
5
6
6
D D
C C
B B
A A
Document Number:
RevSheetDate: of9/25/2008 4 4
Drawing Title:
Page Title:
Size
Ethernet and CAN Evaluation Board
CAN Device using LM3S2110
B
C
EK-LM3S8962
DGND DGND
DGND
C1120.1UF
DGND
DGND
DGND
D+3.3V
D+3.3V
Stellaris LM3S2110 Microcontroller
DGNDDGNDDGND
D+5V
CAN Transceiver
Pin-out enables straight-throughconnection to a CAN DB-9M.
+5VBUS
DCANHDCANL
DGND
D+3.3VD+5V
+5V to +3.3V 500mA Power Supply
DGNDDGND DGND
+5VBUS
+5VBUSD+5V D+3.3V
DGND
DTDIDTMSDTCK
DGND
DTDO
D+3.3V
R10368K
DGND
D+3.3V
DRSTn
SW100
SW-B3S1000
SW101
SW-B3S1000
Up
Down
DGND
R100
330
StatusDGND
DPF0
DPF1
DPF2
DTDIDTMSDTCK
DTDO
DGND
R101
330
PowerD+3.3V
C1010.1UF
DGND
C1100.1UF
C1090.1UF
C1080.01UF
C1070.01UF
R102120R
C1020.1UF
1 23 45 67 89 10
P100
Header 5X2
18PF
C104
18PF
C103
1 2Y100
8.00MHz
OMIT
C100
1 23 45 67 89 1011 1213 1415 1617 1819 20
P101
Header 10X2
Power Rail Break-out
C1110.01UF
C1134.7UF
C1054.7UF
C1064.7UFJTAG/SWD Interface
CANH 7
CANL 6TXD1
RXD4
RS8
GND2 VREF 5VCC 3
U101
SN65HVD1050D
CAN Port
DPF0DPF1DPF2
SW102
SW-B3S1000
Reset
DRSTn
JP100
JP101
LED100Green
LED101Green
R10468K
D+3.3V
35336036
32
2
134 43
46454861625958
7864636665
3144414039302928
1211109272625
57565554
1718192021222324
535216151413
47504951
3456
373842
CAN Device Evaluation Board
NOTE: Some LM3S2110 pins are no-connects. These pins have been brought out to pads to allow other Stellaris CAN devices to be used instead of LM3S2110.
PA0/U0RX26
PA1/U0TX27
PA2/SSI0CLK28
PA3/SSI0FSS29
PA4/SSI0RX30
PA5/SSI0TX31
PC0/TCK/SWCLK80
PC1/TMS/SWDIO79
PC2/TDI78
PC3/TDO/SWO77
PC425
PC5/C1+24
PC6/C2+23
PC7/C2-22
PD0/CAN0RX 10
PD1/CAN0TX 11
PD2 12
PD3 13
PD4/CCP3 95
PD5 96
PD6/FAULT 99
PD7/C0o 100
GND9
GND15
GND21
GND33
RST64
LDO 7
MOSCin48
MOSCout49
PB0/CCP0 66
PB1/CCP2 67
PB2/I2C0SCL 70
PB3/I2C0SDA 71
PB4/C0- 92
PB5/C1- 91
PB6/C0+ 90
PB7/TRST 89
PE072
PE173
nc74
nc75
nc6 nc5
PA6/CCP134
nc35
nc2 nc1
PF0/PWM0 47
PF1/PWM1 61
PF2 60
nc 59
nc 58
nc 46
nc 43
nc 42
PG0 19
PG1 18
nc 17
nc 16
nc 41
nc 40
nc 37
nc 36
PH0 86
PH1 85
nc 84
nc 83
AVDD 3
AVDD 98
AGND97 AGND4
VDD33 8
VDD33 20
VDD33 32
VDD33 44
VDD33 56
VDD33 68
VDD33 81
VDD33 93
GND39
GND45
GND54
GND57
GND63
GND69
GND82
GND87
GND94 VDD25 14
VDD25 38
VDD25 62
VDD25 88
WAKE50
HIB51
OSC32in52
OSC32out53
VBAT 55
CMOD065
CMOD176
U100
LM3S2110
VOUT 4
SENSE 5VIN26
GND2
NC 3
GND 7
VIN11U102
LP8345ILD-3.3
Schematic page 4
A B C D E F G H
A B C D E F G H
1
2
3
4
5
6
7
8
1
2
3
4
5
6
7
8
I102
I100C
D QI96
I105
I104
I36
I35
I18AB
S
I89AB
S I85AB
S
I17AB
S
I10633
I8644
I221
I10738
I707
I4231
I9034
I347
I646
I9232
I1624
I10816
I1326
I159
I7414
I9110
I745
I373
I54
I448
I87
41
I8
40I9
I99
I111
I112
I95
I109
I20
FTDI_DBG
DBGOUTVCP_TX ITCK
SWO_EN
FTDI_TCK XTCK
FTDI_TDI_DO U0TX
XTDOFTDI_TDO_DI
JTAGEN
FTDI_TMS
XTDIJTAGEN
FTDI_DBG
FTDIJTAGEN SWDEN
FTDI_SRSTnXTMS
FTDI_DBG DBGOUT DBGLED
INTDBG TEST
TRSTn
RSTSWMCURSTn
RC
EXTCABLEn
HIBn DRVENAUG 23, 2007JTAG Logic with Auto Mode Detect and Hibernate
Texas Instruments, Inc.LM3S8962 Evaluation Kit
Schematic page 5
February 9, 2010 29
Connection DetailsThis appendix contains the following sections:
Component Locations (see page 30)
Evaluation Board Dimensions (see page 31)
I/O Breakout Pads (see page 32)
LM3S2110 CAN Device Board Connections (see page 33)
Recommended Connectors (see page 33)
ARM Target Pinout (see page 34)
References (see page 35)
A P P E N D I X B
30 February 9, 2010
Component LocationsFigure B-1. LM3S8962 Evaluation Board Component Locations
Stellaris® LM3S8962 Evaluation Board
February 9, 2010 31
Evaluation Board DimensionsFigure B-2. LM3S8962 Evaluation Board Dimensions
Figure B-3. LM3S2110 CAN Device Board Dimensions
32 February 9, 2010
I/O Breakout PadsThe LM3S8962 EVB has 42 I/O pads, 14 power pads, 2 crystal connections, and 2 no-connects, for a total of 60 pads. Connection can be made by soldering wires directly to these pads, or by using 0.1" pitch headers and sockets.
Note: In Table B-2, an asterisk (*) by a signal name (also on the EVB PCB) indicates the signal is normally used for on-board functions. Normally, you should cut the associated jumper (JP1-15) before using an assigned signal for external interfacing.
Table B-1. I/O Breakout Pads
Description Pad No. Description Pad
No. Description Pad No.
GND 1 GND 21 PC3/TDO 41
PA7* 2 ADC3 22 GND 42
PA6/CCP1* 3 ADC2 23 PE2/PhB1* 43
PA5/SSI0TX* 4 ADC1 24 PE3/PhA1* 44
PA4/SSI0RX* 5 ADC0 25 PE0/PWM4* 45
PA3/SSI0FSS* 6 GND 26 PE1/PWM5* 46
PA2/SSI0CLK* 7 PD7/IDX0 27 PB2/I2C0SCL 47
PA1/U0TX* 8 PD6/FAULT 28 PB3/I2C0SDA 48
PA0/U0RX* 9 PD5 29 PB1/PWM3 49
GND 10 PD4/CCP0 30 GND 50
PC4/PHA0 11 +15V 31 PF1/IDX1* 51
+3.3V 12 No connect 32 PB0/PWM2 52
PC5 13 +5V 33 PF3/LED0* 53
PC6/PHB0 14 GND 34 PF2/LED1* 54
PC7 15 PB4/C0- 35 GND 55
PG0* 16 GND 36 OSC32OUT 56
PG1/PWM1* 17 PB6/C0+ 37 GND 57
PD3/U1TX 18 PB5/C0O 38 OSC32IN 58
PD2/U1RX 19 PC2/TDI 39 PF0/PWM0* 59
No connect 20 PB7/TRST 40 +3.3V 60
Stellaris® LM3S8962 Evaluation Board
February 9, 2010 33
LM3S2110 CAN Device Board Connections
Recommended ConnectorsConnection can be made by soldering wires directly to pads or using 0.1” pitch headers and sockets.
Table B-2. Recommended Connectors
Pins 1-30, 31-60 (2 x 15 way)
PCB Socket Sullins PPPC152LFBN-RC Digikey S7118-ND
Cable Socket 3M 89130-0101 Digikey MKC30A-ND
Pin Header Sullins PEC15DAAN Digikey S2011E-15-ND
PC
3 (7
7)nc
(75)
PE
1 (7
3)nc
(74)
PB
3 (7
1)P
E0
(72)
PB
1 (6
7)P
B2
(70)
PF1
*(61
)P
B0
(66)
GN
DP
F2*(
60)
nc (
59)
nc (5
8)X
OSC
1X
OS
C0
GN
D+3
.3V
+5V
BU
S+5
V
PA
1 (2
7)PA
0 (2
6)P
C4
(25)
PC
5 (2
4)P
G6
(23)
PC
7 (2
2)P
G0
(19)
PG
1 (1
8)nc
(17)
nc (1
6)P
D3
(13)
PD
2 (1
2)nc
(6)
nc (5
)nc
(2)
nc (1
)G
ND
+3.3
V
PC2 (78)nc (83)
nc (84)PH1 (85)PH0 (86)PB7*(89)
PB6 (90)GNDPB4 (92)
PB5 (91)PD5 (96)
PD4 (95)PD6 (99)PD7 (100 ) PA2 (28)
PA3 (29) PA4 (30)PA5 (31)
PA6 (34)nc (35) nc (37)nc (40) nc (41)nc (42)
nc (43)nc (46) PF0*(47)GND
12
1718
19 20
31 32
3334
5152
5354
6566
34 February 9, 2010
ARM Target PinoutIn ICDI input and output mode, the Stellaris LM3S8962 Evaluation Kit supports ARM’s standard 20-pin JTAG/SWD configuration. The same pin configuration can be used for debugging over serial-wire debug (SWD) and JTAG interfaces. The debugger software, running on the PC, determines which interface protocol is used.
The Stellaris target board should have a 2x10 0.1” pin header with signals as indicated in Table B-3. This applies to both an external Stellaris microcontroller target (Debug Output mode) and to external JTAG/SWD debuggers (Debug Input mode).
ICDI does not control RST (device reset) or TRST (test reset) signals. Both reset functions are implemented as commands over JTAG/SWD, so these signals are not necessary.
It is recommended that connections be made to all GND pins; however, both targets and external debug interfaces must connect pin 18 and at least one other GND pin to GND.
Table B-3. 20-Pin JTAG/SWD Configuration
Function Pin Pin Function
VCC (optional) 1 2 nc
nc 3 4 GND
TDI 5 6 GND
TMS 7 8 GND
TCK 9 10 GND
nc 11 12 GND
TDO 13 14 GND
nc 15 16 GND
nc 17 18 GND
nc 19 20 GND
Stellaris® LM3S8962 Evaluation Board
February 9, 2010 35
ReferencesIn addition to this document, the following references are included on the Stellaris LM3S8962 Evaluation Kit CD-ROM and are also available for download at www.ti.com/stellaris:
Stellaris LM3S8962 Evaluation Kit Quickstart Guide for appropriate tool kit (see “Evaluation Kit Contents,” on page 12)
Stellaris LM3S8962 Evaluation Kit Read Me First
StellarisWare® Driver Library
StellarisWare® Driver Library User’s Manual, publication SW-DRL-UG
Stellaris LM3S8962 Data Sheet, publication DS-LM3S8962
Stellaris LM3S2110 Data Sheet, publication DS-LM3S2110
Additional references include:
RiT Display Corporation RGS13128096WH000 OLED Display Data Sheet
Future Technology Devices Incorporated FT2232D Data Sheet
Information on development tool being used:
– RealView MDK web site, www.keil.com/arm/rvmdkkit.asp
– IAR Embedded Workbench web site, www.iar.com
– Code Sourcery GCC development tools web site,www.codesourcery.com/gnu_toolchains/arm
– Code Red Technologies development tools web site, www.code-red-tech.com
– Texas Instruments’ Code Composer Studio™ IDE web site, www.ti.com/ccs
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Following are URLs where you can obtain information on other Texas Instruments products and application solutions:
Products Applications
Amplifiers amplifier.ti.com Audio www.ti.com/audio
Data Converters dataconverter.ti.com Automotive www.ti.com/automotive
DLP® Products www.dlp.com Communications and www.ti.com/communicationsTelecom
DSP dsp.ti.com Computers and www.ti.com/computersPeripherals
Clocks and Timers www.ti.com/clocks Consumer Electronics www.ti.com/consumer-apps
Interface interface.ti.com Energy www.ti.com/energy
Logic logic.ti.com Industrial www.ti.com/industrial
Power Mgmt power.ti.com Medical www.ti.com/medical
Microcontrollers microcontroller.ti.com Security www.ti.com/security
RFID www.ti-rfid.com Space, Avionics & www.ti.com/space-avionics-defenseDefense
RF/IF and ZigBee® Solutions www.ti.com/lprf Video and Imaging www.ti.com/video
Wireless www.ti.com/wireless-apps
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