LAUNCHXL-F28379D Overview User Guide Datasheet by Texas Instruments

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LAUNCHXL-F28379D Overview
User's Guide
SPRUI77CAugust 2016Revised March 2019
LAUNCHXL-F28379D Overview
The C2000™ LAUNCHXL-F28379D LaunchPad™ is a complete low-cost development board for the
Texas Instruments Delfino™ F2837xD devices. The LAUNCHXL-F28379D kit features all the hardware
and software necessary to develop applications based on the F2837xD microcontrollers. This LaunchPad
is based on the superset F28379D device, and easily allows users to migrate to lower feature set and/or
lower pin count F2837x devices once the design needs are known. It offers an on-board JTAG debug tool
allowing direct interface to a PC for easy programming, debugging, and evaluation. In addition to JTAG
emulation, the USB interface provides a UART serial connection from the F28379D device to the host PC.
Contents
1 Introduction ................................................................................................................... 2
2 Kit Contents................................................................................................................... 3
3 Installation .................................................................................................................... 4
4 Getting Started With the LAUNCHXL-F28379D ......................................................................... 5
5 Hardware Configuration..................................................................................................... 5
6 LAUNCHXL-F28379D Hardware .......................................................................................... 8
7 References.................................................................................................................. 26
8 Frequently Asked Questions (FAQ)...................................................................................... 27
List of Figures
1 LAUNCHXL-F28379D Board Overview................................................................................... 3
2 P01_Block Diagram........................................................................................................ 10
3 P02_XDS100v2............................................................................................................. 11
4 P03_Power.................................................................................................................. 12
5 P04_ADCIND ............................................................................................................... 13
6 P05_PWM-DAC ............................................................................................................ 13
7 P06_BoosterPack Headers ............................................................................................... 14
8 P07_F28379D-PWR ....................................................................................................... 14
9 P08_F28379D-IO1 ......................................................................................................... 15
10 P09_F28379_IO2 .......................................................................................................... 16
11 P10_EX-Headers........................................................................................................... 17
12 Top ........................................................................................................................... 18
13 GND.......................................................................................................................... 18
14 Route1 ....................................................................................................................... 18
15 Route2 ....................................................................................................................... 18
16 VDD .......................................................................................................................... 18
17 Bottom ....................................................................................................................... 18
18 Top Silkscreen Overlay.................................................................................................... 18
19 Bottom Silkscreen Overlay................................................................................................ 18
20 Top Pad Master ............................................................................................................ 19
21 Bottom Pad Master ........................................................................................................ 19
22 ................................................................................................................................ 28
List of Tables
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LAUNCHXL-F28379D Overview
1 Supplying the LaunchPad With 3.3 V..................................................................................... 6
2 Supplying the LaunchPad With 5 V ....................................................................................... 6
3 Positions of Signals Present on Switch S1............................................................................... 7
4 Revision 2.0: Resistor Selection for Routing Dual-Mapped Signals .................................................. 7
5 F28379D LaunchPad Pin Out and Pin Mux Options - J1, J3.......................................................... 8
6 F28379D LaunchPad Pin Out and Pin Mux Options - J4, J2.......................................................... 8
7 F28379D LaunchPad Pin Out and Pin Mux Options - J5, J7.......................................................... 9
8 F28379D LaunchPad Pin Out and Pin Mux Options - J8, J6.......................................................... 9
9 LAUNCHXL-F28379D Bill of Materials .................................................................................. 20
Trademarks
C2000, LaunchPad, Delfino, Code Composer Studio are trademarks of Texas Instruments.
Windows is a registered trademark of Microsoft Corporation in the United States and/or other countries.
All other trademarks are the property of their respective owners.
1 Introduction
Users can download an unrestricted copy of the latest version of Code Composer Studio™ IDE to write,
download, and debug applications on the LAUNCHXL-F28379D board. The debugger is unobtrusive,
allowing the user to run an application at full speed with hardware breakpoints and available single step
execution while consuming no extra hardware resources.
As shown in Figure 1, the LAUNCHXL-F28379D LaunchPad features include:
USB debugging and programming interface via a high-speed galvanically isolated XDS100v2 debug
probe featuring a USB/UART connection
Superset TMS320F28379D device
Two user LEDs
Device reset pushbutton
Easily accessible device pins for debugging purposes or as sockets for adding customized extension
boards
Dual 5 V quadrature encoder interfaces
CAN Interface with integrated transceiver
Boot selection switches
Differential Amplifier to provide buffered signals to ADCD for 16-bit mode
Optional SMA connection points P/N:SMA-J-P-H-ST-EM1
Four Sigma Delta demodulator inputs brought to the BP headers
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{
{
{
{
XDS100v2 On-Board
Debug Probe
Enables JTAG debugging/
programming as well as provides serial
communication back to the PC. The XDS100
can also provide power to the target MCU.
40-pin BoosterPack Connectors
(J1, J2, J3, and J4)
ADC-D Differential Pair Inputs
(J21)
Optional SMA Jacks
(J19 and J20)
Power Jumpers
(JP4 and JP5)
High-density EMIF Connector
(Bottom)(J9)
On-Board 5V Enable Jumper
(JP3)
CAN Interface w/ Transceiver
(J12)
Dual 5V Quadrature Interfaces
(J14 and J15)
40-pin BoosterPack Connectors
(J5, J6, J7, and J8)
TMS320F28379D
Microcontroller
(U1)
Reset
(S3)
Boot Configuration Switches
(S1)
Power & User LEDs
(D1, D9, and D10)
Electrically Isolated PC Interface
When power to the F28379D device is
supplied externally through the
BoosterPack headers, JP1, JP2, and JP3
may be removed to enable electrical
isolation of the board from the PC.
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LAUNCHXL-F28379D Overview
Figure 1. LAUNCHXL-F28379D Board Overview
2 Kit Contents
The LAUNCHXL-F28379D LaunchPad kit includes the following items:
C2000 Delfino LaunchPad Board (LAUNCHXL-F28379D)
Mini USB-B Cable, 0.5m
Quick Start Guide
2.1 Revisions
The first production revision of the LAUNCHXL-F28379D in 2016 was Revision 1.1. In late 2017 the
LAUNCHXL-F28379D revision changed from 1.1 to 2.0 to fix various issues and make improvements to
the design.
All Revisions:
Resistor R7 in the oscillator circuit is incorrectly placed or should not be installed. This resistor may
impact startup time or robustness of the clocking circuit over the full operating range of the MCU or
different physical layouts of this circuit. The probability is low that this resistor will have any impact on
the functionality of this EVM as is not intended to be operated outside of Standard Temperature and
Pressure in a lab or prototype environment. Do not use this circuit as reference. Follow the
requirements for the Oscillator schematic as documented in the MCU Datasheet.
The SCIA pins routed to the XDS100 v2 are not valid SCI boot mode pins. In addition, the other boot-
able SCI pins are not routed to any external connector. In other words, this LaunchPad is not capable
of using the Boot to SCI boot mode. The TMDSCNCD28379D can be used to evaluate this feature.
Revision 1.1:
ADCINA2 is shorted to VREFHIB. It is recommended that users avoid using the ADCINA2 channel.
The VIN+ signal of component U1 may be shorted to ADCINB4 and/or ADCINC4 due to variance in
manufacturing tolerances. No issues have been reported, but the clearances violate manufacturing
rules and a short may occur.
The silkscreen for the ADC channels on J3 and J7 are mixed up and some may be incorrect.
Reference the schematic for the proper pin positions.
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J3 and J7 connectors are labeled incorrectly on the backside silkscreen. Refer the Rev 1.1 schematic
for the proper signal locations on the connector
Revision 2.0:
A revision was made to resolve the layout issues present on revisions 1.1. In addition to the fixes for
aforementioned issues, additional changes were made to the schematic and layout to improve available
features and increase usability.
User LEDs and current limiting resistor values were changed to prevent the LEDs from being too bright
to look at directly.
The CAN signal header J12 was shifted towards the center of the board and the silkscreen properly
aligned. PGND was removed and replaced with GND for the proper grounding of the CAN signals.
J11 and J13 were removed and replaced with a 0Ωresistor selection tree for routing between the
BoosterPack headers and the backside high-density connector J9. For more information on how to
configure these resistors for the desired routing, see Section 5.5.
Additional EMIF1 signals were routed to J9 to enable SDRAM support. These signals are also routed
to the BoosterPack headers. As such, these signals have a resistor selection network for routing the
signals to either the BoosterPack headers, J9 or both. For the information on how to configure these
resistors for the desired routing, see Section 5.5.
An additional jumper, J16, was added to the lower left corner of the board for an additional connection
point for supplying +5 V externally.
ADC input signal conditioning circuit was updated for proper operation under additional operating
conditions. C4 is now 180 pF; R60/R61 are changed to 10k-Ωand are placed between the VOUT
signal of U13 to the VOCM of U1.
Backside silkscreen for J3 and J7 have been corrected and reflect the proper signals at the noted
location on the connector.
3 Installation
The F28379D LaunchPad is supported in Code Composer Studio.
3.1 Code Composer Studio
3.1.1 Download the Required Software
Code Composer Studio IDE is available for free without any restriction when used with the XDS100v2
debug probe on the C2000 LaunchPad. The software can be downloaded from the C2000 LaunchPad
page at ti.com/launchpad. At this site, you can also download a copy of c2000Ware that includes drivers,
examples, and other support software needed to get started.
3.1.2 Install the Software
Once downloaded, install Code Composer Studio and the C2000Ware package.
3.1.3 Install the Hardware
After Code Composer Studio is installed, plug the supplied USB cable into the C2000 LaunchPad board
and into an available USB port on your computer.
Windows®will automatically detect the hardware and ask you to install software drivers. Let Windows run
a search for the drivers and automatically install them. After Windows successfully installs the drivers for
the integrated XDS100v2 debug probe, your LaunchPad is now ready for use.
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4 Getting Started With the LAUNCHXL-F28379D
4.1 Getting Started
The first time the LAUNCHXL-F28379D board is powered-on a demo application will automatically start.
Connect the LAUNCHXL-F28379D to a free USB port using the included mini-USB cable. The demo
application will start with LEDs D9 and D10 blinking to show the device is active. If your board does not
start the demo application, try setting switch S1 in the following positions and resetting the board: 1-UP, 2-
UP, 3-DOWN.
4.2 Demo Application, ADC Sampling
The LAUNCHXL-F28379D includes a pre-programmed TMS320F28379D device. When the LaunchPad is
powered via USB, the demo starts with an LED blink sequence. After a few seconds the device switches
into an ADC sample mode.
Every 1 second the ADC samples pin ADCIN14 and the sampled data is represented as follows: If the
sample is above mid-scale (2048), the blue LED D10 will illuminate. If the sample is below mid-scale, the
red LED D9 will illuminate.
In addition to the LED indicators, ADC sample information is also displayed on your PC through the
USB/UART connection. To view the UART information on your PC, first determine the COM port
associated with the LaunchPad. To do this in Windows, right click on My Computer and click on
Properties. In the dialog box that appears, click on the Hardware tab and open Device Manager. Look for
an entry under Ports (COM & LPT) titled "USB Serial Port (COMX)", where X is a number. Remember this
number for when you open a serial terminal. The demo applications UART data was written and debugged
using PuTTY, and for the best user experience we recommend you use PuTTY to view the UART data.
PuTTY can be downloaded from the following URL:
http://www.chiark.greenend.org.uk/~sgtatham/putty/download.html
Open your serial terminal program and open the COM port you found previously in device manager with
the following settings: 115200 Baud, 8 data bits, no parity, 1 stop bit. After opening the serial port in your
serial terminal, reset the LaunchPad with the reset push button S3 and observe the serial terminal to see
the TI logo in ASCII art.
4.3 Program and Debug the ADC Sample Demo Application
The project and associated source code for the C2000 Delfino LaunchPad demo is included in the
C2000Ware software package and should automatically be found by the TI Resource Explorer in Code
Composer Studio. In the resource explorer, navigate C2000Ware to find the
device_support\f2837xd\examples folder. Expand this item and LAUNCHXL-F28379D, then select the
LaunchPad Demo Application. Follow the steps in the main pane of the resource explorer to import, build,
debug, and run this application.
4.4 Using Other C2000Ware Examples
Including the LaunchPad demo example described above, C2000Ware provides many examples
demonstrating a majority of the features of the F2837x MCU. Most examples are configured by default to
use the TMDSCNDC28379D ControlCARD, which has a different on-board clocking circuit. As such, some
examples may not work as intended without minor modification. To make this easier on the designer,
compiler switch has been added to automatically pick the proper clock configuration based on adding
"_LAUNCHXL_F28379D" as a predefined symbol in the project properties. Refer to Section 8for more
information on how and where to define this symbol.
5 Hardware Configuration
The F28379D LaunchPad provides users with several options for configuring the board.
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5.1 ADC Resolution
The F28379D had 4 independent 16-bit/12-bit ADCs. The resolution of each ADC is SW selectable.
ADCA, ADCB, and ADCC are all routed to the BoosterPack headers for use with different booster packs.
Most BoosterPacks will use the ADC in 12-bit mode which supports Single Ended (SE) inputs. ADCD has
been routed to a special side connector with ability to drive through a differential amplifier to support 16-bit
mode with Differential Ended (DE) inputs.
5.2 Power Domain
The LaunchPad has several different power domains to enable JTAG Isolation. Jumpers JP1, JP2, JP3
control JTAG Isolation, supply GND, 3.3 V and 5 V to the rest of the board. There are also other jumpers
that provide different methods for powering the device.
Table 1 describes the different methods by which 3.3 V can be supplied to the device. It can be derived
from USB in configuration 1. Here, the on-board regulator steps the 5 V from the USB port down to 3.3 V
to be used by the XDS100v2 debug probe as well as connected to the device side of the LaunchPad
through JP1. Configuration 1 is a non-isolated configuration. Alternately, in configuration 2 the debugger
and USB connection are isolated from the device. The 3.3 V source must be provided externally through
the BoosterPack headers or through J10.
Table 1. Supplying the LaunchPad With 3.3 V
Configuration JP1 JP2 USB External 3.3 V JTAG/USB
Isolation Status
1 Yes Yes Yes No Not Isolated
2 No No Don't Care Yes Isolated
The LaunchPad also has a 5 V power rail. It can be supplied directly from the USB (not isolated)
generated from a 3.3 V to 5 V step-up regulator through JP6, or supplied externally through the
BoosterPack Headers or J16. Table 2 describes these various configurations.
The debug probe and USB are not isolated in configuration 1 since JP2 and JP3 are connected. The 5 V
supply is coming from the USB directly to the device side of the LaunchPad and can be used to power
other devices connected to the BoosterPack headers. In this configuration, do not connect JP6 as there
may be contention between the 5 V from the USB (JP3) and the 5 V from the on-board step-up regulator,
U12.
Configuration 2 is an isolated configuration where 3.3 V is supplied any way other than through JP1. In
this configuration, JP6 is connected allowing the 3.3 V to be stepped up to 5 V with the on-board step-up
regulator, U12. In this configuration ensure that no other 5 V source is connected to the BoosterPack
headers or through J16.
Configuration 3 is another isolated configuration since JP2 and JP3 are not connected. With JP6
disconnected, 5 V must be supplied through an external connection on the BoosterPack headers or J16.
Notice that this configuration does not rely on the 3.3 V supply being powered to provide the 5 V. To
supply 3.3 V to the device in an isolated configuration, see Table 1.
Table 2. Supplying the LaunchPad With 5 V
Configuration JP2 JP3 JP6 External 5 V USB JTAG/USB
Isolation Status
1 Yes Yes No No Yes Not Isolated
2 No No Yes No Don't Care Isolated
3 No No No Yes Don't Care Isolated
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5.3 Boot Mode Selection
The LaunchPad's F28379D device includes a boot ROM that performs some basic start-up checks and
allows for the device to boot in many different ways. Most users will either want to perform an emulation
boot or a boot to flash (if they are running the application standalone). Switch S1 has been provided to
allow users to easily configure the pins that the bootROM checks to make this decision. The positions on
S1 correspond to those shown in Table 3.
Table 3. Positions of Signals Present on Switch S1
Positions Function
1 GPIO84
2 GPIO72
3 TRSTn
Keep in mind that the debug probe does not connect if the device is not in the emulation boot mode
(TRST switch in the UP-1 position). More information about boot mode selection can be found in the Boot
ROM section of the TMS320F2837xD Dual-Core Delfino Microcontrollers Technical Reference Manual.
5.4 Connecting a BoosterPack
The F2837xD LaunchPad is the perfect experimenter board to start hardware development with the
F2837xD devices. All of the connectors are aligned in a 0.1-in (2.54-mm) grid to allow easy and
inexpensive development of add on boards called BoosterPacks. These satellite boards can access all of
the GPIO and analog signals. The pinout of the connectors can be found in Section 5.
5.5 GPIO Routing Between BoosterPack and I/O Expansion Headers
This LaunchPad has a high-density connector (J9) on the backside of the board. This connector provides
for an IO expansion board to be connected. Many of the EMIF1 signals are available as well as SPI and
I2C. Some of the signals present on J9 are also available on the BoosterPack expansion headers.
On Revision 1.x LaunchPads, only two signals were dual-mapped to both J9 and the BoosterPack
Headers, GPIO40 and GPIO41. To select the destination, the three-position jumpers, J11 and J13, could
be adjusted accordingly. Placing the jumper between position 1 and position 2 will route the signal to J9.
Placing the jumper between position 2 and position 3 will route the signal to the BoosterPack headers.
On revision 2.0 LaunchPads, in addition to GPIO40 and GPIO41, four more signals may be routed to
either the BoosterPack headers or J9 independently, or may be connected to both based on the
placement of 0Ωresistors. By default, the signals are only routed to the BoosterPack headers for
alignment with the BoosterPack standards. Table 4 provides the mapping for each signal and which
resistors populate in order to route the signal as desired. Refer to the schematic at the end of this
document in Section 6.2,or located in the C2000Ware directory.
Table 4. Revision 2.0: Resistor Selection for Routing Dual-Mapped Signals
GPIO Route to BoosterPack Headers Route to J9 Header
GPIO29 R75 R76
GPIO40 R67 R68
GPIO41 R69 R70
GPIO52 R77 R78
GPIO104 R71 R72
GPIO105 R73 R74
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6 LAUNCHXL-F28379D Hardware
6.1 Device Pin Out
Table 5 through Table 8 lists the pin out and pin mux options for the C2000 LaunchPad. Additional muxing
options are available and can be found in the TMS320F2837xD Dual-Core Delfino™ Microcontrollers Data
Manual.
(1) For full pin muxing table for functions shown here and additional mux options, see the TMS320F2837xD Dual-Core Delfino™
Microcontrollers Data Manual.
(2) This signal is also routed to the IO expansion header, J9. For information on how to configure this signal, see Section 5.5.
Table 5. F28379D LaunchPad Pin Out and Pin Mux Options - J1, J3
Mux Value J1
Pin J3
Pin
Mux Value
X 2 1 0 0 Alt Function 2 X
3.3V 1 21 5V
GPIO32 2 22 GND
SCIRXDB GPIO19 3 23 ADCIN14 CMPIN4P
SCITXDB GPIO18 4 24 ADCINC3 CMPIN6N
GPIO67 5 25 ADCINB3 CMPIN3N
GPIO111 6 26 ADCINA3 CMPIN1N
SPICLKA(1) GPIO60 7 27 ADCINC2 CMPIN6P
GPIO22 8 28 ADCINB2 CMPIN3P
SCLA GPIO105(2) 9 29 ADCINA2 CMPIN1P
SDAA GPIO104(2) 10 30 ADCINA0 DACOUTA
(1) For full pin muxing table for functions shown here and additional mux options, see the TMS320F2837xD Dual-Core Delfino™
Microcontrollers Data Manual.
(2) This signal is also routed to the IO expansion header, J9. For information on how to configure this signal, see Section 5.5.
Table 6. F28379D LaunchPad Pin Out and Pin Mux Options - J4, J2
Mux Value J4
Pin J2
Pin
Mux Value
X 2 1 0 0 1 2 X
EPWM1A GPIO0 40 20 GND
EPWM1B GPIO1 39 19 GPIO61
EPWM2A GPIO2 38 18 GPIO123 SD1_C1(1)
EPWM2B GPIO3 37 17 GPIO122 SD1_D1(1)
EPWM3A GPIO4 36 16 RST
EPWM3B GPIO5 35 15 GPIO58 SPISIMOA(1)
OUTPUTXBAR1 GPIO24 34 14 GPIO59 SPISOMIA(1)
OUTPUTXBAR7(1) GPIO16 33 13 GPIO124 SD1_D2(1)
DAC1 32 12 GPIO125 SD1_C2(1)
DAC2 31 11 GPIO29(2) OUTPUTXBAR6(1)
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(1) For full pin muxing table for functions shown here and additional mux options, see the TMS320F2837xD Dual-Core Delfino™
Microcontrollers Data Manual.
(2) This signal is also routed to the IO expansion header, J9. For information on how to configure this signal, see Section 5.5.
Table 7. F28379D LaunchPad Pin Out and Pin Mux Options - J5, J7
Mux Value J5
Pin J7
Pin
Mux Value
X 2 1 0 0 Alt Function 2 X
3.3V 41 61 5V
GPIO95 42 62 GND
SCIRXDC(1) GPIO139 43 63 ADCIN15 CMPIN4N
SCITXDC(1) GPIO56 44 64 ADCINC5 CMPIN5N
GPIO97 45 65 ADCINB5
GPIO94 46 66 ADCINA5 CMPIN2N
SPICLKB(1) GPIO65 47 67 ADCINC4 CMPIN5P
GPIO52(2) 48 68 ADCINB4
SCLB(1) GPIO41(2) 49 69 ADCINA4 CMPIN2P
SDAB(1) GPIO40(2) 50 70 ADCINA1 DACOUTB
(1) For full pin muxing table for functions shown here and additional mux options, see the TMS320F2837xD Dual-Core Delfino™
Microcontrollers Data Manual.
Table 8. F28379D LaunchPad Pin Out and Pin Mux Options - J8, J6
Mux Value J8
Pin J6
Pin
Mux Value
X 2 1 0 0 1 2 X
EPWM4A GPIO6 80 60 GND
EPWM4B GPIO7 79 59 GPIO66
EPWM5A GPIO8 78 58 GPIO131 SD2_C1(1)
EPWM5B GPIO9 77 57 GPIO130 SD2_D1(1)
EPWM6A GPIO10 76 56 RST
EPWM6B GPIO11 75 55 GPIO63 SPISIMOB(1)
OUTPUTXBAR3(1) GPIO14 74 54 GPIO64 SPISOMIB(1)
OUTPUTXBAR4(1) GPIO15 73 53 GPIO26 SD2_D2(1)
DAC3 72 52 GPIO27 SD2_C2(1)
DAC4 71 51 GPIO25 OUTPUTXBAR2(1)
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Power management
Micro USB type B
FT2232H
TMS320F28379D-NFBGA
BoosterPack 1 Connector
LEDS
CAN
SERIAL 1&2
Sheet 2
Sheet 3
Sheet 7
Sheet 2
BoosterPack 2 Connector
QEP Connector
Note: NI = Not Install
Sheet 10
Sheet 6
Sheet 6
Sheet 10
Sheet 5
REV DATA NOTE
REV1.0 20151210 ORIGINAL RELEASED
DF40C-60DP-0.4V
Sheet 7
REV1.1 20160415
-Changed value for R11/R52 from 560m to 100m
-Swap pin connection for J3&J7
-Replace U19&U11 with OPA350
-Changed value for R38/R39 from 330R to 820R
REV2.0 20170426
-Add 5V connector J16
-Changed R1/R26/R27/R38/R39/R46 from 820R to 680R
-Replace D1/D4 with 150080VS75000
-Replace D7/D10 with 150080BS75000
-Replace D8/D9 with 150080SS75000
-Changed C40 from 1nF to 180pF
-Changed "PGND" to "GND" in CAN connector J12
-Changed GPIO29/40/41/52/104/105 route in page 9
-Connect U13.6 to U1.2
-Changed R60/R61 from 4K02 to 10K
-Add R79 connect U2.8 to GND
-Add C84/C85
-Changed C23/C38 from 2.2uf to 22uf
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6.2 Schematics
The following figures show the LAUNCHXL-F28379D Rev 2.0 schematic. The schematics for both
LAUNCHXL-F28379D Revision 2.0 and Revision 1.1 are located in C2000Ware.
Figure 2. P01_Block Diagram
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Mini USB
2K2
1%
R31
100nF
C16
93LC56BT-I/OT
6
2
CLK
4
DO 1
DI
3
CS
5
U8
FT2232HQ-REEL
VREGIN
50
USBDM
7
USBDP
8
REF
6
RESET#
14
OSCI
2
OSCO
3
EECS
63
EECLK
62
EEDATA
61
TEST
13
AGND
10
GND1
1
GND2
5
GND3
11
GND4
15
PWREN# 60
SUSPEND# 36
BCBUS3 54
BCBUS2 53
BCBUS1 52
BCBUS0 48
BDBUS7 46
BDBUS6 45
BDBUS5 44
BDBUS4 43
BDBUS3 41
BDBUS2 40
BDBUS1 39
BDBUS0 38
ACBUS3 29
ACBUS2 28
ACBUS1 27
ACBUS0 26
ADBUS7 24
ADBUS6 23
ADBUS5 22
ADBUS4 21
ADBUS3 19
ADBUS2 18
ADBUS1 17
ADBUS0 16
VCCIO1 20
VCORE2 37
VCORE1 12
VPHY 4
ACBUS4 30
ACBUS5 32
ACBUS6 33
ACBUS7 34
BCBUS4 55
BCBUS5 57
BCBUS6 58
BCBUS7 59
GND5
25
GND6
35
GND7
47
GND8
51
VREGOUT
49
VPLL 9
VCORE3 64
VCCIO2 31
VCCIO3 42
VCCIO4 56
TH
65
U6
100nF
C14
100nF
C13
100nF
C12
12K
1%
R24
1K
1%
R22
ISO7231CDWR
VCC1 1
VCC2
16
GND1 2
GND1 8
GND2
15
GND2
9
INA 3
INB 4
OUTC 5
NC1 6
EN1 7
EN2
10
OUTA
14
OUTB
13
INC
12
NC2
11
U7
ISO7240CDWR
VCC1
1VCC2 16
GND1
2
GND1
8
GND2 15
GND2 9
INA
3
INB
4
INC
5
IND
6
NC
7EN 10
OUTA 14
OUTB 13
OUTC 12
OUTD 11
U5
1K
1%
R23
BLUE
D7
RED
D8
680R
1%
R26
680R
1%
R27
12MHZ
Q3
36pF
5%
C17
36pF
5%
C18
0R
5%
NI
R21
0R 5%
NI R20
0R 5%
NI R19
0R 5%
NI R18
0R 5%
NI R16
0R 5%
NI R28
0R 5%
NI R30
0R 5%
NI R32
0R
5%
NI
R25
2.54mm 1x2
1 2
JP1
2.54mm 1x2
1 2
JP2
4.7uF
C10 4.7uFC11
600R
300mA
L2
600R
300mA
L1
0R 5%
R15
0R 5%
R33
TP11
TP12
TP13
TP14 TP15 TP16 TP17
100nF
C43
GREEN
D4
680R
1%
R46
TP30
TPS62162DSGT
EN
3
EX_PAD
9
FB 5
GND
4
PG 8
PGND
1
SW 7
VIN
2
VOS 6
U17
100K 1%
R47
2.2uH
L7
10K
1%
R12
2.54mm 1x2
1 2
JP3
1
2
3
4
5
CON1
AGND
AGND
AGND
AGND
AGND GND
GND
AGND
+3V3
+3V3
AGND
AGND AGND
AGND
AGND AGNDAGND
AGND
AGND
+5V
AGNDAGNDAGNDAGND
+3V3
D-
D-
D+
D+
XUSB
TCK
TDI
TDO
TMS
FTDI_CS
FTDI_CS
FTDI_CLK
FTDI_CLK
FTDI_DATA
FTDI_DATA
PWREN#
SUSPEND#
JTAG_TRST
GPIO42/SCIATX(<-MCU)
GPIO43/SCIARX(->MCU)
USBVCC
FTDI_3V3
USBVCC
USBVCC
FTDI_3V3
FTDI_3V3
FTDI_3V3
FTDI_3V3
FTDI_3V3
FTDI_3V3
FTDI_1V8
FTDI_1V8
AGND
10uF
C44
22uF
C45
3.3uF
C15
500mA
F1
Copyright © 2016, Texas Instruments Incorporated
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Figure 3. P02_XDS100v2
i TEXAS INSTRUMENTS T iLiiLiiLii H >—HJ r—Uifl >—Hi; >—Hi a \ Cupyngm. 2017, Texas msuumems Incurpuremd
2.2uF
C42
2.2uF
C46
2.2uF
C47
2.2uF
C48
2.2uF
C49
2.2uF
C75
2.2uF
C76
2.2uF
C77
2.2uF
C78
10uF
C79
178K
1%
R53
64.9K
1%
R5439K2
1%
R55
220R
L11
10uF
C81
100nF
C56
100nF
C57
100nF
C58
100nF
C59
100nF
C60
100nF
C61
100nF
C62
100nF
C63
100nF
C64
100nF
C65
100nF
C66
100nF
C67
220R
L5
10uF
C68
10uF
C69
60RL3
2.2uF
C27
2.2uF
C29
100nF
C28
100nF
C30
60R
L4
2.2uF
C71
2.2uF
C72
100nF
C73
100nF
C74
100nF
C1
2.2uF
C2
100nF
C5
1K
1%
R3
1uF
C6
1uF
C7
100nF
C9
1uF
C19 0.1R
1%
R11
0.1R
1%
R52
820pF
C25
LMR62421XMFE/NOPB
FB 3
GND
2
SD
4
SWITCH 1
VIN
5
U12
10K
1%
R14
3.3uH
L6
10uF
C41
30K1
1%
R17
10K
1%
R45
4.7uF
C8
1uF
C22
2.54mm 1x2
1 2
JP6 OPA350EA/250
+IN
3
-IN
2
NC1
1
NC2 5
NC3 8
OUT 6
V+ 7
V-
4
U11
OPA350EA/250
+IN
3
-IN
2
NC1
1
NC2 5
NC3 8
OUT 6
V+ 7
V-
4
U19
REF5030IDGKT
DNC1
1DNC2 8
GND
4
NC 7
TEMP
3
TRIM/NR 5
VIN
2
VOUT 6
U13
10uF
C70
GND
+3V3
GND GND GND
GND
+3V3
GND
+3V3
GND GND
+3V3
GND GND
GND
GND
GND GND
GND
GND
GND
GND
+3V3
GNDGND
+5V
GND
+5V
+5V
GND
GND
+5V
+3V3
VREFHIA
VREFHIB
VDDIO
VDDOSC VDDA
VDD+1V2
GND
22uF
C80
1uH
L8
1N5819HW-7-F
D3
VREF
TPS62080ADSGT
EN
1
FB 4
GND
2MODE
3
PG 6
SW 7
VIN
8
VOS 5
PAD
9
U4
22uF
C23
22uF
C38
Copyright © 2017, Texas Instruments Incorporated
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Figure 4. P03_Power
l TEXAS INSTRUMENTS W >—0— fl 2 Raw Cupyngm © 2017‘ Texas \nskuments \ncorpuraied filzt +% Cupyngm @ 2017, Texas Insuumems Incurpura|ed
PWM_DAC
RED
D9
BLUE
D10
SN74LVC2G07DBVR
1A
1
2A
32Y 4
1Y 6
VCC 5
GND
2
U9
680R
1%
R38
680R
1%
R39
1K 1%
R36
1K 1%
R37
1K 1%
R40
1K 1%
R41
100nF
C33
100nF
C34
100nF
C35
100nF
C36
100nF
C24
+3V3 +3V3 +3V3
GND
GND GND GND GND
GND
GPIO34
PWM/BASED/DAC1
PWM/BASED/DAC2
PWM/BASED/DAC3
PWM/BASED/DAC4
GPIO157
GPIO158
GPIO31
GPIO159
GPIO160
Copyright © 2017, Texas Instruments Incorporated
TP21
TP22
TP23
TP24
2K
1%
R56 2K
1%
R57 12R
5%
R58
49R9
1%
R59
49R9
1%
R62
2K
1%
R63 2K
1%
R64 12R
5%
R65
THS4531IDGKR
PD 7
VIN+ 8
VIN-
1
VOCM
2
VOUT+
4VOUT- 5
VS+
3VS- 6
U1
GND
GND GND
GND
+3V3
GND
GND
+3V3
GNDGND
GND
ADCIND5
ADCIND4
ADCIND0
ADCIND1
ADCIND2
ADCIND3
180pF
C40
220nF
C83
100pF
C20
100pF
C82
1uF
C21
2.54mm 2x4
1 2
3 4
5 6
7 8
J21
VREF
SMA-J-P-H-ST-EM1
NI
J19
SMA-J-P-H-ST-EM1
NI
J20
10K
1%
R60
10K
1%
R61
VOCM
Copyright © 2017, Texas Instruments Incorporated
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LAUNCHXL-F28379D Overview
Figure 5. P04_ADCIND
Figure 6. P05_PWM-DAC
l TEXAS INSTRUMENTS Cnpynghl © 2017, Texas Ins|mmems Incorporated : L m fii cnpyngm© 2017, Texas |ns|mmenls Incorporated
RESET GPIO72 GPIO84TRST
1
0 00
0
0
0
x x
0
1
1
1
1
0
Emulation Boot
Parallel I/O
SCI
Wait
GetMode
BOOT
10MHZ
Q1
36pF
5%
C4
36pF
5%
C3
1M
1%
R7
2K2
1%
R6
GREEN
D1
680R
1%
R1
TP1
100nF
C39
B3F-3152
1 2
S3
2K2
1%
R8
2K2
1%
R9
219-3MST
4
5
6 1
2
3
S1
2K2
1%
R10
GND
GND
+3V3
GND
GND
+3V3
GND
+3V3
GND
+3V3+3V3
GNDGNDGND
GND
GND
VREFHIB
VREFHIA
RESET#
RESET#
X1
X1
X2
X2
TCK
TDI
TDO
TMS
TRST
TRST
NC
FLT2
FLT1
ERRORSTS
JTAG_TRST
GPIO72
GPIO84
TMS320F28379DZWTT
ERRORSTS U19
FLT1 W12
FLT2 V13
NC H4
VDDIO25 B1
VDDIO26 F13
VDDIO27 F16
VDDIO28 L14
VDDOSC1 H16
VDDOSC2 H17
VSS1
A1
VSS2
A10
VSS3
A19
VSS4
E5
VSS5
E6
VSS6
E8
VSS7
E12
VSS8
E14
VSS9
E15
VSS10
F5
VSS11
F6
VSS12
F8
VSS13
F12
VSS14
F14
VSS15
F15
VSS16
G16
VSS17
G17
VSS18
H8
VSS19
H9
VSS20
H10
VSS21
H11
VSS22
H12
VSS23
H14
VSS24
H15
VSS25
J5
VSS26
J6
VSS27
J8
VSS28
J9
VSS29
J10
VSS30
J11
VSS31
J12
VSS32
K8
VSS33
K9
VSS34
K10
VSS35
K11
VSS36
K12
VSS37
K14
VSS38
K15
VSS39
L5
VSS40
L6
VSS41
L8
VSS42
L9
VSS43
L10
VSS44
L11
VSS45
L12
VSS46
L18
VSS47 M8
VSS48 M9
VSS49 M10
VSS50 M11
VSS51 M12
VSS52 M14
VSS53 M15
VSS54 N1
VSS55 N5
VSS56 N6
VSS57 P8
VSS58 P11
VSS59 P12
VSS60 P14
VSS61 P15
VSS62 R7
VSS63 R8
VSS64 R14
VSS65 R15
VSS66 W1
VSS67 W7
VSS68 W19
VSSA1 P1
VSSA2 P5
VSSA3 R5
VSSA4 V7
VSSA5 P7
VSSOSC1 H18
VSSOSC2 H19
U14A
TMS320F28379DZWTT
TCK V15
TDI W13
TDO W15
TMS W14
TRST V14
VDD1
E9
VDD2
F9
VDD3
K5
VDD3VFL1
R11
VDD3VFL2
R12
VDD4
E11
VDD5
F11
VDD6
G14
VDD7
G15
VDD8
J14
VDD9
J15
VDD10
K6
VDD11
R10
VDD12
R13
VDD13
P10
VDD14
P13
VDDA1
R6
VDDA2
P6
VDDIO1
A9
VDDIO2
A18
VDDIO3
E7
VDDIO4
E10
VDDIO5
E13
VDDIO6
E16
VDDIO7
F4
VDDIO8
F7
VDDIO9
F10
VDDIO10
G4
VDDIO11
G5
VDDIO12
G6
VDDIO13
H5
VDDIO14
H6
VDDIO15
L15
VDDIO16
M1
VDDIO17
M5
VDDIO18
M6
VDDIO19
N14
VDDIO20
N15
VDDIO21
P9
VDDIO22
R9
VDDIO23
V19
VDDIO24
W8
VREFHIA V1
VREFHIB W5
VREFHIC R1
VREFHID V5
VREFLOA R2
VREFLOB V6
VREFLOC P2
VREFLOD W6
VREGENZ J18
X1 G19
X2 J19
XRS F19
U14B
VDDIO
VDDIO
VDDIO
VDDOSC
VSSOSC
VSSOSC
VDDA
VDD
820R
1%
R5
820R
1%
R4
0R
5%
NI
R66
100nF
C84
100nF
C85
GND
+3V3
Copyright © 2017, Texas Instruments Incorporated
2.54mm 1x2
1 2
JP4
2.54mm 1x2
1 2
JP5
+3V3
GND
GND
+5V
GND GND
+3V3 +5V
RESET#
RESET#
GPIO61/SPIACS
GPIO5/PWMOUT3B
GPIO2/PWMOUT2A
GPIO3/PWMOUT2B
GPIO32
ADCINC3/ANALOGIN
ADCINA3/ANALOGIN
ADCINB3/ANALOGIN
ADCIN15/ANALOGIN
GPIO64/SPIBMISO
GPIO139/SCICRX(->MCU)
GPIO125/SD1CLK2PWM/BASED/DAC1
PWM/BASED/DAC2
PWM/BASED/DAC4
ADCIN14/ANALOGIN
GPIO60/SPICLKA
GPIO26/SD2D2
GPIO27/SD2CLK2
GPIO4/PWMOUT3A
GPIO65/SPIBCLK
ADCINA2/ANALOGIN
GPIO67
GPIO29/OPXBAR6
GPIO105/I2CSCLA/J1
GPIO104/I2CSDAA/J1
GPIO124/SD1D2
GPIO122/SD1D1
GPIO123/SD1CLK1
ADCINA0/ANALOGIN(DACA)
GPIO24/OPXBAR1
GPIO1/PWMOUT1B
GPIO0/PWMOUT1A
GPIO16/OPXBAR7ADCINB2/ANALOGIN
GPIO95
GPIO56/SCICIX(<-MCU)
GPIO97
GPIO94
GPIO52/J5
GPIO25/OPXBAR2
GPIO63/SPIBMOSI
GPIO66/SPIBCS
ADCINB4/ANALOGIN
ADCINC4/ANALOGIN
ADCINB5/ANALOGIN
ADCINC5/ANALOGIN
ADCINA1/ANALOGIN(DACB)
GPIO15/OPXBAR4
GPIO7/PWMOUT4B
GPIO6/PWMOUT4A
GPIO22
GPIO111
PWM/BASED/DAC3ADCINA4/ANALOGIN
ADCINA5/ANALOGIN
ADCINC2/ANALOGIN
GPIO8/PWMOUT5A
GPIO9/PWMOUT5B
GPIO58/SPIAMOSI
GPIO59/SPIAMISO
GPIO11/PWMOUT6B
GPIO10/PWMOUT6A
GPIO14/OPXBAR3
GPIO130/SD2D1
GPIO131/SD2CLK1
GPIO40/I2CSDAB/J5
GPIO41/I2CSCLB/J5
GPIO18
GPIO19
1
2
3
4
5
6
7
8
9
10
J1
1
2
3
4
5
6
7
8
9
10
J3
1
2
3
4
5
6
7
8
9
10
J2
1
2
3
4
5
6
7
8
9
10
J4
+3V3
Analog In
UART RX(->MCU)
UART TX(<-MCU)
GPIO(!)
SPI Clk
I2C SCL
I2C SDA
Analog In
GPIO(!)
+5V
Analog In/I2S WS
Analog In/I2S CLK
Analog Out/I2S DO
Analog Out/I2S DI
Analog In
Analog In
Analog In
Analog In
GND
GPIO(!)
GPIO(!)
GPIO(!)
GPIO(!)
Timer Capture
Timer Capture
PWM Out
PWM Out
PWM Out
PWM Out GND
GPIO(!)/PWM
GPIO(!)/SPI CS
GPIO
Reset
SPI MOSI
SPI MISO
GPIO(!)/SPI CS
GPIO(!)/SPI CS
GPIO(!)
1
2
3
4
5
6
7
8
9
10
J5
1
2
3
4
5
6
7
8
9
10
J7
+3V3
Analog In
GPIO(!)
SPI Clk
I2C SCL
I2C SDA
Analog In
GPIO(!)
UART TX(<-MCU)
UART RX(->MCU)
+5V
Analog In/I2S WS
Analog In/I2S CLK
Analog Out/I2S DO
Analog Out/I2S DI
Analog In
Analog In
Analog In
Analog In
GND
1
2
3
4
5
6
7
8
9
10
J8
1
2
3
4
5
6
7
8
9
10
J6
GPIO(!)
GPIO(!)
GPIO(!)
GPIO(!)
PWM Out
PWM Out
PWM Out
PWM Out
Timer Capture
Timer Capture
GND
GPIO(!)/PWM
GPIO(!)/SPI CS
GPIO
Reset
SPI MOSI
SPI MISO
GPIO(!)/SPI CS
GPIO(!)/SPI CS
GPIO(!)
Copyright © 2017, Texas Instruments Incorporated
LAUNCHXL-F28379D Hardware
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LAUNCHXL-F28379D Overview
Figure 7. P06_BoosterPack Headers
Figure 8. P07_F28379D-PWR
l TEXAS INSTRUMENTS
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LAUNCHXL-F28379D Overview
Figure 9. P08_F28379D-IO1
l TEXAS INSTRUMENTS Copyright © 2017, Texas Instrumems Incnrpcrmed
DF40C-60DP-0.4V(51)
A0 2
A1
3A2 4
A3
5A4 6
A5
7A6 8
A7
9
A8
11 A9 12
A10
13 A11 14
A12
15 A13 16
A14
17 A15 18
BUSY 50
CSN
43
D0
21 D1 22
D2
23 D3 24
D4
25 D5 26
D6/SPI_INT
27 D7 28
D8 34
D9
35 D10 36
D11
37 D12 38
D13
39 D14 40
D15
41
E2PROM_LOAD 20
EMIF_INT
49
ETRESETN 60
GND1
1
GND2 10
GND3
19
GND4
29
GND5 42
GND6
51
I2C-SCL 54
I2C-SDA
55
NRD 44
NWR
45 RSVD1 46
RSVD2 58
RSVD3
59
SPI_CLK
31 SPI_SEL 30
SPI_SIMOA 32
SPI_SOMIA
33
SYNC/LATCH0
47 SYNC/LATCH1 48
VCC33A 52
VCC33B
53
VCC33C 56
VCC33D
57
J9
TMS320F28379DZWTT
ADCIN14/CMPIN4P
T4 ADCIN15/CMPIN4N
U4 ADCINA0/DACOUTA
U1 ADCINA1/DACOUTB
T1 ADCINA2/CMPIN1P
U2 ADCINA3/CMPIN1N
T2 ADCINA4/CMPIN2P
U3 ADCINA5/CMPIN2N
T3 ADCINB0/VDAC
V2 ADCINB1/DACOUTC
W2 ADCINB2/CMPIN3P
V3 ADCINB3/CMPIN3N
W3 ADCINB4
V4 ADCINB5
W4 ADCINC2/CMPIN6P
R3 ADCINC3/CMPIN6N
P3 ADCINC4/CMPIN5P
R4 ADCINC5/CMPIN5N
P4 ADCIND0/CMPIN7P
T5 ADCIND1/CMPIN7N
U5 ADCIND2/CMPIN8P
T6 ADCIND3/CMPIN8N
U6 ADCIND4
T7 ADCIND5
U7
GPIO0/EPWM1A/SDAA
C8 GPIO1/EPWM1B/MFSRB/SCLA
D8 GPIO2/EPWM2A/OUTPUTXBAR1/SDAB
A7 GPIO3/EPWM2B/OUTPUTXBAR2/MCLKRB/OUTPUTXBAR2/SCLB
B7 GPIO4/EPWM3A/OUTPUTXBAR3/CANTXA
C7 GPIO5/EPWM3B/MFSRA/OUTPUTXBAR3/CANRXA
D7 GPIO6/EPWM4A/OUTPUTXBAR4/EXTSYNCOUT/EQEP3A/CANTXB
A6 GPIO7/EPWM4B/MCLKRA/OUTPUTXBAR5/EQEP3B/CANRXB
B6 GPIO8/EPWM5A/CANTXB/ADCSOCAO/EQEP3S/SCITXDA
G2 GPIO9/EPWM5B/SCITXDB/OUTPUTXBAR6/EQEP3I/SCIRXDA
G3 GPIO10/EPWM6A/CANRXB/ADCSOCBO/EQEP1A/SCITXDB/UPP-WAIT
B2 GPIO11/EPWM6B/SCIRXDB/OUTPUTXBAR7/EQEP1B/UPP-START
C1 GPIO12/EPWM7A/CANTXB/MDXB/EQEP1S/SCITXDC/UPP-ENA
C2
GPIO13/EPWM7B/CANRXB/MDRB/EQEP1I/SCIRXDC/UPP-D7 D1
GPIO14/EPWM8A/SCITXDB/MCLKXB/OUTPUTXBAR3/UPP-D6 D2
GPIO15/EPWM8B/SCIRXDB/MFSXB/OUTPUTXBAR4/UPP-D5 D3
GPIO16/SPISIMOA/CANTXB/OUTPUTXBAR7/EPWM9A/SD1_D1/UPP-D4 E1
GPIO17/SPISOMIA/CANRXB/OUTPUTXBAR8/EPWM9B/SD1_C1/UPP-D3 E2
GPIO18/SPICLKA/SCITXDB/CANRXA/EPWM10A/SD1_D2/UPP-D2 E3
GPIO19/SPISTEA/SCIRXDB/CANTXA/EPWM10B/SD1_C2/UPP-D1 E4
GPIO20/EQEP1A/MDXA/CANTXB/EPWM11A/SD1_D3/UPP-D0 F2
GPIO21/EQEP1B/MDRA/CANRXB/EPWM11B/SD1_C3/UPP-CLK F3
GPIO22/EQEP1S/MCLKXA/SCITXDB/EPWM12A/SPICLKB/SD1_D4 J4
GPIO23/EQEP1I/MFSXA/SCIRXDB/EPWM12B/SPISTEB/SD1_C4 K4
GPIO24/OUTPUTXBAR1/EQEP2A/MDXB/SPISIMOB/SD2_D1 K3
GPIO25/OUTPUTXBAR2/EQEP2B/MDRB/SPISOMIB/SD2_C1 K2
GPIO26/OUTPUTXBAR3/EQEP2I/MCLKXB/OUTPUTXBAR3/SPICLKB/SD2_D2 K1
GPIO27/OUTPUTXBAR4/EQEP2S/MFSXB/OUTPUTXBAR4/SPISTEB/SD2_C2 L1
GPIO28/SCIRXDA/EM1CS4/OUTPUTXBAR5/EQEP3A/SD2_D3 V11
GPIO29/SCITXDA/EM1SDCKE/OUTPUTXBAR6/EQEP3B/SD2_C3 W11
GPIO30/CANRXA/EM1CLK/OUTPUTXBAR7/EQEP3S/SD2_D4 T11
GPIO31/CANTXA/EM1WE/OUTPUTXBAR8/EQEP3I/SD2_C4 U11
GPIO32/SDAA/EM1CS0 U13
GPIO33/SCLA/EM1RNW T13
GPIO34/OUTPUTXBAR1/EM1CS2/SDAB U14
GPIO35/SCIRXDA/EM1CS3/SCLB T14
GPIO36/SCITXDA/EM1WAIT/CANRXA V16
GPIO37/OUTPUTXBAR2/EM1OE/CANTXA U16
GPIO38/EM1A0/SCITXDC/CANTXB T16
GPIO39/EM1A1/SCIRXDC/CANRXB W17
GPIO40/EM1A2/SDAB V17
GPIO41/EM1A3/SCLB U17
GPIO42/SDAA/SCITXDA/USB0DM D19
GPIO43/SCLA/SCIRXDA/USB0DP C19
GPIO44/EM1A4 K18
GPIO45/EM1A5 K19
GPIO46/EM1A6/SCIRXDD E19
GPIO47/EM1A7/SCITXDD E18
GPIO48/OUTPUTXBAR3/EM1A8/SCITXDA/SD1_D1 R16
GPIO49/OUTPUTXBAR4/EM1A9/SCIRXDA/SD1_C1 R17
GPIO50/EQEP1A/EM1A10/SPISIMOC/SD1_D2 R18
GPIO51/EQEP1B/EM1A11/SPISOMIC/SD1_C2 R19
U14D
+3V3
+3V3
GND
GPIO93
GPIO92
GPIO69
GPIO70GPIO71
GPIO72GPIO73
GPIO74GPIO75
GPIO76
GPIO77GPIO78
GPIO79GPIO80
GPIO81GPIO82
GPIO83GPIO85
GPIO86 GPIO87
GPIO88 GPIO89
GPIO100
GPIO101
GPIO102
GPIO103
GPIO105/I2CSCLA/J9
GPIO107
GPIO108
GPIO104/I2CSDAA/J9
GPIO29/J9
GPIO51
GPIO51
GPIO50
GPIO50
GPIO49
GPIO49
GPIO48
GPIO48
GPIO46
GPIO46
GPIO45
GPIO45
GPIO44
GPIO44
GPIO41/I2CSCLB
GPIO41/I2CSCLB
GPIO40/I2CSDAB
GPIO40/I2CSDAB
GPIO39
GPIO39
GPIO38
GPIO38
GPIO37
GPIO37
GPIO36
GPIO36
GPIO52/J9
GPIO33
GPIO32
GPIO32
GPIO31
GPIO31
GPIO30
GPIO30
GPIO34
GPIO34
GPIO47
GPIO47
GPIO43/SCIARX(->MCU)
GPIO42/SCIATX(<-MCU)
GPIO35
GPIO29
GPIO28
GPIO27/SD2CLK2
GPIO14/OPXBAR3
GPIO25/OPXBAR2
GPIO24/OPXBAR1
GPIO23
GPIO22
GPIO21
GPIO20
GPIO19
GPIO18
GPIO16/OPXBAR7
GPIO15/OPXBAR4
GPIO13
GPIO12
GPIO7/PWMOUT4B
GPIO6/PWMOUT4A
GPIO5/PWMOUT3B
GPIO4/PWMOUT3A
GPIO3/PWMOUT2B
GPIO2/PWMOUT2A
GPIO1/PWMOUT1B
GPIO0/PWMOUT1A
ADCIND5
ADCIND4
ADCIND3
ADCIND2
ADCIND1
ADCIND0
ADCINC5/ANALOGIN
ADCINC4/ANALOGIN
ADCINC3/ANALOGIN
ADCINC2/ANALOGIN
ADCINB5/ANALOGIN
ADCINB4/ANALOGIN
ADCINB3/ANALOGIN
ADCINB2/ANALOGIN
ADCINB0
ADCINA5/ANALOGIN
ADCINA4/ANALOGIN
ADCINA3/ANALOGIN
ADCINA2/ANALOGIN
ADCINA1/ANALOGIN(DACB)
ADCINA0/ANALOGIN(DACA)
ADCIN15/ANALOGIN
ADCIN14/ANALOGIN
ADCINB1
GPIO8/PWMOUT5A
GPIO9/PWMOUT5B
GPIO11/PWMOUT6B
GPIO10/PWMOUT6A
GPIO26/SD2D2
GPIO41/I2CSCLB/J9
GPIO41/I2CSCLB/J9 GPIO41/I2CSCLB/J5
GPIO40/I2CSDAB/J9
GPIO40/I2CSDAB/J9
GPIO40/I2CSDAB/J5
GPIO17
0R 5%R67
0R 5%
NI
R68
0R 5%
NI
R70
0R 5%
R69
GPIO105/I2CSCLA
GPIO104/I2CSDAA
GPIO105/I2CSCLA/J9
GPIO105/I2CSCLA/J1
GPIO104/I2CSDAA/J9
GPIO104/I2CSDAA/J1 0R 5%R71
0R 5%
NI
R72
0R 5%
NI
R74
0R 5%
R73
GPIO52
GPIO29
GPIO52/J9
GPIO52/J5
GPIO29/J9
GPIO29/OPXBAR6 0R 5%R75
0R 5%
NI
R76
0R 5%
NI
R78
0R 5%
R77
Copyright © 2017, Texas Instruments Incorporated
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LAUNCHXL-F28379D Overview
Figure 10. P09_F28379_IO2
l TEXAS INSTRUMENTS 44% V—\ H» 44 V—\ >—» I Cupyngm 2017‘ Texas msmmems \ncurpuranzd
CAN
LEVEL SHIFT
A
B
I
GND
PWR
J14
J15
A
B
I
GND
PWR
TXB0106PWR
A1 1
A2 3
A3 4
A4 5
A5 6
A6 7
B1
16
B2
14
B3
13
B4
12
B5
11
B6
10
GND
9OE 8
VCCA 2
VCCB
15
U2
2K2
1%
R2
SN65HVD234DR
CANH 7
CANL 6
D
1
EN
5
GND
2
R
4
RS
8
VCC 3
U3
120R
1%
R34
2.54mm 1x3
1
2
3
J12
10K
1%
R35
10K
1%
R42
0R 5%
R43
0R 5%
R44
100nF
C31
100nF
C32
100nF
C37
2.54mm 1x3
1
2
3
J10
2.54mm 1x5
1
2
3
4
5
QEP_A
2.54mm 1x5
1
2
3
4
5
QEP_B
1K
1%
R13
1K
1%
R29
1K
1%
R48
1K
1%
R49
1K
1%
R50
1K
1%
R51
+5V +3V3
GND
+3V3
GNDGND
GND
GND
GND
GND
+3V3
GND
+5V
+5V
GND
GND
GND
GND
+3V3
+5V
+5V
GPIO55
GPIO99
GPIO20EQEP1A
EQEP1A
EQEP1B
EQEP1B
EQEP1I
EQEP1I
EQEP2A
EQEP2A
EQEP2B
EQEP2B
EQEP2I
EQEP2I
CANH
CANL
GPIO54
GPIO12
GPIO17
GPIO21
GPIO57
1nF
C50
1nF
C51
1nF
C52
1nF
C53
1nF
C54
1nF
C55
2.54mm 1x3
1
2
3
J16
GND
+5V
0R
5%
NI
R79
GND
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LAUNCHXL-F28379D Overview
Figure 11. P10_EX-Headers
l TEXAS INSTRUMENTS
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LAUNCHXL-F28379D Overview
6.3 PCB Layout
Figure 12 through Figure 21 show the LAUNCHXL-F28379D Rev 2.0 PCB layout. The gerber files and
PCB layout for both LAUNCHXL-F28379D Revision 2.0 and Revision 1.1 can be found in C2000Ware.
Figure 12. Top Figure 13. GND
Figure 14. Route1 Figure 15. Route2
Figure 16. VDD Figure 17. Bottom
Figure 18. Top Silkscreen Overlay Figure 19. Bottom Silkscreen Overlay
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LAUNCHXL-F28379D Overview
Figure 20. Top Pad Master Figure 21. Bottom Pad Master
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LAUNCHXL-F28379D Overview
6.4 Bill of Materials (BOM)
Table 9 lists the LAUNCHXL-F28379D bill of materials.
Table 9. LAUNCHXL-F28379D Bill of Materials
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
1 PCB LAUNCHXL-
F28379D PCB
rev2.0
1 PCB 6 layers,red
soldermask,wihte
silkscreen,130*59mm,
ENIG,Launchxl-F28379D
Rev2.0 pcb
2 MCU TMS320F28379DZ
WTT 1 U14 Texas
Instruments IC, MCU 32BIT
1024KB,TMS320F28379
DZWTT,
BGA-337,SMD,customer
supply
YES Lead Free Reach
Not
Affected
Jun-2016 Non-Stock IC MCU 32BIT 1MB
FLASH 337NFBGA TMS320F28379DZ
WTT TMS320F28379DZ
WTT-ND
3 Memory 93LC56BT-I/OT 1 U8 Microchip
Technology IC,EEPROM Serial-
Microwire 2K-Bit 128 x
16 2MHz,93LC56BT-
I/OT,SOT-23-6,SMD
YES Lead Free Reach
Not
Affected
Jan-2017 Active IC EEPROM 2KBIT
2MHZ SOT23-6 93LC56BT-I/OT 93LC56BT-I/OTCT-
ND
4 Power
Management REF5030IDGKT 1 U13 Texas
Instruments IC ?V-Ref Precision 3V
10mA 8-Pin VSSOP T/R YES Lead Free Reach
Not
Affected
Jun-2016 Active IC VREF SERIES 3V
8VSSOP REF5030IDGKT 296-24501-1-ND
5 DC-DC LMR62421XMFE/N
OPB 1 U12 Texas
Instruments Conv DC-DC Single Step
Up 2.7V to 5.5V 5-Pin
SOT-23 T/R
,CUSTOMER SUPPLY
YES Lead Free Reach
Not
Affected
Jun-2016 Active IC REG BST SEPIC
ADJ 2.1A SOT23 LMR62421XMFE/
NOPB LMR62421XMFE/N
OPBCT-ND
6 DC-DC TPS62080ADSGT 1 U4 Texas
Instruments IC REG BUCK SYNC
ADJ 1.2A 8WSON YES Lead Free Reach
Not
Affected
Jun-2016 Active IC REG BUCK ADJ
1.2A SYNC 8WSON TPS62080ADSGT 296-30360-1-ND
7 DC-DC TPS62162DSGT 1 U17 Texas
Instruments IC REG BUCK SYNC
3.3V 1A 8WSON YES Lead Free Reach
Not
Affected
Jun-2016 Active IC REG BUCK 3.3V
1A SYNC 8WSON TPS62162DSGT 296-29897-1-ND
8 Amplifier THS4531IDGKR 1 U1 Texas
Instruments IC OPAMP DIFF 27MHZ
RRO 8VSSOP TR YES Lead Free Reach
Not
Affected
Jun-2016 Active IC OPAMP DIFF
27MHZ RRO 8VSSOP THS4531IDGKR 296-30342-1-ND
9 Amplifier OPA350EA/250 2 U11,U19 Texas
Instruments IC OPAMP GP 38MHZ
RRO 8VSSOP T/R YES Lead Free Reach
Not
Affected
Jun-2016 Active IC OPAMP GP
38MHZ RRO 8VSSOP OPA350EA/250 OPA350EACT-ND
10 Logic TXB0106PWR 1 U2 Texas
Instruments IC, 6-bit bidirectional
voltage-level translator
with auto-direction
sensing and ±15-kV ESD
protection,
TXB0106PWR, TSSOP-
16, SMD,Cusomer
Supply
YES Lead Free Reach
Not
Affected
Jun-2016 Active IC 6BIT NON-INV
TRANSLTR 16TSSOP TXB0106PWR 296-23759-1-ND
11 Logic SN74LVC2G07DBV
R1 U9 Texas
Instruments Buffer/Driver 2-CH Non-
Inverting Open Drain
CMOS 6-Pin SOT-23
T/R,CUSTOMER
SUPPLY
YES Lead Free Reach
Not
Affected
Jun-2016 Active IC BUFF/DVR DL
NON-INV SOT23-6 SN74LVC2G07DBV
R296-13494-1-ND
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LAUNCHXL-F28379D Overview
Table 9. LAUNCHXL-F28379D Bill of Materials (continued)
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
12 Interface FT2232HQ-REEL 1 U6 FTDI, Future
Technology
Devices
International Ltd
IC,Dual High Speed USB
to Multipurpose
UART/FIFO
IC,FT2232HQ-
REEL,QFN-64,SMD
YES Lead Free Reach
Not
Affected
Jan-2017 Active IC USB HS DUAL
UART/FIFO 64-QFN FT2232HQ-REEL 768-1025-1-ND
13 Interface SN65HVD234DR 1 U3 Texas
Instruments IC CAN transceiver 3.3V
8-SOIC YES Lead Free Reach
Not
Affected
Jun-2016 Active IC CAN
TRANSCEIVER 3.3V
8-SOIC
SN65HVD234DR 296-27991-1-ND
14 Isolator ISO7231CDWR 1 U7 Texas
Instruments IC DGTL ISO 3CH
CMOS
16SOIC,CUSTOMER
SUPPLY
YES Lead Free Reach
Not
Affected
Jun-2016 Active DGTL ISO 2.5KV
GEN PURP 16SOIC ISO7231CDWR 296-38966-1-ND
15 Isolator ISO7240CDWR 1 U5 Texas
Instruments IC DGTL ISO 4CH
CMOS
16SOIC,CUSTOMER
SUPPLY
YES Lead Free Reach
Not
Affected
Jun-2016 Active DGTL ISO 2.5KV
GEN PURP 16SOIC ISO7240CDWR 296-38555-1-ND
16 Thick film
Resistor RC0402JR-070RL 4 R15, R33,
R43, R44 Yageo RES,0R,±5%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Dec-2015 Active RES SMD 0.0Ω
JUMPER 1/16W 0402 RC0402JR-070RL 311-0.0JRCT-ND
17 Thick film
Resistor RC0402FR-
0749R9L 2 R59, R62 Yageo RES,49R9,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 49.9 Ω1%
1/16W 0402 RC0402FR-
0749R9L 311-49.9LRCT-ND
18 Thick film
Resistor RC0402FR-071KL 13 R3,R13,
R22, R23,
R29, R36,
R37, R40,
R41, R48,
R49, R50,
R51
Yageo RES,1K,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 1K Ω1%
1/16W 0402 RC0402FR-071KL 311-1.00KLRCT-ND
19 Thick film
Resistor RC0402FR-072KL 4 R56, R57,
R63, R64 Yageo RES,2K,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 2K Ω1%
1/16W 0402 RC0402FR-072KL 311-2KLRCT-ND
20 Thick film
Resistor RC0402FR-072K2L 6 R2, R6,
R8, R9,
R10, R31
Yageo RES,2K2,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 2.2K Ω1%
1/16W 0402 RC0402FR-072K2L 311-2.20KLRCT-ND
21 Thick film
Resistor RC0402FR-0710KL 7 R12, R14,
R35, R42,
R45,R60,
R61
Yageo RES,10K,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 10K Ω1%
1/16W 0402 RC0402FR-0710KL 311-10.0KLRCT-ND
22 Thick film
Resistor RC0402FR-0712KL 1 R24 Yageo RES,12K,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 12K Ω1%
1/16W 0402 RC0402FR-0712KL 311-12.0KLRCT-ND
23 Thick film
Resistor RC0402FR-
0730K1L 1 R17 Yageo RES,30K1,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 30.1K Ω
1% 1/16W 0402 RC0402FR-
0730K1L 311-30.1KLRCT-ND
24 Thick film
Resistor RC0402FR-
0739K2L 1 R55 Yageo RES,39K2,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 39.2K Ω
1% 1/16W 0402 RC0402FR-
0739K2L 311-39.2KLRCT-ND
25 Thick film
Resistor RC0402FR-
07100KL 1 R47 Yageo RES,100K,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 100K Ω1%
1/16W 0402 RC0402FR-
07100KL 311-100KLRCT-ND
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LAUNCHXL-F28379D Overview
Table 9. LAUNCHXL-F28379D Bill of Materials (continued)
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
26 Thick film
Resistor RC0402FR-071ML 1 R7 Yageo RES,1M,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 1M Ω1%
1/16W 0402 RC0402FR-071ML 311-1.00MLRCT-
ND
27 Thick film
Resistor RC0603JR-070RL 6 R67,R69,
R71,R73,
R75,R77
Yageo RES,0R,±5%,1/10W,
SMD0603 YES Lead Free Reach
Not
Affected
Dec-2015 Active RES SMD 0.0Ω
JUMPER 1/10W 0603 RC0603JR-070RL 311-0.0GRCT-ND
28 Thick film
Resistor RL0603FR-070R1L 2 R11,R52 Yageo RES,0R1,±1%,1/10W,
SMD0603 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 0.1 Ω1%
1/10W 0603 RL0603FR-070R1L 311-.10QCT-ND
29 Thick film
Resistor RC0603FR-
07120RL 1 R34 Yageo RES,120R,±1%,1/10W,
SMD0603 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 120 Ω1%
1/10W 0603 RC0603FR-
07120RL 311-120HRCT-ND
30 Thick film
Resistor RC0402FR-
07820RL 2 R4, R5 Yageo RES,820R,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 820 Ω1%
1/16W 0402 RC0402FR-
07820RL 311-820LRCT-ND
31 Thick film
Resistor RC0402FR-
07680RL 6 R1,R26,R
27,R38,R
39, R46
Yageo RES,680R,±1%,1/16W,
SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 680 Ω1%
1/16W 0402 RC0402FR-
07680RL 311-680LRCT-ND
32 Thick film
Resistor ERJ-2RKF1783X 1 R53 Panasonic
Electronic
Components
RES, 178K Ω, 1%,
1/10W, SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 178K Ω1%
1/10W 0402 ERJ-2RKF1783X P178KLCT-ND
33 Thick film
Resistor ERJ-2RKF6492X 1 R54 Panasonic
Electronic
Components
RES, 64.9K Ω, 1%,
1/10W, SMD0402 YES Lead Free Reach
Not
Affected
Jan-2017 Active RES SMD 64.9K Ω
1% 1/10W 0402 ERJ-2RKF6492X P64.9KLCT-ND
34 Thick film
Resistor CRCW040212R0JN
ED 2 R58, R65 Vishay Dale RES SMD 12 Ω5%
1/16W 0402 TR YES Lead Free Reach
Not
Affected
Dec-2015 Active RES SMD 12 Ω5%
1/16W 0402 CRCW040212R0JN
ED 541-12JCT-ND
35 Ceramic
Capacitor GRM1555C1H101J
A01D 2 C20, C82 Murata
Electronics North
America
CAP,100PF,±5%,C0G,
50V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 100PF 50V
C0G/NP0 0402 GRM1555C1H101J
A01D 490-5922-1-ND
36 Ceramic
Capacitor GRM1555C1H181J
A01D 1 C40 Murata
Electronics North
America
CAP,180PF,±5%,C0G,
50V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 180PF 50V
C0G/NP0 0402 GRM1555C1H181J
A01D 490-3231-1-ND
37 Ceramic
Capacitor GRM1555C1H821J
A01D 1 C25 Murata
Electronics North
America
CAP,820PF,±5%,C0G,
50V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 820PF 50V
C0G/NP0 0402 GRM1555C1H821J
A01D 490-3242-1-ND
38 Ceramic
Capacitor GRM155R71H102K
A01D 6 C50, C51,
C52, C53,
C54, C55
Murata
Electronics North
America
CAP,1NF,±10%,X7R,
50V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 1000PF
50V X7R 0402 GRM155R71H102K
A01D 490-1303-1-ND
39 Ceramic
Capacitor GRM155R61A224K
E19D 1 C83 Murata
Electronics North
America
CAP,220NF,±10%,X5R,
10V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 0.22UF 10V
X5R 0402 GRM155R61A224K
E19D 490-3910-1-ND
40 Ceramic
Capacitor GRM155R60J105K
E19D 5 C6, C7,
C19,
C21,C22
Murata
Electronics North
America
CAP,1UF,±10%,X5R,6.3
V,SMD0402 ?suffix J
stand for 330mm reel ?
YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 1UF 6.3V
X5R 0402 GRM155R60J105K
E19D 490-1320-1-ND
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Table 9. LAUNCHXL-F28379D Bill of Materials (continued)
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
41 Ceramic
Capacitor GRM155R60J225M
E15D 14 C2, C27,
C29, C42,
C46, C47,
C48, C49,
C71, C72,
C75, C76,
C77, C78
Murata
Electronics North
America
CAP,2.2UF,±20%,X5R,
6.3V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 2.2µF 6.3V
X5R 0402 GRM155R60J225M
E15D 490-4519-1-ND
42 Ceramic
Capacitor GRM188R60J106M
E47D 5 C68, C69,
C70, C79,
C81
Murata
Electronics North
America
CAP,10UF,±20%,X5R,
6.3V,SMD0603 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 10µF 6.3V
X5R 0603 GRM188R60J106M
E47D 490-3896-1-ND
43 Ceramic
Capacitor GRM188R60J226M
EA0D 3 C23,C38,
C80 Murata
Electronics North
America
CAP,22UF,±20%,X5R,
6.3V,SMD0603 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 22µF 6.3V
X5R 0603 GRM188R60J226M
EA0D 490-7611-1-ND
44 Ceramic
Capacitor GRM32DR71E106K
A12L 2 C41, C44 Murata
Electronics North
America
CAP,10UF,±10%,X7R,
25V,SMD1210 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 10µF 25V
X7R 1210 GRM32DR71E106K
A12L 490-1867-1-ND
45 Ceramic
Capacitor GRM155R61A104K
A01D 35 C1, C5,
C9, C12,
C13, C14,
C16, C24,
C28, C30,
C31, C32,
C33, C34,
C35, C36,
C37, C39,
C43, C56,
C57, C58,
C59, C60,
C61, C62,
C63, C64,
C65, C66,
C67, C73,
C74,C84,
C85
Murata
Electronics North
America
CAP,100NF(0.1uf),±10%
,X5R,10V,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 0.1µF 10V
X5R 0402 GRM155R61A104K
A01D 490-1318-1-ND
46 Ceramic
Capacitor GRM32ER61E226K
E15L 1 C45 Murata
Electronics North
America
CAP,22UF,±10%,X5R,
25V,SMD1210 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 22µF 25V
X5R 1210 GRM32ER61E226K
E15L 490-3889-1-ND
47 Ceramic
Capacitor GRM155R60J475M
E47D 3 C8, C10,
C11 Murata
Electronics North
America
CAP,4.7UF,±20%,X5R,
6.3V,SMD0402 fix PN
add D?20151023?
YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 4.7µF 6.3V
X5R 0402 GRM155R60J475M
E47D 490-5915-1-ND
48 Ceramic
Capacitor GRM188R61A335K
E15D 1 C15 Murata
Electronics North
America
CAP,3.3uF,±10%,X5R,
10V,SMD0603 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 3.3µF 10V
X5R 0603 GRM188R61A335K
E15D 490-6411-1-ND
49 Ceramic
Capacitor GRM1555C1H360J
A01D 4 C3,C4,C1
7,C18 Murata
Electronics North
America
CAP,36pF,±5%,C0G,50V
,SMD0402 YES Lead Free Reach
Not
Affected
Jun-2016 Active CAP CER 36PF 50V
C0G/NP0 0402 GRM1555C1H360J
A01D 490-5937-1-ND
50 Inductor LQH3NPN1R0NJ0L 1 L8 Murata
Electronics North
America
FIXED IND 1µH 1.62A
40 MΩSMD,±30% YES Lead Free Reach
Not
Affected
Jun-2016 Active FIXED IND 1µH 1.62A
40 MΩSMD LQH3NPN1R0NJ0L 490-5342-1-ND
51 Inductor CDRH2D18/HPNP-
2R2NC 1 L7 Sumida America
Components Inc. Power inductor,magnetic
shielded,2.2µH,1.6A,0.06
Ω,3.0X3.0X1.8mm,SMD
YES Lead Free Reach
Not
Affected
Jun-2016 Active FIXED IND 2.2µH
1.9A 60 MΩSMD CDRH2D18/HPNP-
2R2NC 308-2295-2-ND
l TEXAS INSTRUMENTS
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LAUNCHXL-F28379D Overview
Table 9. LAUNCHXL-F28379D Bill of Materials (continued)
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
52 Inductor CDRH3D16/HPNP-
3R3NC 1 L6 Sumida America
Components Inc. Power Inductor,Magnetic
shielded,3.3µH,1.4A,0.08
5Ω,3.8X3.8X1.6mm,SMD
YES Lead Free Reach
Not
Affected
Jun-2016 Non-Stock FIXED IND 3.3µH
1.8A 85 MΩSMD CDRH3D16/HPNP-
3R3NC 308-1981-1-ND
53 Ferrite Bead BLM15AG601SN1D 2 L1, L2 Murata
Electronics North
America
Ferrite
Bead,600Ω@100MHz,±2
5%,300mA,0.6Ω,SMD04
02
YES Lead Free Reach
Not
Affected
Jun-2016 Active FERRITE BEAD 600
Ω0402 1LN BLM15AG601SN1D 490-1006-1-ND
54 Ferrite Bead BLM15PD600SN1D 2 L3, L4 Murata
Electronics North
America
Ferrite
Bead,60Ω@100MHz,±25
%,1700mA,0.06Ω,SMD0
402
YES Lead Free Reach
Not
Affected
Jun-2016 Active FERRITE BEAD 60 Ω
0402 1LN BLM15PD600SN1D 490-5201-1-ND
55 Ferrite Bead BKP1005EM221-T 2 L5, L11 Taiyo Yuden FERRITE BEAD 220 Ω
0402,±25% YES Lead Free Reach
Not
Affected
Jun-2016 Active FERRITE BEAD 220
Ω0402 1LN BKP1005EM221-T 587-3290-1-ND
56 LED 150080VS75000 2 D1, D4 Wurth Electronics
Inc. LED, Bright GREEN ,
570nm,20mA,SMD,0805 YES Lead Free Reach
Not
Affected
Jan-2017 Active LED GREEN CLEAR
0805 SMD 150080VS75000 732-4986-1-ND
57 LED 150080BS75000 2 D7, D10 Wurth Electronics
Inc. LED, BLUE ,470NM,
20mA,SMD,0805 YES Lead Free Reach
Not
Affected
Jan-2017 Active LED BLUE CLEAR
0805 SMD 150080BS75000 732-4982-1-ND
58 LED 150080SS75000 2 D8, D9 Wurth Electronics
Inc. LED, SUPPER RED
,630NM,20mA,
SMD,0805
YES Lead Free Reach
Not
Affected
Jan-2017 Active LED RED CLEAR
0805 SMD 150080SS75000 732-4985-1-ND
59 Diode 1N5819HW-7-F 1 D3 Diodes
Incorporated Diode,Schottky
Diode,1N5819HW-7-
F,40V,1A,SOD-
123,SMD,-65~125,TR
YES Lead Free Reach
Not
Affected
Jan-2017 Active DIODE SCHOTTKY
40V 1A SOD123 1N5819HW-7-F 1N5819HW-FDICT-
ND
60 Polyswitch MF-MSMF050-2 1 F1 Bourns Inc. PTC RESETTABLE .50A
15V 1812 YES Lead Free Reach
Not
Affected
Jan-2017 Active PTC RESETTABLE
.50A 15V 1812 MF-MSMF050-2 MF-MSMF050-2CT-
ND
61 Crystal ABLS2-12.000MHZ-
D4Y-T 1 Q3 Abracon LLC Crystal 12MHz ±30ppm
(Tol) ±30ppm (Stability)
18pF FUND 50Ω2-Pin
HC-49/US SMD T/R
YES Lead Free REACH
AFFECTE
D
Jan-2017 Active CRYSTAL
12.0000MHZ 18PF
SMD
ABLS2-12.000MHZ-
D4Y-T 535-9869-1-ND
62 Crystal ATS100B-E 1 Q1 CTS-Frequency
Controls Crystal 10.0000MHz
30ppm 18pF 60 Ω-40°C
- 85°C Through Hole
HC49/US
YES Lead Free Reach
Not
Affected
Jan-2017 Active CRYSTAL
10.0000MHZ 18PF
T/H
ATS100B-E CTX919-ND
63 Pin Header P6E02A-602530-B1 6 JP1, JP2,
JP3, JP4,
JP5, JP6
Connector,Pin
Header,Straight,Male,1x
2Pin,2.54MM
pitch,6.00,3.00,Gold
Flash 1u,
black,DIP,alt_code:1507
1705
64 Pin Header P6E03A-602530-B1 3 J10,J12,J
16 Connector,Pin
Header,Straight,Male,1x
3Pin,2.54MM
pitch,6.00,3.00,Gold
Flash 1u,
black,DIP,alt_code:1507
1706
l TEXAS INSTRUMENTS
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LAUNCHXL-F28379D Hardware
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LAUNCHXL-F28379D Overview
Table 9. LAUNCHXL-F28379D Bill of Materials (continued)
Item
# Note Part Number Qty
REF
Desig
nator Manufacturer
(Digi-Key) Description
ROHS
(Digi-
Key) Lead Free
Status
Reach
Status
(Digi-
Key)
Reach
Effective
Date
(Digi-
Key) Availability Description
(Digi-Key)
Manufacturer
Part Number
Digi-Key)
Digi-Key
Part Number
(Digi-Key)
65 Pin Header P101-1*05SGF-
116A-NX 2 QEP_A,
QEP_B Connector,Pin
Header,Straight,Male,1x
5Pin,2.54MM
pitch,6.06,3.00,Gold
Flash 1u, black,DIP
66 Pin Header P101-2*04SGF-
116A-NX 1 J21 Connector,Pin
Header,Straight,Male,2x
4Pin,2.54MM
pitch,6.06,3.00,Gold
Flash 1u, black,DIP
67 Pin Socket CRD-081413-A-G 4 (J1,J3),(J
2?J4),(J5
?J7),(J6?
J8)
Connector,Pin
Socket,Straight,Female,2
x10Pin,2.54MM
pitch,8.51,9.91,Gold
Flash 10u, black,DIP
upgrade MPN. old part-
>CRD-081413-G-A
68 USB
Connector 897-43-005-00-
100001 1 CON1 Mill-Max
Manufacturing
Corp.
Connector,MiniUSB B
port,5 position,Right
Angle,Gold flash
30u,black,SMD
YES Lead Free Reach
Not
Affected
Jan-2017 Active CONN RECEPT MINI-
USB TYPE B SMT 897-43-005-00-
100001 ED90341CT-ND
69 BTB
Connector DF40C-60DP-
0.4V(51) 1 J9 Hirose Electric
Co Ltd CONN HDR 60POS
0.4MM SMD GOLD TR YES Lead Free Reach
Not
Affected
Dec-2015 Active CONN HDR 60POS
0.4MM SMD GOLD DF40C-60DP-
0.4V(51) H11628CT-ND
70 Shunt MJ501-EOGF-B-K 5 JP1,JP2,J
P3,JP4,J
P5
Connector,Shunt,open
type 2Pin,2.54MM
Pitch,6MM Height,Gold
Flash 1u,black,Bulk
71 Tactile Switch B3F-3152 1 S3 Omron
Electronics Inc-
EMC Div
SWITCH TACTILE
SPST-NO 0.05A 24V YES Lead Free Reach
Not
Affected
Dec-2015 Active SWITCH TACTILE
SPST-NO 0.05A 24V B3F-3152 SW410-ND
72 DIP Switch 219-3MST 1 S1 CTS
Electrocomponen
ts
Switch, DIP Switches,3
Position,2.54MM
Pitch,black housing,white
plunger,SMD
YES Lead Free Reach
Not
Affected
Jun-2016 Active SWITCH SLIDE DIP
SPST 100MA 20V 219-3MST CT2193MST-ND
l TEXAS INSTRUMENTS
References
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LAUNCHXL-F28379D Overview
7 References
The following documents describe the C2000 devices. Copies of these documents are available on the
Internet at http://www.ti.com/c2000 and www.ti.com/c2000-launchpad, or click on the links below:
1. TMS320F2837xD Dual-Core Delfino™ Microcontrollers Data Manual (SPRS880)
2. TMS320F28379D, TMS320F28377D, TMS320F28376D, TMS320F28375D, TMS320F28374D Delfino
Microcontrollers Silicon Errata (SPRZ412)
3. TMS320F2837xD Dual-Core Delfino Microcontrollers Technical Reference Guide (SPRUHM8)
4. TMS320C28x Extended Instruction Sets Technical Reference Manual (SPRUHS1)
5. TMS320C28x Instruction Set Simulator Technical Overview (SPRU608)
6. TMS320C28x Optimizing C/C++ Compiler v6.1 User's Guide (SPRU514)
7. TMS320C28x Assembly Language Tools v6.1 User's Guide (SPRU513)
l TEXAS INSTRUMENTS
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LAUNCHXL-F28379D Overview
8 Frequently Asked Questions (FAQ)
1. Can other programming and debug tools (such as an XDS510 debug probe) be used with the C2000
LaunchPad?
While a user could potentially connect an external debug probe to the F28379D device present on the
LaunchPad, it would require some rework of the board. It is recommended that users who want to use
an external debug probe, purchase a controlCard and docking station that includes an external JTAG
connector.
2. What versions of Code Composer Studio can be used to develop software for the C2000 LaunchPad?
It is highly recommend that novice users develop applications with at least Code Composer Studio v6.
The drivers, examples, and other associated software are tailored to make the user experience as
smooth as possible in Code Composer Studio v6.
3. Why can’t I connect to the LaunchPad in Code Composer Studio?
There are a number of things that could cause this and they all have an easy fix.
Is S1 switch 3 in the down position?
This is the TRST pin that enables and disables JTAG functionality on the chip. This switch must be
in the up position for the debug probe to be able to connect.
Are both power LEDs lit?
The board has two power domains because of the isolated JTAG interface. For low-voltage
application development, JTAG isolation is not needed and the power domains can be combined to
allow for convenience (that is, the board can be powered completely through the USB). Ensure that
jumpers are placed on the posts of JP1 and JP2.
Are drivers correctly installed for the XDS100v2 present on the LaunchPad?
Right click on My Computer and select properties. Navigate to the Hardware tab in the dialog box
and open the device manager. Scroll to the bottom of the list and expand the USB Serial Bus
controllers item. Are there two entries for TI XDS100 Channel A/B? If not, try unplugging and
replugging in the board. Does Windows give you any messages in the system tray? In Device
Manger, do either of the entries have a yellow exclamation mark over their icon? If so, try
reinstalling the drivers.
4. Why is the serial connection not working?
Are you using the correct COM port?
Right click on My Computer and select properties. Navigate to the Hardware tab in the dialog box
and open the device manager. Scroll to Ports (COM & LPT) and expand this entry. Is there a USB
Serial Port listed? If so, read the COM number to the right of the entry; this is the COM number you
should be using.
Are you using the correct baud rate?
Most, if not all, of the examples are configured for a baud rate of 115200 when the CPU is running
at 200 MHz. If you have changed the PLL settings or written your own application you may have to
recalculate the baud rate for your specific application. For information on how to do this, see the
TMS320F2837xD Delfino Microcontrollers Technical Reference Guide.
5. Why is my program operating at half the frequency of what I expected?
By default many of the C2000Ware examples are configured to operate on the
TMDSCNCD28379D which has a different clocking circuit, where the external clock is 20 MHz
instead of 10 MHz as found on this EVM.
A compiler switch was added to various functions to allow a user to change the clocking
configuration based on the status of a predefined symbol.
To ensure the PLL is correctly configured for the LAUNCHXL-F28379D, Add
"_LAUNCHXL_F28379D" to the predefined symbols list.
Access the Predefined symbols list by accessing the Project Properties, Navigating to Build »
C2000 Compiler » Advanced Options » Predefined Symbols. Figure 22 shows the Project
Properties selection tree and the symbol added to the pre-define list.
l TEXAS INSTRUMENTS 7 fix Properties for Example_28379D_launchPad typefikertext '> RgsauK: General . c2000 Compile. vioeessoi Options Optimization lnelode Options Paformavxe Advisor a Advaneed Options Advanced Debug 0min“: Language Options Parse! piepnxessing Opti Pudding! Symbols Diagnostic Options Rumime Model Oylions Advanced optimizanons Entry/Exit Hook Options Lihlaly Fundion Assump‘l Assembler Options File Type speeifier Dimdmy Specific: nelson Fl]: Bl‘lmsions Command files mom-cam I» C2000 Linkr ,IVY,,,V r Walnut Configuration: CPULFNI [Active] I’ve—define NAME ("ding -D) CPUI Undd’m NAM («undfing -U) I ® Show advanced 5min s
Frequently Asked Questions (FAQ)
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LAUNCHXL-F28379D Overview
Figure 22.
l TEXAS INSTRUMENTS
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Revision History
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Revision History
Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from B Revision (June 2018) to C Revision .................................................................................................... Page
Global Replacement of "emulator" with "debug probe"............................................................................... 1
Added list of known issues for all revisions of the EVM to Section 2.1............................................................ 3
Added note about lack of Boot-to-SCI options on this board in Section 2.1....................................................... 3
Added Section 4.4......................................................................................................................... 5
Added an FAQ in Section 8 for code executing at half of the expected frequency. ............................................ 27
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