The ARTIK 053 is a SOC for Wi-Fi™ IoT solutions. The ARTIK 053 has a Wi-Fi subsystem, security subsystem, and application subsystem.
Information
Environment Set-up
How to program a binary
ROMFS
How to use GDB
Configuration Sets
Appendix
The Samsung ARTIK™ 053 Module is a highly integrated module for secure Internet of Things (IoT) devices that require Wi-Fi®. It is based on an ARM® Cortex® R4 core with on-chip memories, a complete 2.4GHz Wi-Fi® Phy, MAC layer processing, a large complement of standard digital buses, a PUF-based security system and power management. The module is packaged with additional external Flash memory, a hardware Secure Element and a single integrated 2.4GHz structural antenna. Aimed especially at power-sensitive devices needing Wi-Fi®, the ARTIK 053 Module provides excellent performance in a variety of environments, with a feature set tailored specifically for IoT end nodes.
XGPIO13(gpio42) <- SW702 | SW703 -> XGPIO15(gpio44)
XGPIO16(gpio45) <- LED703 | LED702 -> XGPIO20(gpio49)
[CON708]
| | * -> XI2C0_SCL
| | * -> XI2C0_SDA
| | * -> AREF
[CON710] | | * -> GND
NC <- * | | 13 -> XSPI1_CLK
NC <- * | | 12 -> XSPI1_MISO
RESET <- * | | 11 -> XSPI1_MOSI
3.3V <- * | ARTIK053 | 10 -> XSPI1_CSN
NC <- * | | 9 -> XPWMTOUT_4
GND <- * | | 8 -> XGPIO21(gpio50)
GND <- * | | [CON709]
Vin <- * | | 7 -> XGPIO19(gpio48)
[CON711] | | 6 -> XPWMTOUT_2
XADC0 <- A0 +-----------+ 5 -> XPWMTOUT_1
XADC1 <- A1 4 -> XGPIO18(gpio47)
XADC2 <- A2 3 -> XPWMTOUT_0
XADC3 <- A3 2 -> XGPIO17(gpio46)
XADC4 <- A4 1 -> XUART0_TX
XADC5 <- A5 0 -> XUART0_RX
[CON703]
2 4 6 8 10 12 14 16 18 20 22 24
1 3 5 7 9 11 13 15 17 19 21 23
[CON704]
2 4 6 8 10 12 14 16 18 20 22 24
1 3 5 7 9 11 13 15 17 19 21 23
XPWMTOUT_1 <- 1 | 2 -> VCC_EXT3P3
XPWMTOUT_2 <- 3 | 4 -> XADC6
XPWMTOUT_3 <- 5 | 6 -> XADC7
XPWMTOUT_0 <- 7 | 8 -> XI2C1_SCL
XUART1_RXD <- 9 | 10 -> XI2C1_SDA
XUART1_TXD <- 11 | 12 -> GND
XGPIO26(gpio55) <- 13 | 14 -> VCC_EXT3P3
XGPIO25(gpio54) <- 15 | 16 -> XSPI0_CLK
XGPIO24(gpio53) <- 17 | 18 -> XSPI0_CSN
XGPIO23(gpio52) <- 19 | 20 -> XSPI0_MISO
XGPIO22(gpio51) <- 21 | 22 -> XSPI0_MOSI
XEINT0(gpio57) <- 23 | 24 -> GND
XPWMTOUT_4 <- 1 | 2 -> VCC_EXT3P3
XPWMTOUT_5 <- 3 | 4 -> XUART2_RXD
XEINT2(gpio59) <- 5 | 6 -> XUART2_TXD
XEINT1(gpio58) <- 7 | 8 -> XUART3_RXD
XGPIO12(gpio41) <- 9 | 10 -> XUART3_TXD
XGPIO10(gpio39) <- 11 | 12 -> GND
XGPIO9(gpio38) <- 13 | 14 -> VCC_EXT3P3
XGPIO11(gpio40) <- 15 | 16 -> XGPIO4(gpio33)/XSPI2_CLK
XGPIO8(gpio37) <- 17 | 18 -> XGPIO5(gpio34)/XSPI2_CSN
XGPIO2(gpio31) <- 19 | 20 -> XGPIO6(gpio35)/XSPI2_MISO
XGPIO1(gpio30) <- 21 | 22 -> XGPIO7(gpio36)/XSPI2_MOSI
XGPIO3(gpio32) <- 23 | 24 -> GND
8MB is allocated to the SPI Flash area. 1280 KB is prepared for operation in SRAM. Here is the physical memory address, see [here].
This section covers board-specific environment set-up.
Please set TizenRT common environment, quick start, first before doing below.
This is an optional environment.
But as ARTIK is connected through USB, some operation like programming of binary can't be worked without this configuration.
The dbuild.sh script with the menu option supports the u. USBrule option to add it.
- Select the d. Download option after building TizenRT
======================================================
"Select build Option"
======================================================
"1. Build with Current Configurations"
"2. Re-configure"
"3. Menuconfig"
"4. Build Clean"
"5. Build Dist-Clean"
"6. Build SmartFS Image"
"d. Download"
"x. Exit"
======================================================
d- Select the u. USBrule option
==================================================
"Select download option"
==================================================
"1. ALL"
"2. OS"
"4. APPS"
"5. OTA"
"6. ROM"
"7. MICOM"
"8. WIFI"
"9. LOADPARAM"
"10. BL1"
"11. BL2"
"12. SSSFW"
"13. WLANFW"
"14. ERASE OTA"
"15. ERASE USERFS"
"16. ERASE ALL"
"u. USBrule"
"x. Exit"
==================================================
uNOTE It requires root permission.
- Make a file named 99-<anyname>.rules.
- Add below contents at above file.
SUBSYSTEMS=="usb",ATTRS{idVendor}=="0403",ATTRS{idProduct}=="6010",MODE="0666" RUN+="/sbin/modprobe ftdi_sio" RUN+="/bin/sh -c 'echo 0403 6010 > /sys/bus/usb-serial/drivers/ftdi_sio/new_id'"
- Place the above file in /etc/udev/rules.d folder with sudo permission.
- Reboot your system.
After building TizenRT, execute below command at $TIZENRT_BASEDIR/os folder.
See [Getting the sources] for how to set TIZENRT_BASEDIR.
./dbuild.sh download [Programming Option]For example, ALL option makes complete set of binaries programmed.
./dbuild.sh download ALLSee programming options list which is pre-defined at .flashSpec.xml.
Refer How to program using OpenOCD to make user-specific programming seqeunce.
If you can not boot normally, you can change os to the initial version. This is possible if there is an initialization binary in memory.
You can download it using OpenOCD. You compress the compiled firmware and download it to the board.
gzip -c tinyara_head.bin > factoryimage.gz
openocd -f artik05x.cfg -s ../build/configs/artik05x/scripts -c ' \
flash_erase_part ota ;\
flash_write factory ../build/configs/artik053/bin/factoryimage.gz; \
exit'When you press the RESET button (SW700) to reboot the Starter Kit, press and hold the 'ARDUINO RESET' button (SW701) for 10 seconds. Enter initialization mode as follows.
.....
Factory reset.
Erasing boot partitions...
....................................e
Erased 600 sectors
Flashing factory image...
Uncompressed size: 1258496 = 0x133400
resetting ...
........ <RESET>.....................
U-Boot 2017
.....
- Run OpenOCD daemon.
@ubuntu:~/TizenRT/os$ ../build/tools/openocd/linux64/openocd -f artik05x.cfg -s ../build/configs/artik05x/scripts/ Open On-Chip Debugger 0.10.0-dirty (2017-09-02-08:32) Licensed under GNU GPL v2 For bug reports, read http://openocd.org/doc/doxygen/bugs.html adapter speed: 2000 kHz Info : auto-selecting first available session transport "jtag". To override use 'transport select <transport>'. force hard breakpoints trst_and_srst separate srst_gates_jtag trst_push_pull srst_push_pull connect_deassert_srst adapter_nsrst_assert_width: 50 adapter_nsrst_delay: 100 debug_level: -1
- Run GDB at another terminal.
Please find<-- COMMANDat below logs.@ubuntu:~/TizenRT/os$ arm-none-eabi-gdb ../build/output/bin/tinyara <-- COMMAND GNU gdb (GNU Tools for ARM Embedded Processors) 7.8.0.20150604-cvs Copyright (C) 2014 Free Software Foundation, Inc. License GPLv3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html> This is free software: you are free to change and redistribute it. There is NO WARRANTY, to the extent permitted by law. Type "show copying" and "show warranty" for details. This GDB was configured as "--host=i686-linux-gnu --target=arm-none-eabi". Type "show configuration" for configuration details. For bug reporting instructions, please see: <http://www.gnu.org/software/gdb/bugs/>. Find the GDB manual and other documentation resources online at: <http://www.gnu.org/software/gdb/documentation/>. For help, type "help". Type "apropos word" to search for commands related to "word"... Reading symbols from TizenRT/build/output/bin/tinyara...done. (gdb) target remote:3333 <-- COMMAND Remote debugging using :3333 0x00003834 in ?? () (gdb) monitor reset halt <-- COMMAND target halted in ARM state due to debug-request, current mode: Supervisor cpsr: 0x60000153 pc: 0x040db8a8 D-Cache: enabled, I-Cache: enabled (gdb) monitor cortex_r4 maskisr on <-- COMMAND cortex_a interrupt mask on (gdb) b hello_main Breakpoint 1 at 0x40d30fc: file hello_main.c, line 196. (gdb) b up_assert Breakpoint 2 at 0x40c9364: file armv7-r/arm_assert.c, line 945. (gdb) c Continuing. Breakpoint 1, hello_main (argc=1, argv=0x202fd1c) at hello_main.c:196 196 { (gdb) s 197 sleep(20); (gdb) s sleep (seconds=seconds@entry=20) at unistd/lib_sleep.c:155 155 if (seconds) { (gdb) c Continuing. Breakpoint 2, up_assert (filename=filename@entry=0x40ea757 "hello_main.c", lineno=lineno@entry=198) at armv7-r/arm_assert.c:945 945 lldbg("Assertion failed at file:%s line: %d task: %s\n", filename, lineno, this_task()->name); (gdb)
help will help you to find GDB commands.
This can be used to use full functionality of TizenRT on ARTIK053.
This provides simple hello world application including kernel.
This can be used to use Iotivity (OCF).
This can be used to use IoT.js
This can be used to test kernel functionality.
This can be used to use the minimal functionality of TizenRT on ARTIK053.
This can be used to test network functionality.
This can be used to test Smart Things Things SDK functionality.
This can be used to test database, File System, kernel, network functionality of TizenRT on ARTIK053.
OpenOCD is used to program and debug.
OpenOCD v0.10.0 is recommended and can be installed like below, but pre-built OpenOCD binaray on tools/openocd/linux64(or 32) can be used without installing.
sudo apt-get build-dep openocd
git clone --depth 1 -b v0.10.0 https://git.code.sf.net/p/openocd/code openocd-code
cd openocd-code
./bootstrap
./configure
make
sudo make installThis is used to program a partial binary.
Export 'OPENOCD_SCRIPTS' to environment variable.
export OPENOCD_SCRIPTS=$TIZENRT_BASEDIR/build/tools/openocdAt first, programming the complete set of binaries are needed.
openocd -f artik05x.cfg -s ../build/configs/artik05x/scripts -c ' \
flash_write bl1 ../build/configs/artik053/bin/bl1.bin; \
flash_write bl2 ../build/configs/artik053/bin/bl2.bin; \
flash_write sssfw ../build/configs/artik053/bin/sssfw.bin; \
flash_write wlanfw ../build/configs/artik053/bin/wlanfw.bin; \
flash_write os ../build/output/bin/tinyara_head.bin; \
exit'Once the complete binaries are successfully programmed, each partition can be updated separately with new one.
openocd -f artik05x.cfg -s ../build/configs/artik05x/scripts -c ' \
flash_write os ../build/output/bin/tinyara_head.bin; exit'