This example is known to work great on the following platforms:

• DISCO_L475E_IOT01A - onboard WiFI and onboard QSPI flash. Board specific example using onboard sensors is available here.
• DISCO_F413H - onboard WiFI and onboard QSPI flash.
• DISCO_F469NI - WizFi310 WiFI shield and onboard QSPI flash (see WiFi shield instructions).
• DISCO_F746NG - onboard Ethernet and using onboard QSPI flash.
• DISCO_F769NI - onboard Ethernet and using onboard QSPI flash.
• DISCO_L496AG - WizFi310 WiFI shield and onboard QSPI flash (see WiFi shield instructions).
• NUCLEO_F207ZG - onboard Ethernet and wired SD card (SD card wiring instructions).
• NUCLEO_F412ZG - WizFi310 WiFI shield and SD card shield (see WiFi shield instructions).
• NUCLEO_F429ZI - onboard Ethernet and wired SD card (SD card wiring instructions).
• NUCLEO_F746ZG - onboard Ethernet and wired SD card (SD card wiring instructions).
• NUCLEO_F767ZI - onboard Ethernet and wired SD card (SD card wiring instructions).
• NUCLEO_L476RG - WizFi310 WiFI shield and SD card shield (see WiFi shield instructions).
• NUCLEO_L496ZG - WizFi310 WiFI shield and SD card shield (see WiFi shield instructions).
• NUCLEO_L4R5ZI - WizFi310 WiFI shield and SD card shield (see WiFi shield instructions).

Follow the Quick-Start instructions: https://cloud.mbed.com/quick-start

Example functionality

This example showcases the following device functionality:

• Read ADC temperature and ADC vref, and report them as Pelion LWM2M resources (see image below).
• On user button click, increment Pelion LWM2M button resource.
• Allow the user to change the state of the board LED from Pelion LWM2M led_state resource and PUT request.

SD card wiring

The ST Nucleo family of boards don't have storage onboard and therefore you will need an SD card. A limitation on ST Nucleo 144 boards is that there's a conflict between Ethernet and SPI pins on Arduino D11. Due to this, the SD card must be wired to different SPI bus that doesn't conflict with other functionality. The image below provide instructions on how to wire an SD card to a non-conflicting SPI instance.

If you are not a first-time Pelion Device Management user your device's SD card may already have connect and update certificates on it. If this is the case, remove and manually format your micro SD card, flash the binary to the device and then re-insert your micro SD card.

WiFi shield setup/wiring

Some ST Nucleo and Discovery boards don't have IP connectivity option, but bundled with a WiFi shield, they can take benefit of full device management capabilities. See links to reference images below on how to wire WizFI310 WiFi shield and/or SD card shield:

• ST DISCO_F469NI + WizFi310 WiFi Shield
• ST DISCO_L496AG + WizFi310 WiFi Shield
• ST NUCLEO_F412ZG + WizFi310 WiFi Shield + SD card shield
• ST NUCLEO_L476RG + WizFi310 WiFi Shield + SD card shield
• ST NUCLEO_L496ZG + WizFi310 WiFi Shield + SD card shield
• ST NUCLEO_L4R5ZI + WizFi310 WiFi Shield + SD card shield

Use this example with Mbed CLI

1. Import the application into your desktop:

mbed import /teams/ST/code/pelion-example-common

cd pelion-example-common

2. Install the CLOUD_SDK_API_KEY

mbed config -G CLOUD_SDK_API_KEY <PELION_DM_API_KEY>

For instructions on how to generate your API key, please see the documentation.

3. Initialize firmware credentials (done once per repository). You can use the following command:

mbed dm init -d "<your company name in Pelion DM>" --model-name "<product model identifier>" -q --force

If above command do not work for your Mbed CLI, please consider upgrading Mbed CLI to version 1.8.x or above.

4. Compile and program:

mbed compile -t <toolchain> -m <TARGET_BOARD>

(supported toolchains : GCC_ARM / ARM / IAR)

if (!isdefinedsymbol(MBED_APP_START)) { define symbol MBED_APP_START = 0x08000000; }
if (!isdefinedsymbol(MBED_APP_SIZE)) { define symbol MBED_APP_SIZE = 0x100000; }

/* [ROM = 1024kb = 0x100000] */
define symbol __intvec_start__     = MBED_APP_START;
define symbol __region_ROM_start__ = MBED_APP_START;
define symbol __region_ROM_end__   = MBED_APP_START + MBED_APP_SIZE - 1;

/* [RAM = 96kb + 32kb = 0x20000] */
/* Vector table dynamic copy: Total: 98 vectors * 4 = 392 bytes (0x188) to be reserved in RAM */
define symbol __NVIC_start__          = 0x10000000;
define symbol __NVIC_end__            = 0x10000187;
define symbol __region_SRAM2_start__  = 0x10000188;
define symbol __region_SRAM2_end__    = 0x10007FFF;
define symbol __region_CRASH_DATA_RAM_start__  = 0x20000000;
define symbol __region_CRASH_DATA_RAM_end__  = 0x200000FF;
define symbol __region_SRAM1_start__  = 0x20000100;
define symbol __region_SRAM1_end__    = 0x20017FFF;

/* Memory regions */
define memory mem with size = 4G;
define region ROM_region = mem:[from __region_ROM_start__ to __region_ROM_end__];
define region SRAM2_region = mem:[from __region_SRAM2_start__ to __region_SRAM2_end__];
define region CRASH_DATA_RAM_region = mem:[from __region_CRASH_DATA_RAM_start__ to __region_CRASH_DATA_RAM_end__];
define region SRAM1_region = mem:[from __region_SRAM1_start__ to __region_SRAM1_end__];

/* Define Crash Data Symbols */
define exported symbol __CRASH_DATA_RAM_START__ = __region_CRASH_DATA_RAM_start__;
define exported symbol __CRASH_DATA_RAM_END__ = __region_CRASH_DATA_RAM_end__;

/* Stack complete SRAM2 and Heap 2/3 of SRAM1 */
define symbol __size_cstack__ = 0x7e00;
define symbol __size_heap__   = 0x10000;
define block CSTACK    with alignment = 8, size = __size_cstack__   { };
define block HEAP      with alignment = 8, size = __size_heap__     { };

initialize by copy with packing = zeros { readwrite };
do not initialize  { section .noinit };

place at address mem:__intvec_start__ { readonly section .intvec };

place in ROM_region   { readonly };
place in SRAM1_region { readwrite, block HEAP };
place in SRAM2_region { block CSTACK };