contiki/platform/zoul/README.md
2015-11-24 21:15:34 +01:00

16 KiB

Zolertia Zoul core module

Zolertia Zoul Module

The Zoul is a core module developed by Zolertia to target most IoT applications, providing a flexible and affordable module solution to integrate to most existing products and solutions, or ease the prototyping and production of new products in a short time.

The Zoul is based on TI's CC2538 system on chip (SoC), featuring an ARM Cortex-M3 with 512KB flash, 32Kb RAM, double RF interface, and the following goodies:

  • ISM 2.4-GHz IEEE 802.15.4 & Zigbee compliant.
  • ISM 868-, 915-, 920-, 950-MHz ISM/SRD Band.
  • AES-128/256, SHA2 Hardware Encryption Engine.
  • ECC-128/256, RSA Hardware Acceleration Engine for Secure Key Exchange.
  • Small form-factor of 16.78 x 30.89 mm.
  • Prototype friendly, to fit on most prototyping boards (breadboard, etc.).
  • Self-contained and EMI-protected module under a shield.

The Zoul will be CE/FCC certified (2016) to allow a fast integration and short time to market for new products and solutions.

Zoul pin-out

Zoul pin-out (front) Zoul pin-out (back)

Port Features

The Zoul has the following key features:

  • Deep Sleep support with RAM retention for ultra-low energy consumption.
  • Native USB support (CDC-ACM). SLIP over UART for border routers is no longer a bottleneck.
  • DMA transfers for increased performance (RAM to/from RF, RAM to/from USB).

In terms of hardware support, the following drivers have been implemented for the Zoul-based platforms:

  • CC2538 System-on-Chip:
    • Standard Cortex M3 peripherals (NVIC, SCB, SysTick)
    • Sleep Timer (underpins rtimers)
    • SysTick (underpins the platform clock and Contiki's timers infrastructure)
    • RF (2.4GHz)
    • UART
    • Watchdog (in watchdog mode)
    • USB (in CDC-ACM)
    • uDMA Controller (RAM to/from USB and RAM to/from RF)
    • Random number generator
    • Low Power Modes
    • General-Purpose Timers. NB: GPT0 is in use by the platform code, the remaining GPTs are available for application development.
    • ADC
    • Cryptoprocessor (AES-CCM-256, SHA-256)
    • Public Key Accelerator (ECDH, ECDSA)
    • Flash-based port of Coffee
    • LEDs
    • Buttons
    • Built-in core temperature and battery sensor.
  • CC1200 sub-1GHz radio interface.

There is a Zoul powering the RE-Mote and Firefly platforms, check out its specific README files for more information about on-board features.

Requirements

To start using Contiki, the following is required:

  • A zoul-based board (RE-Mote, firefly)
  • A toolchain to compile Contiki for the CC2538.
  • Drivers so that your OS can communicate with your hardware.
  • Software to upload images to the CC2538.

Install a Toolchain

The toolchain used to build contiki is arm-gcc, also used by other arm-based Contiki ports. If you are using Instant Contiki, you will have a version pre-installed in your system. To find out if this is the case, try this:

$ arm-none-eabi-gcc -v
Using built-in specs.
Target: arm-none-eabi
Configured with: /scratch/julian/lite-respin/eabi/src/gcc-4.3/configure
...
(skip)
...
Thread model: single
gcc version 4.3.2 (Sourcery G++ Lite 2008q3-66)

The platform is currently being used/tested with the following toolchains:

Drivers

Depending on your Zoul flavour, there are different options. As today the RE-Mote and Firefly platforms host a Zoul with a CP2104 USB-to-serial converter, governed by a low-power PIC to handle resetting and flashing the Zoul over USB, without having to press any button or use external tools.

The driver is available at https://www.silabs.com/products/mcu/Pages/USBtoUARTBridgeVCPDrivers.aspx

Check the board's specific README files for more information.

For windows users, if using the USB 2.0 interface (via CDC-ACM driver), there is an available driver in this folder:

zolertia-zoul-cdc-acm

Software to Program the Nodes

The Zoul can be programmed via the jtag interface or via the serial boot loader on the chip.

Both the RE-Mote and Firefly has a mini JTAG 10-pin male header, compatible with the SmartRF06 development board, which can be used to flash and debug the platforms. Alternatively one could use the JLink programmer with a 20-to-10 pin converter like the following: https://www.olimex.com/Products/ARM/JTAG/ARM-JTAG-20-10/.

The serial boot loader on the chip is exposed to the user via an USB interface. In the not so distant past we used to press a button sequence to unlock the boot loader, but now an on-board PIC in both RE-Motes and Fireflies handles this on its own, so it will detect the BSL sequence and flash the CC2538 without user intervention.

Instructions to flash for different OS are given below.

  • On Windows:

    • Nodes can be programmed with TI's ArmProgConsole or the SmartRF Flash Programmer 2. The README should be self-explanatory. With ArmProgConsole, upload the file with a .bin extension. (jtag + serial)
    • Nodes can also be programmed via the serial boot loader in the cc2538. In tools/cc2538-bsl/ you can find cc2538-bsl.py this is a python script that can download firmware to your node via a serial connection. If you use this option you just need to make sure you have a working version of python installed. You can read the README in the same directory for more info. (serial)
  • On Linux:

    • Nodes can be programmed with TI's UniFlash tool. With UniFlash, use the file with .elf extension. (jtag + serial)
    • Nodes can also be programmed via the serial boot loader in the cc2538. No extra software needs to be installed. (serial)
  • On OSX:

    • The cc2538-bsl.py script in tools/cc2538-bsl/ is the only option. No extra software needs to be installed. (serial)

The file with a .zoul extension is a copy of the .elf file.

Use the Port

The following examples are intended to work off-the-shelf:

  • Examples under examples/zolertia/zoul
  • MQTT example examples/cc2538dk/mqtt-demo
  • Border router: examples/ipv6/rpl-border-router
  • Webserver: examples/webserver-ipv6
  • CoAP example: examples/er-rest-example/

Build your First Examples

It is recommended to start with the zoul-demo, it is a simple example that walkthroughs the zoul features (can be compiled for both the RE-Mote and the Firefly), such as the built-in sensors, LEDs, user button operation modes (press, release, hold-press), radio (Rime broadcast).

The Makefile.target includes the TARGET= argument, predefining which is the target platform to compile for, it is automatically included at compilation. The BOARD= argument is using as a glue switch to pull in specific platform files, for example the specific RE-Mote core drivers. If no BOARD argument is given, it will default to remote and compile for the RE-Mote platform.

To generate or override an existing one, you can run:

make TARGET=zoul savetarget

Then you can just run make to compile an application, otherwise you will need to do make TARGET=zoul.

Alternatively you can export the following to your work environment:

export BOARD=remote or export BOARD=firefly

This will avoid having to type this argument at each compilation.

If you want to upload the compiled firmware to a node via the serial boot loader you need first to either manually enable the boot loader, or just let the Co-Processor detect the flash sequence and do it on your behalf, as simple as not pressing anything at all!

Then use make zoul-demo.upload.

The PORT argument could be used to specify in which port the device is connected, in case we have multiple devices connected at the same time.

To generate an assembly listing of the compiled firmware, run make zoul-demo.lst. This may be useful for debugging or optimizing your application code. To intersperse the C source code within the assembly listing, you must instruct the compiler to include debugging information by adding CFLAGS += -g to the project Makefile and rebuild by running make clean zoul-demo.lst.

To enable printing debug output to your console, use the make login to get the information over the USB programming/debugging port, or alternatively use make serialview to also add a timestamp in each print.

Node IEEE/RIME/IPv6 Addresses

Nodes will generally autoconfigure their IPv6 address based on their IEEE address. The IEEE address can be read directly from the CC2538 Info Page, or it can be hard-coded. Additionally, the user may specify a 2-byte value at build time, which will be used as the IEEE address' 2 LSBs.

To configure the IEEE address source location (Info Page or hard-coded), use the IEEE_ADDR_CONF_HARDCODED define in contiki-conf.h:

  • 0: Info Page
  • 1: Hard-coded

If IEEE_ADDR_CONF_HARDCODED is defined as 1, the IEEE address will take its value from the IEEE_ADDR_CONF_ADDRESS define. If IEEE_ADDR_CONF_HARDCODED is defined as 0, the IEEE address can come from either the primary or secondary location in the Info Page. To use the secondary address, define IEEE_ADDR_CONF_USE_SECONDARY_LOCATION as 1.

Additionally, you can override the IEEE's 2 LSBs, by using the NODEID make variable. The value of NODEID will become the value of the IEEE_ADDR_NODE_ID pre-processor define. If NODEID is not defined, IEEE_ADDR_NODE_ID will not get defined either. For example:

make NODEID=0x79ab

This will result in the 2 last bytes of the IEEE address getting set to 0x79 0xAB

Note: Some early production devices do not have am IEEE address written on the Info Page. For those devices, using value 0 above will result in a Rime address of all 0xFFs. If your device is in this category, define IEEE_ADDR_CONF_HARDCODED to 1 and specify NODEID to differentiate between devices.

Low-Power Modes

The CC2538 port supports power modes for low energy consumption. The SoC will enter a low power mode as part of the main loop when there are no more events to service.

LPM support can be disabled in its entirety by setting LPM_CONF_ENABLE to 0 in contiki-conf.h or project-conf.h.

The Low-Power module uses a simple heuristic to determine the best power mode, depending on anticipated Deep Sleep duration and the state of various peripherals.

In a nutshell, the algorithm first answers the following questions:

  • Is the RF off?
  • Are all registered peripherals permitting PM1+?
  • Is the Sleep Timer scheduled to fire an interrupt?

If the answer to any of the above question is "No", the SoC will enter PM0. If the answer to all questions is "Yes", the SoC will enter one of PMs 0/1/2 depending on the expected Deep Sleep duration and subject to user configuration and application requirements.

At runtime, the application may enable/disable some Power Modes by making calls to lpm_set_max_pm(). For example, to avoid PM2 an application could call lpm_set_max_pm(1). Subsequently, to re-enable PM2 the application would call lpm_set_max_pm(2).

The LPM module can be configured with a hard maximum permitted power mode.

#define LPM_CONF_MAX_PM        N

Where N corresponds to the PM number. Supported values are 0, 1, 2. PM3 is not supported. Thus, if the value of the define is 1, the SoC will only ever enter PMs 0 or 1 but never 2 and so on.

The configuration directive LPM_CONF_MAX_PM sets a hard upper boundary. For instance, if LPM_CONF_MAX_PM is defined as 1, calls to lpm_set_max_pm() can only enable/disable PM1. In this scenario, PM2 can not be enabled at runtime.

When setting LPM_CONF_MAX_PM to 0 or 1, the entire SRAM will be available. Crucially, when value 2 is used the linker will automatically stop using the SoC's SRAM non-retention area, resulting in a total available RAM of 16MB instead of 32MB.

LPM and Duty Cycling Driver

LPM is highly related to the operations of the Radio Duty Cycling (RDC) driver of the Contiki network stack and will work correctly with ContikiMAC and NullRDC.

  • With ContikiMAC, PMs 0/1/2 are supported subject to user configuration.
  • When NullRDC is in use, the radio will be always on. As a result, the algorithm discussed above will always choose PM0 and will never attempt to drop to PM1/2.

Shutdown Mode

The RE-Mote has a built-in shutdown mode which effectively reduces the power consumption down to 300nA. Check its specific README file for more information.

Build headless nodes

It is possible to turn off all character I/O for nodes not connected to a PC. Doing this will entirely disable the UART as well as the USB controller, preserving energy in the long term. The define used to achieve this is (1: Quiet, 0: Normal output):

#define CC2538_CONF_QUIET      0

Setting this define to 1 will automatically set the following to 0:

  • USB_SERIAL_CONF_ENABLE
  • UART_CONF_ENABLE
  • STARTUP_CONF_VERBOSE

Code Size Optimisations

The build system currently uses optimization level -Os, which is controlled indirectly through the value of the SMALL make variable. This value can be overridden by example makefiles, or it can be changed directly in platform/zoul/Makefile.zoul.

Historically, the -Os flag has caused problems with some toolchains. If you are using one of the toolchains documented in this README, you should be able to use it without issues. If for whatever reason you do come across problems, try setting SMALL=0 or replacing -Os with -O2 in cpu/cc2538/Makefile.cc2538.

Doxygen Documentation

This port's code has been documented with doxygen. To build the documentation, navigate to $(CONTIKI)/doc and run make. This will build the entire contiki documentation and may take a while.

If you want to build this platform's documentation only and skip the remaining platforms, run this:

make basedirs="platform/zoul core cpu/cc2538 examples/zolertia/zoul examples/cc2538dk"

Once you've built the docs, open $(CONTIKI)/doc/html/index.html and enjoy.

Other Versions of this Guide

If you prefer this guide in other formats, use the excellent pandoc to convert it.

  • pdf: pandoc -s --toc README.md -o README.pdf
  • html: pandoc -s --toc README.md -o README.html

More Reading

  1. Zolertia website
  2. CC2538 System-on-Chip Solution
  3. CC1200 sub-1GHz RF transceiver
  4. Zolertia Hackster channel
  5. IoT in five days open source and online book

Maintainers

The Zoul and derived platforms (as well as the Z1 mote) are maintained by Zolertia. Main contributor: Antonio Lignan alignan@zolertia.com