osd-contiki/platform/srf06-cc26xx
George Oikonomou 7ae3cd49ba Make sure SSI0 is powered and clocked before accessing it
* Fail all SSI0 operations if the module is not powered and clocked
* Make sure SERIAL is powered before trying to enable run mode clock
2015-05-15 11:38:20 +01:00
..
sensortag Make sure SSI0 is powered and clocked before accessing it 2015-05-15 11:38:20 +01:00
srf06 Change the LPM locks API: 2015-05-15 09:21:02 +01:00
contiki-conf.h Merge pull request #1046 from g-oikonomou/cc26xx/contrib/slip-and-br 2015-05-09 22:51:06 +01:00
contiki-main.c Adjust main: 2015-05-15 09:21:04 +01:00
Makefile.srf06-cc26xx Add CC26xx common platform files 2015-02-25 13:12:20 +01:00
README.md Merge pull request #986 from g-oikonomou/cc26xx-hdc-sensor 2015-05-15 10:12:08 +02:00

Getting Started with Contiki for TI CC26xx

This guide's aim is to help you start using Contiki for TI's CC26xx. The platform supports two different boards:

  • SmartRF 06 Evaluation Board with a CC26xx Evaluation Module (relevant files and drivers are under srf06/)
  • CC26xx SensorTag 2.0 (relevant drivers under sensortag/)

The CPU code, common for both platforms, can be found under $(CONTIKI)/cpu/cc26xx. The port was developed and tested with CC2650s, but the intention is for it to work with the CC2630 as well. Thus, bug reports are welcome for both chips. Bear in mind that the CC2630 does not have BLE capability.

This port is only meant to work with 7x7mm chips

This guide assumes that you have basic understanding of how to use the command line and perform basic admin tasks on UNIX family OSs.

Port Features

The platform has the following key features:

  • Deep Sleep support with RAM retention for ultra-low energy consumption.
  • Support for CC26xx RF in IEEE as well as BLE mode (BLE support is very basic since Contiki does not provide a BLE stack).

In terms of hardware support, the following drivers have been implemented:

  • SmartRF06 EB peripherals
    • LEDs
    • Buttons
    • UART connectivity over the XDS100v3 backchannel
  • SensorTag 2.0
    • LEDs
    • Buttons (One of the buttons can be used as a shutdown button)
    • Reed relay
    • Motion Processing Unit (MPU9250 - Accelerometer, Gyro)
    • BMP280 sensor
    • TMP007 sensor
    • HDC1000 sensor
    • OPT3001 sensor
    • Buzzer
    • External SPI flash

Examples

The port comes with two examples: A very basic example and a mode advanced one (web demo). The former demonstrates how to read sensors and how to use board peripherals. It also demonstrates how to send out BLE advertisements. The latter includes a CoAP server, an MQTT client which connects and publishes to the IBM quickstart service, a net-based UART and lastly a web server that can be used to configure the rest of the example.

More details about those two examples can be found in their respective READMEs.

Requirements

To use the port you need:

  • TI's CC26xxware sources (more below)

  • Software to program the nodes. Use TI's SmartRF Flash Programmer

  • A toolchain to build firmware: The port has been developed and tested with GNU Tools for ARM Embedded Processors https://launchpad.net/gcc-arm-embedded. The port was developed and tested using this version:

    $ arm-none-eabi-gcc -v [...] gcc version 4.9.3 20141119 (release) [ARM/embedded-4_9-branch revision 218278] (GNU Tools for ARM Embedded Processors)

  • srecord (http://srecord.sourceforge.net/)

  • You may also need other drivers so that the SmartRF can communicate with your operating system and so that you can use the chip's UART for I/O. Please read the section "Drivers" in the CC2538DK readme.

Environment

To use this port, you will need to download and extract CC26xxware sources. We currently use CC26xxware version 2.20.06.14829. The download link can be found here: http://processors.wiki.ti.com/index.php/CC26xxware

Once you have done this, you will need to configure the Contiki build system so that it can locate and compile them as part of the build process.

To do this, you will need to set the following environment variable:

  • TI_CC26XXWARE

    Stores the path to a directory containing the following:

    • cc26xxware sources under $(TI_CC26XXWARE)/driverlib
    • cc26xxware includes under $(TI_CC26XXWARE)/inc
    • Startup files under $(TI_CC26XXWARE)/startup_files

This must be a path relative to the Contiki source directory. For example, if Contiki is in /home/user/contiki-2.x and the CC26xxware is in /home/user/cc26xxware, then TI_CC26XXWARE must be set to ../cc26xxware

The variable can be set within the example's Makefile, by adding this:

TI_CC26XXWARE=../cc26xxware

or you can use an environment variable, like so:

export TI_CC26XXWARE=../cc26xxware

Filename conflicts between Contiki and CC26xxware

There is a file called timer.c both in Contiki as well as in CC26xxware. The way things are configured now, we don't use the latter. However, if you need to start using it at some point, you will need to rename it:

From $(TI_CC26XXWARE)/driverlib/cc26xx/source/timer.c to driverlib-timer.c

Sensortag vs Srf06

To build for the sensortag, set BOARD=sensortag. You can do that by exporting it as an environment variable, by adding it to your Makefile or by adding it to your make command as an argument

If the BOARD variable is not equal to sensortag, an image for the Srf06 CC26XXEM will be built instead.

If you want to switch between building for one platform to the other, make certain to make clean before building for the new one, or you will get linker errors.

Low Power Operation

The platform takes advantage of the CC26xx's power saving features. In a nutshell, here is how things work:

  • When the RF is TXing, the CPU will enter sleep mode and will resume after TX has completed.
  • When there are no events in the Contiki event queue, the chip will enter 'some' low power mode (more below).

We do not use pre-defined power profiles (e.g. as mentioned in the TRM or as we do for the CC2538 with LPM1, LPM2 etc). Each time we enter low power operation, we either put the CM3 to sleep or to deep sleep. The latter case is highly configurable: the LPM engine allows other code modules to register themselves for notifications and to configure low power operation. With these facilities, a module can e.g. prohibit deep sleep altogether, or it can request that a power domain be kept powered. The LPM engine will turn off as many CC26xx components as it can while satisfying all restrictions set by registered modules.

To determine which power mode to use, the following logic is followed:

  • The deepest available low power mode can be hard-coded by using the LPM_MODE_MAX_SUPPORTED macro in the LPM driver (lpm.[ch]). Thus, it is possible to prohibit deep sleep altogether.
  • Code modules which are affected by low power operation can 'register' themselves with the LPM driver.
  • If the projected low-power duration is lower than STANDBY_MIN_DURATION, the chip will simply sleep.
  • If the projected low power duration is sufficiently long, the LPM will visit all registered modules to query the maximum allowed power mode (maximum means sleep vs deep sleep in this context). It will then drop to this power mode. This is where a code module can forbid deep sleep if required.
  • All registered modules will be notified when the chip is about to enter deep sleep, as well as after wake-up.

When the chip does enter deep sleep:

  • The RF Core, VIMS, SYSBUS and CPU power domains are always turned off. Due to the way the RF driver works, the RFCORE PD should be off already.
  • Peripheral clocks stop
  • The Serial and Peripheral power domains are turned off, unless an LPM module requests them to stay operational. For example, the net-uart demo keeps the serial power domain powered on and the UART clocked under sleep and deep sleep in order to retain UART RX functionality.
  • If both SERIAL and PERIPH PDs are turned off, we also switch power source to the uLDO for ultra low leakage under deep sleep.

The chip will come out of low power mode by one of the following events:

  • Button press or, in the case of the SensorTag, a reed relay trigger
  • Software clock tick (timer). The clock ticks at 128Hz, therefore the maximum time we will ever spend in a sleep mode is 7.8125ms. In hardware terms, this is an AON RTC Channel 2 compare interrupt.
  • Rtimer triggers, as part of ContikiMAC's sleep/wake-up cycles. The rtimer sits on the AON RTC channel 0.