10 KiB
IEEE 802.15.4e TSCH (TimeSlotted Channel Hopping)
Overview
TSCH is a MAC layer of the IEEE 802.15.4e-2012 amendment, currently being integrated as part of the new IEEE 802.15.4-2015. 6TiSCH is an IETF Working Group focused on IPv6 over TSCH. This is a Contiki implementation of TSCH and the 6TiSCH so-called "minimal configuration", which defines how to run a basic RPL+TSCH network.
It was developped by:
- Simon Duquennoy, SICS, simonduq@sics.se, github user: simonduq
- Beshr Al Nahas, SICS (now Chalmers University), beshr@chalmers.se, github user: beshrns
You can find an extensive evaluation of this implementation in our paper Orchestra: Robust Mesh Networks Through Autonomously Scheduled TSCH, ACM SenSys'15.
Features
This implementation includes:
- Standard IEEE 802.15.4e-2012 frame version 2
- Standard TSCH joining procedure with Enhanced Beacons with the following Information Elements:
- TSCH synchronization (join priority and ASN)
- TSCH slotframe and link (basic schedule)
- TSCH timeslot (timeslot timing template)
- TSCH channel hopping sequence (hopping sequence template)
- Standard TSCH link selection and slot operation (10ms slots by default)
- Standard TSCH synchronization, including with ACK/NACK time correction Information Element
- Standard TSCH queues and CSMA-CA mechanism
- Standard TSCH security
- Standard 6TiSCH TSCH-RPL interaction (6TiSCH Minimal Configuration and Minimal Schedule)
- A scheduling API to add/remove slotframes and links
- A system for logging from TSCH timeslot operation interrupt, with postponed printout
- Orchestra: an autonomous scheduler for TSCH+RPL networks
It has been tested on the following platforms:
- NXP JN516x (
jn516x
, tested on hardware) - Tmote Sky (
sky
, tested on hardware and in cooja) - Zolertia Z1 (
z1
, tested in cooja only) - CC2538DK (
cc2538dk
, tested on hardware) - Zolertia Zoul (
zoul
, tested on hardware) - OpenMote-CC2538 (
openmote-cc2538
, tested on hardware) - CC2650 (
srf06-cc26xx
, tested on hardware)
This implementation was present at the ETSI Plugtest event in Prague in July 2015, and did successfully inter-operate with all four implementations it was tested against.
We have designed this implementation with IPv6 and RPL in mind, but the code is fully independent
from upper layers (with the exception of the optional tsch-rpl.[ch]
), and has been
also tested with Rime (currently only with 64-bit link-layer addresses).
Code structure
The IEEE 802.15.4e-2012 frame format is implemented in:
core/net/mac/frame802154.[ch]
: handling of frame version 2core/net/mac/frame802154-ie.[ch]
: handling of Information Elements
TSCH is implemented in:
core/net/mac/tsch/tsch.[ch]
: TSCH management (association, keep-alive), processes handling pending outgoing and incoming packets, and interface with Contiki's upper layers as a MAC driver. TSCH does not require a RDC (nordc is recommended).tsch-slot-operation.[ch]
: TSCH low-level slot operation, fully interrupt-driven. Node wake up at every active slot (according to the slotframes and links installed), transmit or receive frames and ACKs. Received packets are stored in a ringbuf for latter upper-layer processing. Outgoing packets that are dequeued (because acknowledged or dropped) are stored in another ringbuf for upper-layer processing.tsch-asn.h
: TSCH macros for Absolute Slot Number (ASN) handling.tsch-packet.[ch]
: TSCH Enhanced ACK (EACK) and enhanced Beacon (EB) creation and parsing.tsch-queue.[ch]
: TSCH per-neighbor queue, neighbor state, and CSMA-CA.tsch-schedule.[ch]
: TSCH slotframe and link handling, and API for slotframe and link installation/removal.tsch-security.[ch]
: TSCH security, i.e. securing frames and ACKs from interrupt with ASN as part of the Nonce. Implements the 6TiSCH minimal configuration K1-K2 keys pair.tsch-rpl.[ch]
: used for TSCH+RPL networks, to align TSCH and RPL states (preferred parent -> time source, rank -> join priority) as defined in the 6TiSCH minimal configuration.tsch-log.[ch]
: logging system for TSCH, including delayed messages for logging from slot operation interrupt.
Orchestra is implemented in:
apps/orchestra
: seeapps/orchestra/README.md
for more information.
Using TSCH
A simple TSCH+RPL example is included under examples/ipv6/rpl-tsch
.
To use TSCH, first make sure your platform supports it.
Currently, jn516x
, sky
, z1
, cc2538dk
, zoul
, openmote-cc2538
, and srf06-cc26xx
are the supported platforms.
To add your own, we refer the reader to the next section.
To add TSCH to your application, first include the TSCH module from your makefile with:
MODULES += core/net/mac/tsch
Then, enable TSCH from your project conf with the following:
/* Netstack layers */
#undef NETSTACK_CONF_MAC
#define NETSTACK_CONF_MAC tschmac_driver
#undef NETSTACK_CONF_RDC
#define NETSTACK_CONF_RDC nordc_driver
#undef NETSTACK_CONF_FRAMER
#define NETSTACK_CONF_FRAMER framer_802154
/* IEEE802.15.4 frame version */
#undef FRAME802154_CONF_VERSION
#define FRAME802154_CONF_VERSION FRAME802154_IEEE802154E_2012
If you are running with RPL, it is recommended to enable the tsch-rpl
module with:
/* TSCH and RPL callbacks */
#define RPL_CALLBACK_PARENT_SWITCH tsch_rpl_callback_parent_switch
#define RPL_CALLBACK_NEW_DIO_INTERVAL tsch_rpl_callback_new_dio_interval
#define TSCH_CALLBACK_JOINING_NETWORK tsch_rpl_callback_joining_network
#define TSCH_CALLBACK_LEAVING_NETWORK tsch_rpl_callback_leaving_network
On CC2420-based platforms, enable SFD timestamps with:
/* Disable DCO calibration (uses timerB) */
#undef DCOSYNCH_CONF_ENABLED
#define DCOSYNCH_CONF_ENABLED 0
/* Enable SFD timestamps (uses timerB) */
#undef CC2420_CONF_SFD_TIMESTAMPS
#define CC2420_CONF_SFD_TIMESTAMPS 1
To configure TSCH, see the macros in .h
files under core/net/mac/tsch/
and redefine your own in your project-conf.h
.
Using TSCH with Security
To include TSCH standard-compliant security, set the following:
/* Enable security */
#undef LLSEC802154_CONF_ENABLED
#define LLSEC802154_CONF_ENABLED 1
/* TSCH uses explicit keys to identify k1 and k2 */
#undef LLSEC802154_CONF_USES_EXPLICIT_KEYS
#define LLSEC802154_CONF_USES_EXPLICIT_KEYS 1
/* TSCH uses the ASN rather than frame counter to construct the Nonce */
#undef LLSEC802154_CONF_USES_FRAME_COUNTER
#define LLSEC802154_CONF_USES_FRAME_COUNTER 0
The keys can be configured in net/mac/tsch/tsch-security.h
.
Nodes handle security level and keys dynamically, i.e. as specified by the incoming frame header rather that compile-time defined.
By default, when including security, the PAN coordinator will transmit secured EBs.
Use tsch_set_pan_secured
to explicitly ask the coordinator to secure EBs or not.
When associating, nodes with security included can join both secured or non-secured networks.
Set TSCH_CONF_JOIN_SECURED_ONLY
to force joining secured networks only.
Likewise, set TSCH_JOIN_MY_PANID_ONLY
to force joining networks with a specific PANID only.
TSCH Scheduling
By default (see TSCH_SCHEDULE_WITH_6TISCH_MINIMAL
), our implementation runs a 6TiSCH minimal schedule, which emulates an always-on link on top of TSCH.
The schedule consists in a single shared slot for all transmissions and receptions, in a slotframe of length TSCH_SCHEDULE_DEFAULT_LENGTH
.
As an alternative, we provide Orchestra (under apps/orchestra
), an autonomous scheduling solution for TSCH where nodes maintain their own schedule locally, solely based on their local RPL state.
Orchestra can be simply enabled and should work out-of-the-box with its default settings as long as RPL is also enabled.
See apps/orchestra/README.md
for more information.
Finally, one can also implement his own scheduler, centralized or distributed, based on the scheduling API provides in core/net/mac/tsch/tsch-schedule.h
.
Porting TSCH to a new platform
Porting TSCH to a new platform requires a few new features in the radio driver, a number of timing-related configuration paramters.
The easiest is probably to start from one of the existing port: jn516x
, sky
, z1
, cc2538dk
, zoul
, openmote-cc2538
, srf06-cc26xx
.
Radio features required for TSCH
The main new feature required for TSCH is the so-called poll mode, a new Rx mode for Contiki radio drivers. In poll mode, radio interrupts are disabled, and the radio driver never calls upper layers. Instead, TSCH will poll the driver for incoming packets, from interrupt, exactly when it expects one.
TSCH will check when initializing (in tsch_init
) that the radio driver supports all required features, namely:
- get and set Rx mode (
RADIO_PARAM_RX_MODE
) as follows:- enable address filtering with
RADIO_RX_MODE_ADDRESS_FILTER
- disable auto-ack with
RADIO_RX_MODE_AUTOACK
- enable poll mode with
RADIO_RX_MODE_POLL_MODE
- enable address filtering with
- get and set Tx mode (
RADIO_PARAM_TX_MODE
) as follows:- disable CCA-before-sending with
RADIO_TX_MODE_SEND_ON_CCA
- disable CCA-before-sending with
- set radio channel with
RADIO_PARAM_CHANNEL
- get last packet timestamp with
RADIO_PARAM_LAST_PACKET_TIMESTAMP
- optionally: get last packet RSSI with
RADIO_PARAM_LAST_RSSI
- optionally: get last packet LQI with
RADIO_PARAM_LAST_LQI
Timing macros required for TSCH
The following macros must be provided:
US_TO_RTIMERTICKS(US)
: converts micro-seconds to rtimer ticksRTIMERTICKS_TO_US(T)
: converts rtimer ticks to micro-secondsRADIO_DELAY_BEFORE_TX
: the delay between radio Tx request and SFD sent, in rtimer ticksRADIO_DELAY_BEFORE_RX
: the delay between radio Rx request and start listening, in rtimer ticks- optionally,
TSCH_CONF_DEFAULT_TIMESLOT_LENGTH
: the default TSCH timeslot length, useful i.e. for platforms too slow for the default 10ms timeslots.