Internet DRAFT - draft-ietf-6tisch-tsch
draft-ietf-6tisch-tsch
6TiSCH T. Watteyne, Ed.
Internet-Draft Linear Technology
Intended status: Informational MR. Palattella
Expires: September 10, 2015 University of Luxembourg
LA. Grieco
Politecnico di Bari
March 9, 2015
Using IEEE802.15.4e TSCH in an IoT context:
Overview, Problem Statement and Goals
draft-ietf-6tisch-tsch-06
Abstract
This document describes the environment, problem statement, and goals
for using the IEEE802.15.4e TSCH MAC protocol in the context of LLNs.
The set of goals enumerated in this document form an initial set
only.
Status of This Memo
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. TSCH in the LLN Context . . . . . . . . . . . . . . . . . . . 4
3. Problems and Goals . . . . . . . . . . . . . . . . . . . . . 6
3.1. Network Formation . . . . . . . . . . . . . . . . . . . . 6
3.2. Network Maintenance . . . . . . . . . . . . . . . . . . . 7
3.3. Multi-Hop Topology . . . . . . . . . . . . . . . . . . . 7
3.4. Routing and Timing Parents . . . . . . . . . . . . . . . 7
3.5. Resource Management . . . . . . . . . . . . . . . . . . . 8
3.6. Dataflow Control . . . . . . . . . . . . . . . . . . . . 8
3.7. Deterministic Behavior . . . . . . . . . . . . . . . . . 8
3.8. Scheduling Mechanisms . . . . . . . . . . . . . . . . . . 9
3.9. Secure Communication . . . . . . . . . . . . . . . . . . 9
4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 9
5. Security Considerations . . . . . . . . . . . . . . . . . . . 10
6. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 10
7. References . . . . . . . . . . . . . . . . . . . . . . . . . 10
7.1. Normative References . . . . . . . . . . . . . . . . . . 10
7.2. Informative References . . . . . . . . . . . . . . . . . 10
Appendix A. TSCH Protocol Highlights . . . . . . . . . . . . . . 13
A.1. Timeslots . . . . . . . . . . . . . . . . . . . . . . . . 13
A.2. Slotframes . . . . . . . . . . . . . . . . . . . . . . . 14
A.3. Node TSCH Schedule . . . . . . . . . . . . . . . . . . . 14
A.4. Cells and Bundles . . . . . . . . . . . . . . . . . . . . 14
A.5. Dedicated vs. Shared Cells . . . . . . . . . . . . . . . 15
A.6. Absolute Slot Number . . . . . . . . . . . . . . . . . . 15
A.7. Channel Hopping . . . . . . . . . . . . . . . . . . . . . 16
A.8. Time Synchronization . . . . . . . . . . . . . . . . . . 16
A.9. Power Consumption . . . . . . . . . . . . . . . . . . . . 17
A.10. Network TSCH Schedule . . . . . . . . . . . . . . . . . . 17
A.11. Join Process . . . . . . . . . . . . . . . . . . . . . . 18
A.12. Information Elements . . . . . . . . . . . . . . . . . . 18
A.13. Extensibility . . . . . . . . . . . . . . . . . . . . . . 18
Appendix B. TSCH Features . . . . . . . . . . . . . . . . . . . 19
B.1. Collision Free Communication . . . . . . . . . . . . . . 19
B.2. Multi-Channel vs. Channel Hopping . . . . . . . . . . . . 19
B.3. Cost of (continuous) Synchronization . . . . . . . . . . 19
B.4. Topology Stability . . . . . . . . . . . . . . . . . . . 20
B.5. Multiple Concurrent Slotframes . . . . . . . . . . . . . 20
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 20
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1. Introduction
IEEE802.15.4e [IEEE802154e] was published in 2012 as an amendment to
the Medium Access Control (MAC) protocol defined by the
IEEE802.15.4-2011 [IEEE802154] standard. IEEE802.15.4e will be
rolled into the next revision of IEEE802.15.4, scheduled to be
published in 2015. The Timeslotted Channel Hopping (TSCH) mode of
IEEE802.15.4e is the object of this document.
This document describes the main issues arising from the adoption of
the IEEE802.15.4e TSCH in the LLN context, following the terminology
defined in [I-D.ietf-6tisch-terminology]. Appendix A further gives
an overview of the key features of the IEEE802.15.4e Timeslotted
Channel Hopping (TSCH) amendment. Appendix B details features of
IEEE802.15.4e TSCH which might be interesting for the work of the
6TiSCH WG.
TSCH was designed to allow IEEE802.15.4 devices to support a wide
range of applications including, but not limited to, industrial ones
[IEEE802154e]. At its core is a medium access technique which uses
time synchronization to achieve low power operation and channel
hopping to enable high reliability. Synchronization accuracy impacts
power consumption, and can vary from micro-seconds to milli-seconds
depending on the solution. This is very different from the "legacy"
IEEE802.15.4 MAC protocol, and is therefore better described as a
"redesign". TSCH does not amend the physical layer; i.e., it can
operate on any IEEE802.15.4-compliant hardware.
IEEE802.15.4e is the latest generation of ultra-lower power and
reliable networking solutions for LLNs. [RFC5673] discusses
industrial applications, and highlights the harsh operating
conditions as well as the stringent reliability, availability, and
security requirements for an LLN to operate in an industrial
environment. In these environments, vast deployment environments
with large (metallic) equipment cause multi-path fading and
interference to thwart any attempt of a single-channel solution to be
reliable; the channel agility of TSCH is the key to its ultra high
reliability. Commercial networking solutions are available today in
which nodes consume 10's of micro-amps on average [CurrentCalculator]
with end-to-end packet delivery ratios over 99.999%
[doherty07channel].
IEEE802.15.4e has been designed for low-power constrained devices,
often called "motes". Several terms are used in the IETF to refer to
those devices, including "LLN nodes" [RFC7102] and "constrained
nodes" [RFC7228]. In this document, we use the generic (and shorter)
term "node", used as a synonym for "LLN node", "constrained node" or
"mote".
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Enabling the LLN protocol stack to operate in industrial environments
opens up new application domains for these networks. Sensors
deployed in smart cities [RFC5548] will be able to be installed for
years without needing battery replacement. "Umbrella" networks will
interconnect smart elements from different entities in smart
buildings [RFC5867]. Peel-and-stick switches will obsolete the need
for costly conduits for lighting solutions in smart homes [RFC5826].
IEEE802.15.4e TSCH focuses on the MAC layer only. This clean
layering allows for TSCH to fit under an IPv6 enabled protocol stack
for LLNs, running 6LoWPAN [RFC6282], IPv6 Routing Protocol for Low
power and Lossy Networks (RPL) [RFC6550] and the Constrained
Application Protocol (CoAP) [RFC7252]. What is missing is a
functional entity which is in charge of scheduling TSCH timeslots for
frames to be sent on. In this document, we refer to this entity as
the "Logical Link Control" (LLC), bearing in mind that realizations
of this entity can be of different types, including a distributed
protocol or a centralized server in charge of scheduling.
While [IEEE802154e] defines the mechanisms for a TSCH node to
communicate, it does not define the policies to build and maintain
the communication schedule, match that schedule to the multi-hop
paths maintained by RPL, adapt the resources allocated between
neighbor nodes to the data traffic flows, enforce a differentiated
treatment for data generated at the application layer and signaling
messages needed by 6LoWPAN and RPL to discover neighbors, react to
topology changes, self-configure IP addresses, or manage keying
material.
In other words, IEEE802.15.4e TSCH is designed to allow optimizations
and strong customizations, simplifying the merging of TSCH with a
protocol stack based on IPv6, 6LoWPAN, and RPL.
2. TSCH in the LLN Context
To map the services required by the IP layer to the services provided
by the link layer, an adaptation layer is used
[palattella12standardized]. The 6LoWPAN working group started
working in 2007 on specifications for transmitting IPv6 packets over
IEEE802.15.4 networks [RFC4919]. Low-power Wireless Personal Area
Networks (WPANs) typically feature small frame sizes, support for
addresses with different lengths, low bandwidth, star and mesh
topologies, battery powered devices, low cost, large number of
devices, unknown node positions, high unreliability, and periods
during which communication interfaces are turned off to save energy.
Given these features, it is clear that the adoption of IPv6 on top of
a Low-Power WPAN is not straightforward, but poses strong
requirements for the optimization of this adaptation layer.
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For instance, due to the IPv6 default minimum MTU size (1280 bytes),
an un-fragmented IPv6 packet is too large to fit in an IEEE802.15.4
frame. Moreover, the overhead due to the 40-byte long IPv6 header
wastes the scarce bandwidth available at the PHY layer [RFC4944].
For these reasons, the 6LoWPAN working group has defined an effective
adaptation layer [RFC6282]. Further issues encompass the auto-
configuration of IPv6 addresses [RFC2460][RFC4862], the compliance
with the recommendation on supporting link-layer subnet broadcast in
shared networks [RFC3819], the reduction of routing and management
overhead [RFC6606], the adoption of lightweight application protocols
(or novel data encoding techniques), and the support for security
mechanisms (confidentiality and integrity protection, device
bootstrapping, key establishment, and management).
These features can run on top of TSCH. There are, however, important
issues to solve, as highlighted in Section 3.
Routing issues are challenging for 6LoWPAN, given the low-power and
lossy radio links, the battery-powered nodes, the multi-hop mesh
topologies, and the frequent topology changes due to mobility.
Successful solutions take into account the specific application
requirements, along with IPv6 behavior and 6LoWPAN mechanisms
[palattella12standardized]. The ROLL working group has defined RPL
in [RFC6550]. RPL can support a wide variety of link layers,
including ones that are constrained, potentially lossy, or typically
utilized in conjunction with host or router devices with very limited
resources, as in building/home automation [RFC5867][RFC5826],
industrial environments [RFC5673], and urban applications [RFC5548].
RPL is able to quickly build up network routes, distribute routing
knowledge among nodes, and adapt to a changing topology. In a
typical setting, nodes are connected through multi-hop paths to a
small set of root devices, which are usually responsible for data
collection and coordination. For each of them, a Destination
Oriented Directed Acyclic Graph (DODAG) is created by accounting for
link costs, node attributes/status information, and an Objective
Function, which maps the optimization requirements of the target
scenario.
The topology is set up based on a Rank metric, which encodes the
distance of each node with respect to its reference root, as
specified by the Objective Function. Regardless of the way it is
computed, the Rank monotonically decreases along the DODAG towards
the root, building a gradient. RPL encompasses different kinds of
traffic and signaling information. Multipoint-to-Point (MP2P) is the
dominant traffic in LLN applications. Data is routed towards nodes
with some application relevance, such as the LLN gateway to the
larger Internet, or to the core of private IP networks. In general,
these destinations are the DODAG roots and act as data collection
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points for distributed monitoring applications. Point-to-Multipoint
(P2MP) data streams are used for actuation purposes, where messages
are sent from DODAG roots to destination nodes. Point-to-Point (P2P)
traffic allows communication between two devices belonging to the
same LLN, such as a sensor and an actuator. A packet flows from the
source to the common ancestor of those two communicating devices,
then downward towards the destination. RPL therefore has to discover
both upward routes (i.e. from nodes to DODAG roots) in order to
enable MP2P and P2P flows, and downward routes (i.e. from DODAG roots
to nodes) to support P2MP and P2P traffic.
Section 3 highlights the challenges that need to be addressed to use
RPL on top of TSCH.
Open-source initiatives have emerged around TSCH, with the OpenWSN
project [OpenWSN][OpenWSNETT] being the first open-source
implementation of a standards-based protocol stack. This
implementation was used as the foundation for an IP for Smart Objects
Alliance (IPSO) [IPSO] interoperability event in 2011. In the
absence of a standardized scheduling mechanism for TSCH, a "slotted
Aloha" schedule was used.
3. Problems and Goals
As highlighted in Appendix A, TSCH differs from other low-power MAC
protocols because of its scheduled nature. TSCH defines the
mechanisms to execute a communication schedule, yet it is the entity
that sets up that schedule which controls the topology of the
network. This scheduling entity also controls the resources
allocated to each link in that topology.
How this entity should operate is out of scope of TSCH. The
remainder of this section highlights the problems this entity needs
to address. For simplicity, we refer to this entity by the generic
name "LLC". Note that the 6top sublayer, currently being defined in
[I-D.wang-6tisch-6top-sublayer], can be seen as an embodiment of this
generic "LLC".
Some of the issues the LLC needs to target might overlap with the
scope of other protocols (e.g., 6LoWPAN, RPL, and RSVP). In this
case, it is entailed that the LLC will profit from the services
provided by other protocols to pursue these objectives.
3.1. Network Formation
The LLC needs to control the way the network is formed, including how
new nodes join, and how already joined nodes advertise the presence
of the network. The LLC needs to:
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1. Define the Information Elements included in the Enhanced Beacons
[IEEE802154e] advertising the presence of the network.
2. For a new node, define rules to process and filter received
Enhanced Beacons.
3. Define the joining procedure. This might include a mechanism to
assign a unique 16-bit address to a node, and the management of
initial keying material.
4. Define a mechanism to secure the joining process and the
subsequent optional process of scheduling more communication
cells.
3.2. Network Maintenance
Once a network is formed, the LLC needs to maintain the network's
health, allowing for nodes to stay synchronized. The LLC needs to:
1. Manage each node's time source neighbor.
2. Define a mechanism for a node to update the join priority it
announces in its Enhanced Beacon.
3. Schedule transmissions of Enhanced Beacons to advertise the
presence of the network.
3.3. Multi-Hop Topology
RPL, given a weighted connectivity graph, determines multi-hop
routes. The LLC needs to:
1. Define a mechanism to gather topological information, node and
link state, which it can then feed to RPL.
2. Ensure that the TSCH schedule contains cells along the multi-hop
routes identified by RPL (a cell in a TSCH schedule is an atomic
"unit" of resource, see Section 3.5).
3. Where applicable, maintain independent sets of cells to transport
independent flows of data.
3.4. Routing and Timing Parents
At all times, a TSCH node needs to have a time source neighbor it can
synchronize to. The LLC therefore needs to assign a time source
neighbor to allow for correct operation of the TSCH network. A time
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source neighbors could, or not, be taken from the RPL routing parent
set.
3.5. Resource Management
A cell in a TSCH schedule is an atomic "unit" of resource. The
number of cells to assign between neighbor nodes needs to be
appropriate for the size of the traffic flow. The LLC needs to:
1. Define a mechanism for neighbor nodes to exchange information
about their schedule and, if applicable, negotiate the addition/
deletion of cells.
2. Allow for an entity (e.g., a set of devices, a distributed
protocol, a Path Computation Element (PCE), etc.) to take control
of the schedule.
3.6. Dataflow Control
TSCH defines mechanisms for a node to signal it cannot accept an
incoming packet. It does not, however, define the policy which
determines when to stop accepting packets. The LLC needs to:
1. Allow for the implementation and configuration of policy to queue
incoming and outgoing packets.
2. Manage the buffer space, and indicate to TSCH when to stop
accepting incoming packets.
3. Handle transmissions that have failed. A transmission is
declared failed when TSCH has retransmitted the packet multiple
times, without receiving an acknowledgment. This covers both
dedicated and shared cells.
3.7. Deterministic Behavior
As highlighted in [RFC5673], in some applications, data is generated
periodically and has a well understood data bandwidth requirement,
which is deterministic and predictable. The LLC needs to:
1. Ensure that the data is delivered to its final destination before
a deadline possibly determined by the application.
2. Provide a mechanism for such deterministic flows to coexist with
bursty or infrequent traffic flows of different priorities.
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3.8. Scheduling Mechanisms
Several scheduling mechanisms can be envisioned, and possibly coexist
in the same network. For example,
[I-D.phinney-roll-rpl-industrial-applicability] describes how the
allocation of bandwidth can be optimized by an external Path
Computation Element (PCE) [RFC4655]. Another centralized (PCE-based)
traffic-aware scheduling algorithm is defined in [TASA-PIMRC].
Alternatively, two neighbor nodes can adapt the number of cells
autonomously by monitoring the amount of traffic, and negotiating the
allocation to extra cell when needed. An example of decentralized
algorithm (i.e. no PCE is needed) is provided in
[tinka10decentralized]. This mechanism can be used to establish
multi-hop paths in a fashion similar to RSVP [RFC2205]. The LLC
needs to:
1. Provide a mechanism for two devices to negotiate the allocation
and deallocation of cells between them.
2. Provide a mechanism for device to monitor and manage the
capabilities of a node several hops away.
3. Define an mechanism for these different scheduling mechanisms to
coexist in the same network.
3.9. Secure Communication
Given some keying material, TSCH defines mechanisms to encrypt and
authenticate MAC frames. It does not define how this keying material
is generated. The LLC needs to:
1. Define the keying material and authentication mechanism needed by
a new node to join an existing network.
2. Define a mechanism to allow for the secure transfer of
application data between neighbor nodes.
3. Define a mechanism to allow for the secure transfer of signaling
data between nodes and the LLC.
4. IANA Considerations
This memo includes no request to IANA.
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5. Security Considerations
This memo is an informational overview of existing standards, and
does not define any new mechanisms or protocols.
It does describe the need for the 6TiSCH WG to define a secure
solution. In particular, Section 3.1 describes security in the join
process. Section 3.9 discusses data frame protection.
6. Acknowledgments
Special thanks to Dominique Barthel, Patricia Brett, Guillaume
Gaillard, Pat Kinney, Ines Robles, Timothy J. Salo, Jonathan Simon,
Rene Struik, Xavi Vilajosana for reviewing the document and providing
valuable feedback. Thanks to the IoT6 European Project (STREP) of
the 7th Framework Program (Grant 288445).
7. References
7.1. Normative References
[IEEE802154e]
IEEE standard for Information Technology, "IEEE std.
802.15.4e, Part. 15.4: Low-Rate Wireless Personal Area
Networks (LR-WPANs) Amendment 1: MAC sublayer", April
2012.
[IEEE802154]
IEEE standard for Information Technology, "IEEE std.
802.15.4, Part. 15.4: Wireless Medium Access Control (MAC)
and Physical Layer (PHY) Specifications for Low-Rate
Wireless Personal Area Networks", June 2011.
7.2. Informative References
[RFC7252] Shelby, Z., Hartke, K., and C. Bormann, "The Constrained
Application Protocol (CoAP)", RFC 7252, June 2014.
[RFC7228] Bormann, C., Ersue, M., and A. Keranen, "Terminology for
Constrained-Node Networks", RFC 7228, May 2014.
[RFC7102] Vasseur, JP., "Terms Used in Routing for Low-Power and
Lossy Networks", RFC 7102, January 2014.
[RFC6606] Kim, E., Kaspar, D., Gomez, C., and C. Bormann, "Problem
Statement and Requirements for IPv6 over Low-Power
Wireless Personal Area Network (6LoWPAN) Routing", RFC
6606, May 2012.
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[RFC6550] Winter, T., Thubert, P., Brandt, A., Hui, J., Kelsey, R.,
Levis, P., Pister, K., Struik, R., Vasseur, JP., and R.
Alexander, "RPL: IPv6 Routing Protocol for Low-Power and
Lossy Networks", RFC 6550, March 2012.
[RFC6282] Hui, J. and P. Thubert, "Compression Format for IPv6
Datagrams over IEEE 802.15.4-Based Networks", RFC 6282,
September 2011.
[RFC5867] Martocci, J., De Mil, P., Riou, N., and W. Vermeylen,
"Building Automation Routing Requirements in Low-Power and
Lossy Networks", RFC 5867, June 2010.
[RFC5826] Brandt, A., Buron, J., and G. Porcu, "Home Automation
Routing Requirements in Low-Power and Lossy Networks", RFC
5826, April 2010.
[RFC5673] Pister, K., Thubert, P., Dwars, S., and T. Phinney,
"Industrial Routing Requirements in Low-Power and Lossy
Networks", RFC 5673, October 2009.
[RFC5548] Dohler, M., Watteyne, T., Winter, T., and D. Barthel,
"Routing Requirements for Urban Low-Power and Lossy
Networks", RFC 5548, May 2009.
[RFC4944] Montenegro, G., Kushalnagar, N., Hui, J., and D. Culler,
"Transmission of IPv6 Packets over IEEE 802.15.4
Networks", RFC 4944, September 2007.
[RFC4919] Kushalnagar, N., Montenegro, G., and C. Schumacher, "IPv6
over Low-Power Wireless Personal Area Networks (6LoWPANs):
Overview, Assumptions, Problem Statement, and Goals", RFC
4919, August 2007.
[RFC4862] Thomson, S., Narten, T., and T. Jinmei, "IPv6 Stateless
Address Autoconfiguration", RFC 4862, September 2007.
[RFC4655] Farrel, A., Vasseur, J., and J. Ash, "A Path Computation
Element (PCE)-Based Architecture", RFC 4655, August 2006.
[RFC3819] Karn, P., Bormann, C., Fairhurst, G., Grossman, D.,
Ludwig, R., Mahdavi, J., Montenegro, G., Touch, J., and L.
Wood, "Advice for Internet Subnetwork Designers", BCP 89,
RFC 3819, July 2004.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", RFC 2460, December 1998.
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[RFC2205] Braden, B., Zhang, L., Berson, S., Herzog, S., and S.
Jamin, "Resource ReSerVation Protocol (RSVP) -- Version 1
Functional Specification", RFC 2205, September 1997.
[I-D.ietf-6tisch-terminology]
Palattella, M., Thubert, P., Watteyne, T., and Q. Wang,
"Terminology in IPv6 over the TSCH mode of IEEE
802.15.4e", draft-ietf-6tisch-terminology-03 (work in
progress), January 2015.
[I-D.wang-6tisch-6top-sublayer]
Wang, Q., Vilajosana, X., and T. Watteyne, "6TiSCH
Operation Sublayer (6top)", draft-wang-6tisch-6top-
sublayer-01 (work in progress), July 2014.
[I-D.phinney-roll-rpl-industrial-applicability]
Phinney, T., Thubert, P., and R. Assimiti, "RPL
applicability in industrial networks", draft-phinney-roll-
rpl-industrial-applicability-02 (work in progress),
February 2013.
[OpenWSN] "Berkeley's OpenWSN Project Homepage",
<http://www.openwsn.org/>.
[OpenWSNETT]
Watteyne, T., Vilajosana, X., Kerkez, B., Chraim, F.,
Weekly, K., Wang, Q., Glaser, S., and K. Pister, "OpenWSN:
a Standards-Based Low-Power Wireless Development
Environment", Transactions on Emerging Telecommunications
Technologies , August 2012.
[IPSO] "IP for Smart Objects Alliance Homepage",
<http://www.ipso-alliance.org/>.
[CurrentCalculator]
Linear Technology, "Application Note: Using the Current
Calculator to Estimate Mote Power", August 2012,
<http://www.linear.com/docs/42452>.
[doherty07channel]
Doherty, L., Lindsay, W., and J. Simon, "Channel-Specific
Wireless Sensor Network Path Data", IEEE International
Conference on Computer Communications and Networks (ICCCN)
2008, 2007.
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[tinka10decentralized]
Tinka, A., Watteyne, T., and K. Pister, "A Decentralized
Scheduling Algorithm for Time Synchronized Channel
Hopping", Ad Hoc Networks 2010, 2010.
[watteyne09reliability]
Watteyne, T., Mehta, A., and K. Pister, "Reliability
Through Frequency Diversity: Why Channel Hopping Makes
Sense", International Conference on Performance Evaluation
of Wireless Ad Hoc, Sensor, and Ubiquitous Networks (PE-
WASUN) 2009, Oct. 2009.
[TASA-PIMRC]
Palattella, MR., Accettura, N., Dohler, M., Grieco, LA.,
and G. Boggia, "Traffic Aware Scheduling Algorithm for
Multi-Hop IEEE 802.15.4e Networks", IEEE PIMRC 2012, Sept.
2012.
[palattella12standardized]
Palattella, MR., Accettura, N., Vilajosana, X., Watteyne,
T., Grieco, LA., Boggia, G., and M. Dohler, "Standardized
Protocol Stack For The Internet Of (Important) Things",
IEEE Communications Surveys and Tutorials 2012, Dec. 2012.
Appendix A. TSCH Protocol Highlights
This appendix gives an overview of the key features of the
IEEE802.15.4e Timeslotted Channel Hopping (TSCH) amendment. It makes
no attempt at repeating the standard, but rather focuses on the
following:
o Concepts which are sufficiently different from other IEEE802.15.4
networking that they may need to be defined and presented
precisely.
o Techniques and ideas which are part of IEEE802.15.4e and which
might be useful for the work of the 6TiSCH WG.
A.1. Timeslots
All nodes in a TSCH network are synchronized. Time is sliced up into
timeslots. A timeslot is long enough for a MAC frame of maximum size
to be sent from node A to node B, and for node B to reply with an
acknowledgment (ACK) frame indicating successful reception.
The duration of a timeslot is not defined by the standard. With
IEEE802.15.4-compliant radios operating in the 2.4GHz frequency band,
a maximum-length frame of 127 bytes takes about 4ms to transmit; a
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shorter ACK takes about 1ms. With a 10ms slot (a typical duration),
this leaves 5ms to radio turnaround, packet processing and security
operations.
A.2. Slotframes
Timeslots are grouped into one of more slotframes. A slotframe
continuously repeats over time. TSCH does not impose a slotframe
size. Depending on the application needs, these can range from 10s
to 1000s of timeslots. The shorter the slotframe, the more often a
timeslot repeats, resulting in more available bandwidth, but also in
a higher power consumption.
A.3. Node TSCH Schedule
A TSCH schedule instructs each node what to do in each timeslot:
transmit, receive or sleep. The schedule indicates, for each
scheduled (transmit or receive) cell, a channelOffset and the address
of the neighbor to communicate with.
Once a node obtains its schedule, it executes it:
o For each transmit cell, the node checks whether there is a packet
in the outgoing buffer which matches the neighbor written in the
schedule information for that timeslot. If there is none, the
node keeps its radio off for the duration of the timeslot. If
there is one, the node can ask for the neighbor to acknowledge it,
in which case it has to listen for the acknowledgment after
transmitting.
o For each receive cell, the node listens for possible incoming
packets. If none is received after some listening period, it
shuts down its radio. If a packet is received, addressed to the
node, and passes security checks, the node can send back an
acknowledgment.
How the schedule is built, updated and maintained, and by which
entity, is outside of the scope of the IEEE802.15.4e standard.
A.4. Cells and Bundles
Assuming the schedule is well built, if node A is scheduled to
transmit to node B at slotOffset 5 and channelOffset 11, node B will
be scheduled to receive from node A at the same slotOffset and
channelOffset.
A single element of the schedule characterized by a slotOffset and
channelOffset, and reserved for node A to transmit to node B (or for
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node B to receive from node A) within a given slotframe, is called a
"scheduled cell".
If there is a lot of data flowing from node A to node B, the schedule
might contain multiple cells from A to B, at different times.
Multiple cells scheduled to the same neighbor can be equivalent, i.e.
the MAC layer sends the packet on whichever of these cells shows up
first after the packet was put in the MAC queue. The union of all
cells between two neighbors, A and B, is called a "bundle". Since
the slotframe repeats over time (and the length of the slotframe is
typically constant), each cell gives a "quantum" of bandwidth to a
given neighbor. Modifying the number of equivalent cells in a bundle
modifies the amount of resources allocated between two neighbors.
A.5. Dedicated vs. Shared Cells
By default, each scheduled transmit cell within the TSCH schedule is
dedicated, i.e., reserved only for node A to transmit to node B.
IEEE802.15.4e allows also to mark a cell as shared. In a shared
cell, multiple nodes can transmit at the same time, on the same
frequency. To avoid contention, TSCH defines a back-off algorithm
for shared cells.
A scheduled cell can be marked as both transmitting and receiving.
In this case, a node transmits if it has an appropriate packet in its
output buffer, or listens otherwise. Marking a cell as
[transmit,receive,shared] results in slotted-Aloha behavior.
A.6. Absolute Slot Number
TSCH defines a timeslot counter called Absolute Slot Number (ASN).
When a new network is created, the ASN is initialized to 0; from then
on, it increments by 1 at each timeslot. In detail:
ASN = (k*S+t)
where k is the slotframe cycle (i.e., the number of slotframe
repetitions since the network was started), S the slotframe size and
t the slotOffset. A node learns the current ASN when it joins the
network. Since nodes are synchronized, they all know the current
value of the ASN, at any time. The ASN is encoded as a 5-byte
number: this allows it to increment for hundreds of years (the exact
value depends on the duration of a timeslot) without wrapping over.
The ASN is used to calculate the frequency to communicate on, and can
be used for security-related operations.
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A.7. Channel Hopping
For each scheduled cell, the schedule specifies a slotOffset and a
channelOffset. In a well-built schedule, when node A has a transmit
cell to node B on channelOffset 5, node B has a receive cell from
node A on the same channelOffset. The channelOffset is translated by
both nodes into a frequency using the following function:
frequency = F {(ASN + channelOffset) mod nFreq}
The function F consists of a look-up table containing the set of
available channels. The value nFreq (the number of available
frequencies) is the size of this look-up table. There are as many
channelOffset values as there are frequencies available (e.g. 16 when
using IEEE802.15.4-compliant radios at 2.4GHz, when all channels are
used). Since both nodes have the same channelOffset written in their
schedule for that scheduled cell, and the same ASN counter, they
compute the same frequency. At the next iteration (cycle) of the
slotframe, however, while the channelOffset is the same, the ASN has
changed, resulting in the computation of a different frequency.
This results in "channel hopping": even with a static schedule, pairs
of neighbors "hop" between the different frequencies when
communicating. A way of ensuring communication happens on all
available frequencies is to set the number of timeslots in a
slotframe to a prime number. Channel hopping is a technique known to
efficiently combat multi-path fading and external interference
[watteyne09reliability].
A.8. Time Synchronization
Because of the slotted nature of communication in a TSCH network,
nodes have to maintain tight synchronization. All nodes are assumed
to be equipped with clocks to keep track of time. Yet, because
clocks in different nodes drift with respect to one another, neighbor
nodes need to periodically re-synchronize.
Each node needs to periodically synchronize its network clock to
another node, and it also provides its network time to its neighbors.
It is up to the entity that manages the schedule to assign an
adequate time source neighbor to each node, i.e., to indicate in the
schedule which of neighbor is its "time source neighbor". While
setting the time source neighbor, it is important to avoid
synchronization loops, which could result in the formation of
independent clusters of synchronized nodes.
TSCH adds timing information in all packets that are exchanged (both
data and ACK frames). This means that neighbor nodes can
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resynchronize to one another whenever they exchange data. In detail,
two methods are defined in IEEE802.15.4e-2012 for allowing a device
to synchronize in a TSCH network: (i) Acknowledgment-Based and (ii)
Frame-Based synchronization. In both cases, the receiver calculates
the difference in time between the expected time of frame arrival and
its actual arrival. In Acknowledgment-Based synchronization, the
receiver provides such information to the sender node in its
acknowledgment. In this case, it is the sender node that
synchronizes to the clock of the receiver. In Frame-Based
synchronization, the receiver uses the computed delta for adjusting
its own clock. In this case, it is the receiver node that
synchronizes to the clock of the sender.
Different synchronization policies are possible. Nodes can keep
synchronization exclusively by exchanging EBs. Nodes can also keep
synchronized by periodically sending valid frames to a time source
neighbor and use the acknowledgment to resynchronize. Both method
(or a combination thereof) are valid synchronization policies; which
one to use depends on network requirements.
A.9. Power Consumption
There are only a handful of activities a node can perform during a
timeslot: transmit, receive, or sleep. Each of these operations has
some energy cost associated to them, the exact value depends on the
the hardware used. Given the schedule of a node, it is
straightforward to calculate the expected average power consumption
of that node.
A.10. Network TSCH Schedule
The schedule entirely defines the synchronization and communication
between nodes. By adding/removing cells between neighbors, one can
adapt a schedule to the needs of the application. Intuitive examples
are:
o Make the schedule "sparse" for applications where nodes need to
consume as little energy as possible, at the price of reduced
bandwidth.
o Make the schedule "dense" for applications where nodes generate a
lot of data, at the price of increased power consumption.
o Add more cells along a multi-hop route over which many packets
flow.
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A.11. Join Process
Nodes already part of the network can periodically send Enhanced
Beacon (EB) frames to announce the presence of the network. These
contain information about the size of the timeslot used in the
network, the current ASN, information about the slotframes and
timeslots the beaconing node is listening on, and a 1-byte join
priority. The join priority field gives information to make a better
decision of which node to join. Even if a node is configured to send
all EB frames on the same channel offset, because of the channel
hopping nature of TSCH described in Appendix A.7, this channel offset
translates into a different frequency at different slotframe cycles.
As a result, EB frames are sent on all frequencies.
A node wishing to join the network listens for EBs. Since EBs are
sent on all frequencies, the joining node can listen on any frequency
until it hears an EB. What frequency it listens on is
implementation-specific. Once it has received one or more EBs, the
new node enables the TSCH mode and uses the ASN and the other timing
information from the EB to synchronize to the network. Using the
slotframe and cell information from the EB, it knows how to contact
other nodes in the network.
The IEEE802.15.4e TSCH standard does not define the steps beyond this
network "bootstrap".
A.12. Information Elements
TSCH introduces the concept of Information Elements (IEs). An
information element is a list of Type-Length-Value containers placed
at the end of the MAC header. A small number of types are defined
for TSCH (e.g., the ASN in the EB is contained in an IE), and an
unmanaged range is available for extensions.
A data bit in the MAC header indicates whether the frame contains
IEs. IEs are grouped into Header IEs, consumed by the MAC layer and
therefore typically invisible to the next higher layer, and Payload
IEs, which are passed untouched to the next higher layer, possibly
followed by regular payload. Payload IEs can therefore be used for
the next higher layers of two neighbor nodes to exchange information.
A.13. Extensibility
The TSCH standard is designed to be extensible. It introduces the
mechanisms as "building block" (e.g., cells, bundles, slotframes,
etc.), but leaves entire freedom to the upper layer to assemble
those. The MAC protocol can be extended by defining new Header IEs.
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An intermediate layer can be defined to manage the MAC layer by
defining new Payload IEs.
Appendix B. TSCH Features
This section details features of IEEE802.15.4e TSCH which might be
interesting for the work of the 6TiSCH WG. It does not define any
requirements.
B.1. Collision Free Communication
TSCH allows one to design a schedule which yields collision-free
communication. This is done by building the schedule with dedicated
cells in such a way that at most one node communicates with a
specific neighbor in each slotOffset/channelOffset cell. Multiple
pairs of neighbor nodes can exchange data at the same time, but on
different frequencies.
B.2. Multi-Channel vs. Channel Hopping
A TSCH schedule looks like a matrix of width "slotframe size", S, and
of height "number of frequencies", nFreq. For a scheduling
algorithm, cells can be considered atomic "units" to schedule. In
particular, because of the channel hopping nature of TSCH, the
scheduling algorithm should not worry about the actual frequency
communication happens on, since it changes at each slotframe
iteration.
B.3. Cost of (continuous) Synchronization
When there is traffic in the network, nodes which are communicating
implicitly re-synchronize using the data frames they exchange. In
the absence of data traffic, nodes are required to synchronize to
their time source neighbor(s) periodically not to drift in time. If
they have not been communicating for some time (typically 30s), nodes
can exchange an dummy data frame to re-synchronize. The frequency at
which such messages need to be transmitted depends on the stability
of the clock source, and on how "early" each node starts listening
for data (the "guard time"). Theoretically, with a 10ppm clock and a
1ms guard time, this period can be 100s. Assuming this exchange
causes the node's radio to be on for 5ms, this yields a radio duty
cycle needed to keep synchronized of 5ms/100s=0.005%. While TSCH does
requires nodes to resynchronize periodically, the cost of doing so is
very low.
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B.4. Topology Stability
The channel hopping nature of TSCH causes links to be very "stable".
Wireless phenomena such as multi-path fading and external
interference impact a wireless link between two nodes differently on
each frequency. If a transmission from node A to node B fails,
retransmitting on a different frequency has a higher likelihood of
succeeding that retransmitting on the same frequency. As a result,
even when some frequencies are "behaving bad", channel hopping
"smoothens" the contribution of each frequency, resulting in more
stable links, and therefore a more stable topology.
B.5. Multiple Concurrent Slotframes
The TSCH standard allows for multiple slotframes to coexist in a
node's schedule. It is possible that, at some timeslot, a node has
multiple activities scheduled (e.g. transmit to node B on slotframe
2, receive from node C on slotframe 1). To handle this situation,
the TSCH standard defines the following precedence rules:
1. Transmissions take precedence over receptions;
2. Lower slotframe identifiers take precedence over higher slotframe
identifiers.
In the example above, the node would transmit to node B on slotframe
2.
Authors' Addresses
Thomas Watteyne (editor)
Linear Technology
32990 Alvarado-Niles Road, Suite 910
Union City, CA 94587
USA
Phone: +1 (510) 400-2978
Email: twatteyne@linear.com
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Maria Rita Palattella
University of Luxembourg
Interdisciplinary Centre for Security, Reliability and Trust
4, rue Alphonse Weicker
Luxembourg L-2721
LUXEMBOURG
Phone: +352 46 66 44 5841
Email: maria-rita.palattella@uni.lu
Luigi Alfredo Grieco
Politecnico di Bari
Department of Electrical and Information Engineering
Via Orabona 4
Bari 70125
Italy
Phone: +39 08 05 96 3911
Email: a.grieco@poliba.it
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