HotOS X Paper   
[HotOS X Final Program]
Towards a Sensor Network Architecture:
Lowering the Waistline
David Culler*, Prabal Dutta*, Cheng Tien Eee*, Rodrigo Fonseca*, Jonathan Hui*, Philip Levis*, Joseph Polastre*, Scott Shenker*, Ion Stoica*, Gilman Tolle*, and Jerry Zhao
Wireless sensor networks have the potential to be tremendously
beneficial to society. Embedded sensing will enable new scientific
exploration, lead to better engineering, improve productivity, and
enhance security. Research in sensor networks has made dramatic
progress in the past decade, bringing these possibilities closer to
reality. Hardware, particularly radio technology, is improving
rapidly, leading to cheaper, faster, smaller, and longer-lasting
nodes. Many systems challenges, such as robust multihop routing,
effective power management, precise time synchronization, and
efficient in-network query processing, have stable and compelling
solutions. Several complete applications have been deployed that
demonstrate all of these research accomplishments integrated into a
coherent system, including some at relatively large
scale[5,17].
But the situation in sensornets, while promising, also has problems.
The literature presents an alphabet soup of protocols and subsystems
that make widely differing assumptions about the rest of the system
and how its parts should interact. The extent to which these parts can
be combined to build usable systems is quite limited. In order to
produce running systems, research groups have produced vertically
integrated designs in which their own set of components are
specifically designed to work together, but are unable to interoperate
with the work of others. This inherent incompatibility greatly reduces
the synergy possible between research efforts and impedes progress.
It is the central tenet of this paper that the primary factor
currently limiting research progress in sensornets today is not any
specific technical challenge (though many remain, and deserve much
further study) but is instead the lack of an overall sensor
network architecture. Such an architecture would identify the
essential services and their conceptual relationships. Such a
decomposition would make it possible to compose components in a manner
that promotes interoperability, transcends generations of technology,
and allows innovation.
At the highest level, an architecture decomposes a problem domain into
a set of services, which are functional components, their
mechanisms and their responsibilities. An architecture can also define
a set of interfaces to its services, which are the structures
and functions services expose their mechanisms with. Finally, at the
lowest level, an architecture can specify its protocols, which
include packet formats, communication exchanges, and state machines.
For interfaces and protocols, we say an architecture can define
them because sometimes it is advantageous not to. For example, the
Internet architecture precisely defines IP as a service (end-to-end
communication, best-effort delivery, fragmentation/defragmentation,
etc.) and as a protocol (packet format and semantics), but is
ambivalent to the IP interface. Given the Internet's principal design
goal -- it is a network interconnection architecture -- this
ambivalence makes sense: IP does not want to dictate what software
runs on each host.
In contrast to the Internet architecture, which seeks to promote
communication interoperability, the POSIX architecture cares about
software interoperability. Correspondingly, it cares greatly about
interfaces while remaining ambivalent about the protocols. For
example, the sockets service for end-to-end communication provides a
precise interface, but has several underlying protocols (e.g., local
communication, TCP, etc.).
The challenge in sensor networks is that their modes of operation
introduce requirements and tradeoffs are very different from
traditional systems. A sensor network application dictates sensor
modalities, sample rates, real-time processing, data storage,
and information exchange protocols among nodes. Early vision papers
and analyses claimed that the traditional application/OS and
network/data-link divisions are not well suited to sensor
networks [3,7], and community
experiences building protocols and applications have shown this claim
to be true [11,16,18,27].
Thus, current sensor network software systems, such as
TinyOS [9] relax these divisions and give developers the
flexibility to define new ones. This relaxation has allowed
researchers to re-examine core issues in scheduling, power-control,
and information flow by cutting across traditional service
boundaries [14].
Cutting across boundaries, however, has led to monolithic solutions or
to subsystem components with arbitrary interface assumptions. While
research groups have each been able to build large and complex
systems, the resulting services, interfaces, and protocols are
incompatible with each other. For future work to be able to build on
the prior efforts of others, we need a sensor network architecture,
which will re-establish a meaningful separation of concerns.
The Internet architecture demonstrated how a properly chosen set of
guiding principles and services can shape the evolution of a complex
system over vast changes in technology, scale, and
usage [2]. The philosophy of designing for
heterogeneity, change and uncertainty was a radical shift from
classical systems design, which more traditionally seeks a near
optimal assembly of near optimal parts. Faced with integrating several
existing networks with widely varying characteristics, the end-to-end
principle and focus on interoperability led to a design that has
successfully coped with tremendous growth and change. However, this
design is not free of costs; the use of rigid layering sacrifices
efficiency in various regards in return for increased
interoperability.
The power of the Internet is revealed not so much in the elegance or
efficiency of its individual services, but in its overall ability to
adapt. This is one of our goals for developing an architecture for
sensornets. We must be extremely mindful of any loss of efficiency for
particular tasks as we seek to greatly enhance the interoperability
between components and ability to advance.
The experiences and efforts of the sensor network community over the
past years has helped discover exactly how the requirements and
concerns of a sensor network architecture are different from the
Internet, and how they are the same. The challenge in defining a
sensor network architecture is deciding what to specify in its
services and what to leave open. Specifying too little will force
systems to re-implement functionality they cannot depend on, while
specifying too much will constrain future technologies and possibly
lead developers to discard the architecture. For this reason, we
expect developing an architecture to be at first a growing and organic
process. While conclusions from community experience have clearly
converged on some issues, such as packet timestamps, others, such as
aggregation, are still under debate. By starting with services (or
even parts of services) for which there is consensus, an architecture
will help focus the research debate on open problems, promoting
forward progress.
A complete sensornet architecture will need to address a family of
specific issues, such as discovery, topology management, naming,
routing and so on, but the over-riding question is whether there is a
``narrow waist'' -- a functional component representing a common
service that permits a wide variety of uses above and a range of
implementations below. At what level should it occur and what should
it express? By requiring all network technologies to support IP, and
all applications to run on top of IP, the Internet accommodates, even
encourages, a vast degree of heterogeneity and diversity in both
applications and underlying technologies.
We have an analogous goal for sensornets; in both the application and
device arenas we are in the midst of extremely rapid developments.
Sensornets will only flourish if we can identify a narrow waist in the
architecture that will allow devices and protocols to evolve and
change without hampering optimization. The Internet has shown that the
most important service of a network architecture is its narrow waist.
We claim that sensor networks can also have a narrow waist, the
Sensor-net Protocol (SP). Unlike IP, which is a multihop protocol
intended for end hosts communicating over a shared routing
infrastructure, SP is a single hop protocol. The reason for this
difference is simple: sensor networks use a wide range of multihop
protocols, such as dissemination [15], flooding, tree
routing [26], and aggregation [18].
Applications differ dramatically in their communication patterns and
are intimately tied to their associated network protocols. Most
applications neither require nor benefit from a common, universally
routable addressing scheme. Those that do can build such protocols on
top of SP.
The first step in developing our architecture is defining the SP
service by deciding which mechanisms and functionality it provides and
which it does not. Using SP, protocol designers must be able to design
a range of efficient routing protocols independently of the underlying
link layer. SP must facilitate in-network processing and collective
communication as well as point-to-point transport. Moving the point of
universal abstraction downward presents new issues that we do not
typically concern ourselves about in the Internet architecture. It
also requires a careful design of the layers above SP to provide a
reasonably general platform on which to build various sensor network
applications efficiently. If SP is to be a well defined service on
top of a range of physical layers, how functionality divides across
the packet boundary is a key question. To support the network
protocols found in the sensornet literature, the mechanisms which a
sender should be able to control include link level acknowledgments,
post-media arbitration timestamping, retransmission and power
management (cf. [20]). In addition to providing control points
downwards, SP needs to expose costs upwards to higher layers so
protocols can receive feedback on how to optimize their behavior as
they exercise the available control.
Figure 1:
Sensor Network Service Decomposition
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For example, it is clear from community experience that the SP service
must provide packet timestamps. Time synchronization
research [6,13] has shown that obtaining
high precision timestamps on packet transmission and reception is
inexpensive and can enable a wide range of synchronization algorithms
above. While the need for this information is clear, exactly how it
manifests is less so. There is consensus that when a node receives a
packet, the SP service must provide a receive timestamp. As this
timestamp is not a field of the packet that is received over the air,
it is part of the SP service but not the protocol. The point of debate
is on transmission. ETA [13] argues that transmitted packets
should contain the sender's timestamp, while
RBS [6] argues that this is unnecessary, as only
the transmitter needs to know its timestamp. While both agree
timestamps must be part of the SP service, ETA requires transmit
timestamps to be part of the SP protocol, while RBS does not.
SP sits below many multihop protocols. Allowing higher level protocols
to share control over an underlying communication medium raises
concern as to how these protocols work together and cooperate. This
is just the kind of investigation that the existence of SP would
promote. We suggest that this question is tractable and very
interesting in sensornets because they typically host a small number
of widely distributed applications. In the Internet, such control is
problematic because the infrastructure is shared by arbitrary
applications anywhere in the world. The application specific nature of
sensornets is more conducive to cross-layer and cross-application
customization.
Therefore, rather than immediately specify protocols, our development
of a sensor network architecture starts with defining SP as a service
and providing a possible interface to that service so developers can
test and evaluate it. Once, through literature analysis, communication
with the community, and, of course, trial and error, we determine the
boundaries of SP as a service, we can then focus on building and
evaluating different candidate SP interfaces and SP protocols. We have
begun this process by making a first attempt at defining SP as a
service [21]. Trying to define a common service on top
of very different underlying link layers (e.g., TDMA and CSMA) raises
interesting questions about networking in this regime and suggests
places where well-established networking terminology is ill-suited.
SP is the keystone of our sensor network architecture, bridging higher
level protocols and applications to underlying data link and physical
layers. Defining the SP service requires understanding the
requirements of applications that lie above it and the capabilities of
the technologies that lie below. Just as with IP, it is unlikely that
SP will be ideally suited to all of its possible uses. However, by
examining applications and their requirements, we can make educated
decisions on what tradeoffs SP makes between its above and below
pressures.
Applications today use a wide range of service layers, some of which
have no clear analogues in the OSI model. For example, several
commonly used communication services, such as collection
routing [26] and dissemination [15], are
address-free, in that, from the perspective from an application,
there is no explicit destination. Of course, there are also name-based
communication services, but the form and semantics of the naming are
very different than end-to-end communication.
Address-free and name-based communication represent traditional
service layers, which encapsulate underlying functionality. Our sensor
network architecture also has cross-layer services, which cut
across SP and indeed the entire architecture. Deployed applications
have demonstrated that there are pieces of information and
functionality which many different services require
concurrently. Establishing the concept of cross-layer services allows
existing approaches to continue while providing the structure
necessary to promote composability and reuse.
Figure 1 shows a possible decomposition of a sensor
network architecture. SP is the unifying service that bridges
protocols and applications to the underlying data link and physical
layers. Situated above SP are multiple network layer services, with
applications selecting specific ones that suite the networking needs
of the application. In Section 4.2, we discuss two of
these upper layer services, name-based and address-free protocols.
Situated below SP are underlying data link and physical layers, such
as 802.15.4 [25] or S-MAC [28]. The diversity of
functionality underlying layers present poses a variety of technical
challenges to SP's design, which we discuss and address in our
SP proposal [21].
In addition to the layered services above and below SP, the
architecture has cross-layer services, which
Figure 1 shows on the left side. Cross-layer
services include power management, timestamping/time synchronization,
and discovery. As we discuss further in Section 4.3, these
services are cross-layer in that they have uses across the entire
spectrum of service layers.
This decomposition is far from complete. As sensor networks evolve and
spread into new application domains, it is inevitable that new
services will emerge. Current and foreseen future uses motivate our
current decomposition, but it is also intended to be flexible enough
to engender growth.
Address-free and Name-based
Unlike an IP network, which supports a single network addressing
scheme and largely provides a single communication abstraction (i.e., unicast), applications developed so far use a variety of naming
schemes and multihop communication services. For example, the Line in
the Sand event detection application routed along a 2D
grid [5], the Great Duck Island habitat monitoring application
routed up a collection tree [17] and Pursuer Evader Game
tracking application used a landmark routing overlay on top of a
tree-building algorithm [23].
This variety in naming and multihop communication is one of the main
reasons behind our decision to push the narrow waist below the OSI
network layer. Lowering the narrow waist allows the architecture to
express and encompass this diversity both in the present and in the
future. Trading off between the requirements of higher level services
and the desire to keep SP as simple as possible is the principal first
challenge in developing the architecture. In the remainder of this
section, we describe two higher level services and how they might
influence SP. Key architectural issues that arise in designing these
services include route discovery and maintenance, naming, and the
packet forwarding rules.
The address-free service layer encompasses a wide range of protocols,
including flooding, collection routing [26],
dissemination [15], and
aggregation [4]. Although these protocols may
include names to refer to data items -- such as sequence numbers or
dispatch IDs -- they do not identify nodes directly. For example,
when an application wants to send a piece of data up a collection
tree, it does not need to specify a destination because it is
implicit: the node's parent in the tree. The underlying collection
tree routing protocol may address the parent directly, but it
encapsulates this naming and hides it from layers above.
Unlike collection routing, however, which typically names nodes at the
SP level, broadcast and dissemination protocols rely on the implicit
naming provided by local connectivity. This represents an interesting
SP design consideration, as some underlying MAC layers (e.g.,
TDMA-based MACs that turn off the radio) may not by themselves provide
an efficient local broadcast primitive. This tension between the
requirements of layers above and the capabilities of layers below
demonstrates some of the difficulties that designing SP presents.
The name-based service layer encompasses multihop communication based
on destination identifiers. This includes approaches such as
geographic routing [12] and logical coordinate
routing [8,19], as well as more abstract and flexible naming
schemes such as directed diffusion, which use data
identifiers [11]. Global network names are powerful
enough to support content-based storage within the sensor network, but
require any-to-any routing [22].
In addition to packet forwarding, a node along a path can inspect
received data and make local decisions regarding a packet based on its
contents, possibly transforming the data before forwarding it, or
suppressing it completely. This in-network processing can reduce
communication while keeping higher-level semantic requirements. For
example, when collecting a MAX query, which returns the maximum value
of some variable, nodes need only forward the highest value they
receive and suppress all other values.
The key observation is that the services above SP support very
different semantics than those found in the network layer services of
the Internet and OSI specifications. In particular, sensornets are
primarily concerned with dissemination, collection, aggregation, and
gradient-directed services, whereas the Internet is principally
concerned with end-to-end communication [1].
Cross-Layer Services
One novel aspect of our sensor network architecture is the concept of
cross-layer services. These services cut across layers or arise within
multiple layers. Instead of being fully encapsulated at one layer,
only visible to the layers above and below, cross-layer services are
accessible to all of the layers in the system. In this section, we use
power management to motivate the need for cross-layer services in a
sensor network architecture, describe some of the research challenges
they pose, and present timestamping as one example of such a service.
Energy constraints are a defining characteristic of sensor networks.
Traditionally, power aware networking has dealt with a single point in
the stack in isolation. This approach is not practical in sensornets
because power management often appears in many places and takes many
forms. Below SP, power aware MACs attempt to turn off the radio
invisibly to the stack above [24]. Within SP, buffering
multiple packets and sending them back-to-back in a burst can be more
efficient than sending them individually as they appear from the
network layer services [21]. Routing layers above SP
can have multihop flow information that allows them to schedule future
radio activity [10]. Applications can have their own scheduling
policies: TinyDB shuts down the whole networking stack between query
processing epochs [16].
As a consequence of its ubiquity, power management is particularly
challenging to abstract into a clean architectural concept. The
architecture must allow many different services from very different
levels to collaborate and work together. These services must therefore
be accessible to all levels of the system. On one hand, these services
must have policies to arbitrate between conflicting requests; on the
other, constraining the possible policies unnecessarily will hamper
future growth. An architecture must establish clear guiding principles
and sufficiently rich, yet loosely-coupled and appropriately
abstracted, interfaces to support cross layer services.
All of the power management approaches mentioned above use some form
of time synchronization to schedule communication. All of these time
synchronization algorithms depend on having accurate packet
timestamps. Therefore, these timestamps must be information that cuts
through layers so sub-SP as well as super-SP services can use
them. While time synchronization services can be situated above SP,
MAC-layer timestamping below SP greatly improves their
precision [13]. By choosing an to generate this data at an
idealized point in the communication stack (e.g., post media
arbitration) SP can achieve microsecond resolution inexpensively.
Timing information must cross layers so many services can take
advantage of them. The sensor network architecture therefore provides
it in cross-layer services. The preferred method of exposing
timestamps in the link interface, and more generally across the
architecture, is an important design point that must be addressed with
an eye toward removing any temptation for time coordination services
to circumvent SP. Power management is an example of a cross-layer
service for downward control; timestamps are an example of a
cross-layer service for upward information flow.
While this section presented only two cross layer abstractions, there
are many more that we need to address. Examples include system
management, discovery, and security. These services need to be
accessible to all of the layers in the system so their abstractions
present a central challenge to the architecture's design: developing a
methodology for providing interfaces rich enough for
application/system collaboration while remaining flexible enough to
encompass growth and evolve as time rolls forward.
We contend that the main obstacle limiting progress in sensornet work
is the lack of an architecture. A sensor network architecture would
factor out the key services required by applications and compose them
in a coherent structure, while allowing innovative technologies and
applications to evolve independently. We argue that the narrow waist
of this architecture should not be a network layer as in the current
Internet, but single-hop communication with a rich enough interface to
allow a diverse range of network protocols. This design decision is
driven by the fact that, unlike an IP network, sensornets require a
wide variety of naming schemes and multihop communication services.
However, there are many questions that need to be answered before such
an architecture becomes a reality. Chief among those are the
functionality provided by the SP service, the functional decomposition
of sensor networking into services now that the narrow waist is single
hop, and how cross-layers services such as timestamping can be
designed to enable a broad spectrum of uses while minimizing
complexity. Our hope and goal is that such an architecture will enable
research groups to more easily collaborate and build on each other's
efforts. Rather than a set of incompatible and vertically integrated
systems, we will in the near future see in sensor networks the variety
and innovation we see in the Internet today.
This work was supported by the National Science Foundation, under grant
CNS-043545.
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Footnotes
- * CS Division, UC Berkeley, Berkeley, CA 94720.
- ICSI, 1947 Center Street, Berkeley, CA 94704
Towards a Sensor Network Architecture:
Lowering the Waistline
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