ISO/IEC 29182-3:2014

DRAFT INTERNATIONAL STANDARD ISO/IEC DIS 29182-3
ISO/IEC JTC 1 Secretariat: ANSI

Voting begins on Voting terminates on
2013-01-14 2013-04-14
INTERNATIONAL ORGANIZATION FOR STANDARDIZATION • МЕЖДУНАРОДНАЯ ОРГАНИЗАЦИЯ ПО СТАНДАРТИЗАЦИИ • ORGANISATION INTERNATIONALE DE NORMALISATION
INTERNATIONAL ELECTROTECHNICAL COMMISSION • МЕЖДУНАРОДНАЯ ЭЛЕКТРОТЕХНИЧЕСКАЯ КОММИСИЯ • COMMISSION ÉLECTROTECHNIQUE INTERNATIONALE


Reference architecture for sensor network applications and
services —
Part 3:
Reference architecture views
Architecture de référence pour applications et services de réseaux de capteurs —
Partie 3: Vues de l'architecture de référence

ICS 35.110



To expedite distribution, this document is circulated as received from the committee
secretariat. ISO Central Secretariat work of editing and text composition will be undertaken at
publication stage.
Pour accélérer la distribution, le présent document est distribué tel qu'il est parvenu du
secrétariat du comité. Le travail de rédaction et de composition de texte sera effectué au
Secrétariat central de l'ISO au stade de publication.


THIS DOCUMENT IS A DRAFT CIRCULATED FOR COMMENT AND APPROVAL. IT IS THEREFORE SUBJECT TO CHANGE AND MAY NOT BE
REFERRED TO AS AN INTERNATIONAL STANDARD UNTIL PUBLISHED AS SUCH.
PURPOSES,
IN ADDITION TO THEIR EVALUATION AS BEING ACCEPTABLE FOR INDUSTRIAL, TECHNOLOGICAL, COMMERCIAL AND USER
DRAFT INTERNATIONAL STANDARDS MAY ON OCCASION HAVE TO BE CONSIDERED IN THE LIGHT OF THEIR POTENTIAL TO BECOME
STANDARDS TO WHICH REFERENCE MAY BE MADE IN NATIONAL REGULATIONS.
RECIPIENTS OF THIS DRAFT ARE INVITED TO SUBMIT, WITH THEIR COMMENTS, NOTIFICATION OF ANY RELEVANT PATENT RIGHTS OF WHICH
THEY ARE AWARE AND TO PROVIDE SUPPORTING DOCUMENTATION.
International Organization for Standardization, 2013
©
International Electrotechnical Commission, 2013

---------------------- Page: 1 ----------------------
ISO/IEC DIS 29182-3

Copyright notice
This ISO document is a Draft International Standard and is copyright-protected by ISO. Except as permitted
under the applicable laws of the user's country, neither this ISO draft nor any extract from it may be
reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic,
photocopying, recording or otherwise, without prior written permission being secured.
Requests for permission to reproduce should be addressed to either ISO at the address below or ISO's
member body in the country of the requester.
ISO copyright office
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Reproduction may be subject to royalty payments or a licensing agreement.
Violators may be prosecuted.
ii © ISO/IEC 2013 — All rights reserved

---------------------- Page: 2 ----------------------
ISO/IEC DIS 29182-3

Contents Page
Foreword . iv
Introduction . v
1 Scope . 1
2 Normative References . 1
3 Terms and Definitions . 1
4 Symbols (and abbreviated terms) . 1
5 Purpose of Sensor Network Reference Architecture . 3
6 Overview of Sensor Network Reference Architecture . 4
7 Business Architecture . 11
8 Information Architecture . 12
8.1 Application Architecture . 12
8.2 Data Architecture . 12
9 Technical Architecture . 13
9.1 Introduction . 13
9.1 Physical View . 16
9.2 System View . 17
9.3 System Functionality . 19
9.4 Technical View . 19
Bibliography . 21


© ISO/IEC 2012 – All rights reserved iii

---------------------- Page: 3 ----------------------
ISO/IEC DIS 29182-3

Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the International
Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2.
The main task of technical committees is to prepare International Standards. Draft International Standards
adopted by the technical committees are circulated to the member bodies for voting. Publication as an
International Standard requires approval by at least 75 % of the member bodies casting a vote.
Attention is drawn to the possibility that some of the elements of this document may be the subject of patent
rights. ISO shall not be held responsible for identifying any or all such patent rights.
ISO/IEC 29182-3 was prepared by Working Group ISO/IEC JTC 1/WG 7.
ISO/IEC 29182 consists of the following parts, under the general title Information technology — Sensor
networks: Sensor Network Reference Architecture (SNRA):
ISO/IEC 29182-1 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 1: General overview and requirements
ISO/IEC 29182-2 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 2: Vocabulary/Terminology
ISO/IEC 29182-3 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 3: Architecture Views
ISO/IEC 29182-4 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 4: Entity models
ISO/IEC 29182-5 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 5: Interface definitions
ISO/IEC 29182-6 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 6: Application profiles
ISO/IEC 29182-7 Information technology – Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 7: Interoperability Guidelines

iv © ISO/IEC 2012 – All rights reserved

---------------------- Page: 4 ----------------------
ISO/IEC DIS 29182-3

Introduction
A wide range of applications has been proposed for sensor networks. In practice, however, sensor networks
have been built and deployed for a relatively small number of applications. This is partly due to the lack of a
business case for certain applications and partly due to technical challenges in building a non-trivial sensor
network of reasonable complexity. The main reason for this impediment is multi-disciplinary expertise – such
as sensors, communications and networking, signal processing, electronics, computing, and cyber security –is
required to design a sensor network. Presently, the design process is so complex that one can leverage little
from one sensor network design to another. It appears as if one has to start from almost scratch every time
one wishes to design and deploy a sensor network. Yet, upon closer inspection, there are many
commonalities in instantiations of sensor networks that realize various applications. These commonalities
include similarities in the choice of network architecture and the entities/functional blocks that are used in the
architecture.
The purpose of the ISO/IEC 29182 family of International Standards (ISs) is to
 provide guidance to facilitate the design and development of sensor networks,
 improve interoperability of sensor networks, and
 make sensor networks plug-and-play, so that it becomes fairly easy to add/remove sensor nodes
to/from an existing sensor network.
The ISO/IEC 29182 family of standards can be used by sensor network designers, software developers, and
service providers to meet customer requirements, including any applicable interoperability requirements.
The ISO/IEC 29182 family of standards is comprised of seven parts. Brief descriptions of these parts are
given next, followed by an introduction to Part 4.
Part 1 provides a general overview and the requirements for the sensor network reference architecture.
Part 2 provides definitions for the terminology and vocabulary used in the reference architecture.
Part 3 presents the reference architecture from various viewpoints, such as business, operational, system,
technical, functional, and logical views.
Part 4 categorizes the entities comprising the reference architecture into two classes of physical and functional
entities and presents models for the entities.
Part 5 provides detailed information on the interfaces among various entities in the reference architecture.
Part 6 provides the application profiles that are derived from studies of use cases, scenarios, etc., for sensor-
network-based applications and services.
Part 7 provides design principles for the reference architecture that take the interoperability requirements into
account.

© ISO/IEC 2012 – All rights reserved v

---------------------- Page: 5 ----------------------
DRAFT ISO/IEC DIS 29182-3

Information technology — Sensor Networks: Sensor Network
Reference Architecture – Part 3: Reference Architecture Views
1 Scope
This International Standard (IS) provides Sensor Network Reference Architecture (SNRA) views. The
architecture views include business, operational, systems, and technical perspectives, and these views are
presented in functional, logical, and/or physical views where applicable. This IS focuses on high-level
architecture views which can be further developed by system developers and implementers for specific
applications and services.
This International Standard provides reference architecture views consistent with the requirements which are
defined in Part 1 (General overview and requirements) and can be utilized more effectively with other Parts,
especially with Part 4 (Entity Models) and Part 5 (Interface Definitions).
2 Normative References
The following referenced documents are indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced document
(including any amendments) applies.
ISO/IEC 29182-1, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 1: General overview and requirements
ISO/IEC 29182-2, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 2: Vocabulary/Terminology
ISO/IEC 29182-4, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 4: Entity models
ISO/IEC 29182-5, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 5: Interface Definitions
ISO/IEC 29182-6, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 6: Application Profiles
ISO/IEC 29182-7, Information technology –Sensor Network: Sensor Network Reference Architecture (SNRA) –
Part 7: Interoperability guidelines
3 Terms and Definitions
The terms and definitions used in this document are provided in ISO/IEC 29182-2 – Vocabulary/Terminology.
4 Symbols (and abbreviated terms)
1D One-dimensional
2D Two-dimensional
3D Three-dimensional
BFL Basic Function Layer
CIP Collaborative Information Processing
© ISO/IEC 2012 – All rights reserved 1

---------------------- Page: 6 ----------------------
ISO/IEC DIS 29182-3

CLM Cross Layer Management
CPU Computer Processing Unit
GHL Gateway Hardware Layer
GPS Global Positioning System
NOAA National Oceanic and Atmospheric Administration
IS International Standard
PV Physical View
RA Reference Architecture
SL Service Layer
SNHL Sensor Node Hardware Layer
SNRA Sensor Network Reference Architecture
SOA Service-Oriented Architecture
SV System View
TS Technical Standards
2 © ISO/IEC 2012 – All rights reserved

---------------------- Page: 7 ----------------------
ISO/IEC DIS 29182-3


5 Purpose of Sensor Network Reference Architecture
A Reference Architecture (RA) is a generalized architecture of several end systems that share one or more
common domains, giving direction downward and requiring compliance upward. Therefore, an architecture for
a certain application will contain some, most, or all of the reference architecture. In other words, the developer
can reuse entities and elements in the reference architecture that fit his or her application architecture and
ignore the rest of entities and elements in the reference architecture. In addition, the RA provides standards
and policies for building a specific architecture.
RAs provide a consistent point of departure for implementing solutions so that each implementation:

 Follows a consistent decomposition and design pattern;
 Reduces cost by exploiting opportunities for reuse of services, products, data definitions, etc.;
 Reduces schedule by starting with a core architecture to be tailored for implementation; and
 Reduces risk by:
o Incorporating required global capabilities; and
o Taking advantaged of lessons learned and related expertise.

The Sensor Network Reference Architecture (SNRA) outlines “what” the overall structured approach is for
facilitating interoperability and, through the details of this structure, indicates “how” the architecture and its
entities will operate through the development of interface standards. In short, the SNRA provides rules and
guidance for developing and presenting architecture descriptions.
This standard provides not only multiple perspectives of SNRA (e.g., business, information, and technical) but
also multiple views of the technical architecture (e.g., physical, system, operational, etc.) describing a sensor
network (e.g., business, information, application, and data). The combination of these architecture perspectives
and views forms a comprehensive architectural description of the sensor network system. The reference
architecture perspectives and views are to:
 Show how Sensor Networks operate in a homogeneous or a heterogeneous system;
 Show the systems of equipment and the flows of information that support the sensor networks; and
 Show the technical rules and guidelines that allow these systems to interoperate.

Typically, a developer begins depicting an architecture with desires and needs for the data/information that
could be provided by a sensor network or sensor networks and that could meet the desires and needs (e.g.,
then translated into a set of requirements). Additionally, the developer needs to have an understanding of the
technology available and also the roadmap of technologies to come. For example, the desires and needs
could be a computer and a set of sensor nodes (thus, a sensor network) in a car to monitor and control
subsystems, or alternatively they could be a large system of systems, such as the sensor networks by National
Oceanic and Atmospheric Administration (NOAA) to monitor worldwide weather in order to predict weather
patterns and to provide warnings if necessary. Each developer will have specific requirements concerning the
capabilities that a sensor node or sensor network should have for target applications and services. The
developer also needs to make many decisions in developing a sensor network architecture including whether a
sensor network will perform data processing to provide high level information to a user, or a sensor network will
make the raw data available to a user who will use its own applications to process the raw data. The Sensor
Network Reference Architecture (SNRA) can provide the developer with various options and understanding for
the developments, and more importantly, SNRA provides the developer with the architecture starting point.
The SNRA supports the development of interoperating and interacting architectures. It defines the multiple
perspectives of SNRA and the multiple views of the technical architecture. Each view is composed of sets of
architecture data elements that are depicted via graphic, tabular, or textual products. The SNRA also clearly
defines the relationships between these architectural views and the data elements they contain.
© ISO/IEC 2012 – All rights reserved 3

---------------------- Page: 8 ----------------------
ISO/IEC DIS 29182-3

6 Overview of Sensor Network Reference Architecture
Sensor network is a system of distributed sensor nodes communicating with each other and also interacting
with other sensor networks that monitors environments external to the sensor network in order to acquire,
process, transfer, and provide information extracted from a physical world.
This Sensor Network Reference Architecture (SNRA) consists of a set of domains which are concerned with
gathering raw data from each domain’s physical environment, processing raw data into information, and
delivering information to a user or users. The user can be a human or a machine/software (e.g., automated
command and control system). In cases where a sensor network has a sensor node or sensor nodes
equipped with an actuator or actuators, information in the forms of a decision can flow from the user to the
actuator(s) attached to the sensor node to provide an actuation command.
Each sensor network consists of various entities such as sensor nodes, actuators, a network, processing (at a
local sensor node, a gateway, and/or fusion centre), applications used by the sensor nodes, applications used
1
by the users , and finally the user. Figure 1 shows a high level physical view of multiple sensor network
domains although there are other domains not captured in the figure. Most sensor network domains are
designed to be dissimilar and disparate as each sensor network focuses on its own specific application. This
figure is to emphasize the importance of interoperability among dissimilar networks, sensors, and disparate data
contents and formats. Figure 1 also shows that sensing can occur in all geospatial expanses (e.g., space, air,
maritime, ground, and subsurface (e.g., underground, and below ocean/lake/river surface)). In each geospatial
expanse, there are many capabilities that sensor networks can provide as shown in the figure. In space, a
sensor network formed by the sensor nodes in a constellation of satellites can provide data and information
about Earth’s weather, air pollution, oceanic current movements, and so on. In the air, air traffic control cannot
be performed without sensor networks (e.g., radars). In maritime, ships rely on GPS for navigating the oceans.
The sensor networks can also be effectively used for maritime container tracking, tagging of, and protection for
the contents of the containers, On the ground, many different sensor networks are found as there exist many
different applications, (e.g., intelligent highway, transportation, supply chain management, medical, military,
industrial, finance, first responders, governmental, home, environmental monitoring, perimeter protection and
intrusion prevention, health/situation monitoring of elderly or patients, and so on).

1
[When the user is a person] Personal information belongs to individuals. It shall be implemented any protection means
when personal information is connected to networks. [Reference: NIST-IR7628, Smart Grid Cyber Security Vol.2 “Privacy
and the Smart Grid”, and OECD: “Privacy Principles”]
4 © ISO/IEC 2012 – All rights reserved

---------------------- Page: 9 ----------------------
ISO/IEC DIS 29182-3

Interoperability amongst:
• Networks
• Sensing
Space
• Sensors
Standardization of
• Processing
• Data
− Central
Sensor Networks at
− Distributed
various levels
• Data/Info Exchange
− Contents
Information on:
− Security
• Motion
• Services
• Fire
• Intrusion
• Disaster
Information on:
• Etc.
• Health
• Emergency
• GPS
Air
• Monitoring
• Etc.
Air Traffic Control
Maritime
Oceanic
Military
Industrial
Federal, State, Local
Finance
Commercial
Intelligent Highway
Ground
VVehehiicucullarar
Home
Transportation
Sub-surface
Police, Fire, Emergency
Medical
Figure 1. High level physical graphic of sensor network domains.
In summary Figure 1 shows that there are many dissimilar sensor networks in various geospatial expanses, and
within each expanse, there are many disparate sensor network applications and services where the disparity
exists in types of sensors in the sensor network, networks that support the sensor networks, and data formats
utilized by the sensors and the communication networks.
Figure 1 also attempts to illustrate an interoperable sensor network reference architecture, consisting of multiple
horizontally interoperable subsystems or modules and the interfaces between those subsystems and modules.
Interoperability also needs to exist vertically to transmit the information seamlessly within the hierarchical
structure of the sensor networks supporting a complex system of systems. Both horizontal and vertical
interoperability can be achieved by a standard developing process that promotes open architecture and also by
standardization of interfaces between subdivisions (both subsystems and sensor networks), layered structures
in sensor networks and its applications. For the reference architecture to fulfil the requirements of
interoperability, existing interoperability standards should be used to describe sensor network systems.
Additionally, the needs for new standards, to satisfy new technologies, applications and services of sensor
networks, can be identified from the sensor network reference architecture.
Figure 2 describes the sensor network reference architecture by identifying the main entities of sensor networks
and the interfaces between the main entities which make up a sensor network. The detailed descriptions of
the interfaces (e.g., Interface 1, Interface 2, …, Interface 5) can be found in Part 5 – Interface Definitions – of
this International Standard series.
The main entities identified are:
1. Sensor Nodes, and a sensor node has:
 Sensor Node Hardware Layer (SNHL);
 Basic Functions Layer (BFL);
 Service Layer (SL);
 Application Layer (AL); and
© ISO/IEC 2012 – All rights reserved 5

---------------------- Page: 10 ----------------------
ISO/IEC DIS 29182-3

 Cross Layer Management (CLM);
2. Gateway and a gateway is likely to have the same or similar layers and layer structure as those in the
sensor node); thus, a gateway has:
 Gateway Hardware Layer (GHL);
 Basic Functions Layer (BFL);
 Service Layer (SL);
 Application Layer (AL); and
 Cross Layer Management (CLM);
3. External Environment through Access Network and Backbone Network connecting to service providers
and users.
In Service Provider, it is likely to have the similar layer structure as the one in a gateway.
The interfaces between these main entities, identified in grey colour-filled boxes in Figure 2, are:
1. Within a sensor node, there are:
 Interface between Sensor Node Hardware Layer and Basic Functions Layer (SNHL / BFL);
 Interface between Basic Functions Layer and Service Layer (BFL / SL);
 Interface between Service Layer and Application Layer (SL / AL); and
 Interfaces between Management Cross Layer and Applications Layer, Service Layer, and Basic
Functions Layer (CLM / AL-SL-BFL);
2. Interface between a Sensor Node to a Sensor Node within a Sensor Network; and
3. Interface between Sensor Network Gateway Node and other networks (ISO/IEC 29182-1 Figure 3
designates “Backbone Network and Access Network” as “Other Networks,” which is also shown in
Figure 9 of this standard).
The interfaces between Sensor Node Hardware Layer and Basic Functions Layer (SNHL / BFL) are realized by
the functions reside in SNHL and those that reside in BFL.
External Environment
Gateway
Sensor Node
Interface 1
Service Provider User
Sensor Node
Backbone
Network
Application Layer (AL)
Interface 3
Access
Interface – SL / AL
Network
Service Layer (SL)
Interface 5
Interface 2
Interface 4
Interface – BFL / SL
Basic Functions Layer (BFL)
Interface – NH / BFL
Sensor Node Hardware Layer
(SNHL)

Figure 2. Overview of sensor network interfaces in a sensor node, sensor node to sensor node, and
sensor node to the External Environment.
6 © ISO/IEC 2012 – All rights reserved

Cross Layer Management
Interface –
CLM / (AL-SL-BFL)

---------------------- Page: 11 ----------------------
ISO/IEC DIS 29182-3

Device Management
Data Storage
Service Management
Data Mining CIP
Information Communication
Security Management
Data Fusion Others
Business Management
Data Processing
Information Provisioning
User Management
Wide
Security Management
Local Area
Data
Area
Networks Communication
Service Management
Network
Device Management
Data Acquisition Data Storage
Communication
Protocol Stack Service Management
CIP Data Fusion
Security Management
Feature Extraction
Communication
Data Aggregation
Support functions
Network Management
Others
Data Processing Data Communication Feedback & Control
Data, Information, & Communications Control & Management

Figure 3. Sensor Network Functional Architecture.
Figure 1 illustrates a set of functional entities that realizes various sensor network services, and it depicts the
functional view of the sensor network reference architecture. This sensor network functional architecture lists
many significant functions in a sensor network, but not all functions are included.
In the sensor network functional architecture shown in Figure 1, Sensing Domain transports data/information to
Service Domain through Local Area Networks or Wide Area Network. As shown in the figure, there are two
main groups responsible for data and information generation: Data, Information, & Communications Group and
Control & Management Group within Sensing Domain. Data, Information & Communication Group provides
functions such as data acquisition, data storage, data processing (e.g., Collaborative processing, data
aggregation, feature extraction, data fusion, etc.), data communication (e.g., communication protocol,
communication support function, etc.). Control & Management provides functions such as sensing device
management, service management, network management, security management. Once data/information is
passed to Service Domain, the data/information is processed by the functions such as data mining, information
extraction, data fusion and other relevant functions not shown in the figure. Additionally, the data/information
can be stored, communicated, and provisioned in Service Domain.

Sensing Domain
Table 1 describes the functional entities in Sensing Domain depicted in Figure 1. Comprehensive description
of the entities can be found in Part 4 – Entity Models of this IS series.
Table 1. Function model and descriptions in Sensing Domain.
Functional Entities Descriptions
Data acquisition Sense and capture data from the environment for applications.
Data storage Store sensor data, control instructions, and management data.
Data processing Use data/signal processing algorithms to extract requested or useful information
© ISO/IEC 2012 – All rights reserved 7

Service
Sensing Network
Domain
Domain Domain

---------------------- Page: 12 ----------------------
ISO/IEC DIS 29182-3

Functional Entities Descriptions
from sensor data and metadata. The information extraction algorithms include
collaborative information processing (e.g., data fusion, feature extraction, data
aggregation and data presentatio
...