A Protocol for Command and Control Systems Integration
Patrick Lara and Ricardo Choren
Military Institute of Engineering, Praça General Tibúrcio, Rio de Janeiro, Brazil
Keywords: Command and Control, Enterprise Integration, JC3IEDM, Message Protocol, SOAP, Systems Integration.
Abstract: Integration of Command and Control (C2) systems is a real need in any Joint Operation. Solutions are
typically based on data exchange, usually using the Joint Consultation, Command and Control Information
Exchange Data Model (JC3IEDM), a data model established by NATO. The use of this model with service
oriented architecture (SOA) has been consolidated as one of the key factors to achieve command and
control systems integration. However, these solutions require great computer process capacity and
broadband networks, which are usually hard to find in military tactical environments. This paper presents
approaches of integration systems available, comparing their technologies, pointing out their advantages and
disadvantages, and finally proposes requirements for a generic protocol to allow message handling between
command and control systems, using the JC3IEDM.
1 INTRODUCTION
Command and control (C2) is the art and science in
the study of the operation of a chain of command,
which consists basically of three components:
authority, processes and structure (Amorim, 2011).
Command and control systems with superior
performance enables commanders to remain
victorious in the joint efforts, helping them to apply
their skills in critical time and select the best strategy
to succeed in a given situation. Two features are
essential: the human element and the need for
relevant information, timely and accurate. The
human element, with its ability to infer what is
important, the essential elements absorbs and reacts
to information, which makes it an important factor
constant over time (Shalikashvili, 1995).
Technology has improved mobility, weapons,
sensors and C2 systems (C2S), and continues to
reduce the time and space, increasing the pace of
operations, generating large amounts of information.
If we cannot process this information, it may impair
the reactions of the fighting force. The use of C2S
systems designed to assist human capabilities and
limitations is essential to keep the C2 commander
capacity victoriously (Shalikashvili, 1995).
The situational awareness shared between
military units is essential for the ability to network-
enabled operations (NEC). This requires greater
access to information, ensuring that the units in need
of information have access to it. Nevertheless, the
operating environment focusing in rapid reaction
requires more adaptable and efficient solutions for
the exchange of information, to create and update
dynamically an operational scenario.
This paper presents an initial solution to the
problem, using a set of messages and rules to
manage traffic of information between C2S, with the
proposal to allow the exchange of data between
systems via messages. The definition of a protocol
for exchanging messages is a complex task. For
example, we have the LRIT system (LONG-
RANGE IDENTIFICATION AND TRACKING
SYSTEM), where a multinational group took about
five years to achieve stabilization at the Interface
Data Exchange (IDE) protocols (IMO, 2012). This
paper therefore aims to solve the problem by
presenting a set of messages and the respective rules
governing the traffic between systems to enable data
exchange. The challenge in this type of solution is
how to minimize the overhead caused by the time
wasted on the reading messages process. This step
could be mandatory to reach a satisfactory
performance in C2S integration.
The rest of the paper is organized as follows:
section 2 presents the command and control systems
integration; section 3 presents the proposed
approach; section 4 presents examples of the
messages handled by the Protocol on a scenario;
section 5 discusses the related work; section 6
484
Lara P. and Choren R..
A Protocol for Command and Control Systems Integration.
DOI: 10.5220/0004970404840489
In Proceedings of the 16th International Conference on Enterprise Information Systems (ICEIS-2014), pages 484-489
ISBN: 978-989-758-029-1
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
presents conclusions of the study and the future
works; and the references are listed in section 7.
2 C2S INTEGRATION
The Force Commanders needs accurate and timely
information to operate, guaranteeing that the soldiers
will have access to the information they need. The
C2S system is a major tool to support Joint Force
commanders (JFC) allowing gathering, transport,
process and dissemination of information
(Shalikashvili, 1995).
To ensure the continuous and uninterrupted flow
and processing of information, joint combatants
should have C2S that are interoperable, flexible,
agile, mobile, disciplined, survival and sustainable
(Shalikashvili, 1995).
There are more principles then listed above.
Other relevant principles are encompassed or
applied when appropriate. They are: integration,
ease of maintenance, mobility, modularity, planning,
prioritization procedures, readiness, responsibility,
agility, simplicity and capacity (Blair, 1996).
Joint and multinational operations are complex
and gather various military organizations operating
as a Force. Multinational forces may have
differences in C2S, language, terminology, doctrine
and standards of operation that may cause confusion.
The confusion increases the demand for information
and also the level of uncertainty. The lower the level
of the interface between various commands, the
greater will be the uncertainty as well the demand
for systems of C2S. The JFC must ensure that great
care is taken in structuring multinational force
before operations to avoid unnecessary confusion
within friendly forces (Blair, 1996).
2.1 JC3IEDM
The protocol proposes the handling of information.
The data is treated as having value as a source of
information. The problem of representation of
information for C2S has mature solutions, for
example the JC3IEDM (Joint Consultation,
Command and Control Information Exchange Data
Model. However, the model does not provide
solution to the need of dynamic exchange data
between systems. This dynamic exchange is defined,
as previously mentioned in a protocol for message
handling, using the meta-model of JC3IEDM.
According to the Multilateral Interoperability
Programme (MIP, 2012), Data interoperability
requires a rigorous defined semantic vocabulary.
The JC3IEDM is embedded in a structured context
that defines the standard elements of information
that compose the basis for interoperability between
automated Command and Control Information
Systems (C2IS), as long as can accommodate the
model's information structure.
“The MIP nations agreed with requirements to
define only the information that is to be exchanged
rather than all of the information that would
normally be required in a national system.
Consequently, JC3IEDM is first and foremost an
information exchange data model. The model can
also serve as a coherent basis for other information
exchange applications within functional user
communities. The general pattern is to use a subset
of JC3IEDM and add functional extensions.” - The
JC3IEDM is used by NATO in their joint operations
in the integration of C2 systems of participating
countries (MIP, 2012).
JC3IEDM should be considerate as a
consolidated model. However, this model does not
provide a solution for the dynamic Data exchange
between systems. This dynamic exchange is defined,
as previously stated, in a protocol for exchanging
messages, using the data model JC3IEDM.
2.1.1 JC3IEDM Chosen Entities
Figure 1 shows a part of the model that contains the
chosen independent entities of the data model and
their relationships for this study, with a brief
description of their typical meanings.
Figure 1: Independent entities of JC3IEDM.
ACTION - An activity, or the occurrence of an
activity, that may utilise resources and may be used
against an objective. Examples: Order of Operation,
Operation Plan, Order of Movement, Movement
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485
Plan, events or incident (i.e. enemy attack).
LOCATION - A specification of position and
geometry with respect to a specified horizontal
frame of reference and a vertical distance measured
from a specified datum. Examples: points, sequence
points, polygon, circle, rectangle, ellipse, polygon
area, sphere, cone and block space. LOCATION
specifies location and dimensionality.
OBJECT-TYPE - An individually identified
class of objects that has military or civilian
significance.
Examples: type of person (i.e. by rank), type of
material, type of facility, or type of organization.
OBJECT-ITEM - An individually identified
object that has military or civilian significance.
Examples: a specific person, or a specific unit.
REPORTING-DATA - The specification of
source, quality and timing that applies to reported
data.
Using a significant part of the data model shown
above, herewith Web Services technology, it is
believed that there is a synergy between the
available data and services offered by specialized
suppliers. Web services allow platform
independence and programming language because it
uses XML to definitions and communication. It also
enables a strong definition of messages and services
through WSDL documents. The use of HTTPS for
transport will also facilitate the passage of
information through firewalls without the need of
using specific ports.
3 THE PROPOSED APROACH
The study aims to identify available approaches of
integration systems, compare their technologies,
pointing out their advantages and disadvantages, and
propose a model of generic protocol for exchanging
messages between systems situational awareness in
Joint Operations, using the JC3IEDM.
The project has being developed through a survey,
which was prepared a case of study with a model to
exchange messages on a system of maritime
situational awareness already developed, simulating
the exchange of information between C2 systems.
We looked for what type of information that the
source system needs. After this phase, we designed
the model to exchange messages from a source to
the destination C2 systems.
The research considers the following assumptions:
a) The protocol is conceptual, but its
implementation may be accomplished through a
layered architecture on a services layer (Erl, 2009),
which would implement the interfaces of the
messages and business rules governing its
processing; e
b) The architecture Publish/Subscribe (Hohpe
and Woolf, 2003) is suitable for allow maintenance
situational awareness environments war.
A high-level view (see Figure 2) shows the proposed
architecture, where the protocol allows for messages
to exchange information through a system of
systems, composed of several systems of military
situational awareness, defined as clients, and a C2
System, the main consumer of message content.
Figure 2: High Level Architecture.
The study was conducted comparing the four main
approaches in the area of integration, and how it’s
used to exchange messages between systems based
on SOA standards, considered state of the art in the
field of integration of systems.
Was presented a proposed integration model
through a generic protocol, using the concepts of
JC3IEDM to exchange messages between existing
systems of maritime situational awareness, already
in use, and available for study.
As a result of field research conducted in the
Brazilian Navy organizations, we obtained the
necessary requirements for command and control of
a joint operation at the operational level. It was
emphasized that the delay in the data flow holds the
progress of actions during the Combined Operations
exercises.
In an overview, the protocol should operate as a
message handling service of messages, allowing for
exchange of information between the systems to be
integrated. Based on the field research and previous
experiences in maritime systems of situational
awareness, the functional requirements for the
message protocol were established. Protocol should:
a) allow the system to shall request and send the
position of friendly forces;
b) allow the system to ask and update the
position of friendly forces, in a predefined time;
ICEIS2014-16thInternationalConferenceonEnterpriseInformationSystems
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c) allow the system to perform the position
request a specific unit known; and
d) allow the system to perform location request
per geographical area.
W. Lam and V. Shankararaman listed ten common
types of integration requirements in enterprise
integration. Analysing our problem, we selected four
of them to apply on the message protocol
requirements (Lam and Shankararaman, 2004).
Also were defined as requirements:
1) Timeliness – Urgency of the communication
or integration between applications. A big time
reflects on the precision and the relevance of the
information in the situational awareness scenario, at
the operational level. To maintain the timeliness, the
Protocol should only route messages between
systems. Its interface should be available for
communication between systems, via standard
Internet protocol. The protocol must use the
Requestor User or the Provider User parameters
included in the messages to determine where to
forward the message.
2) Resilience and recovery – Resilience of the
integration infrastructure in event of failures.
Reaching more redundancy will help to guarantee
the higher the message delivery. To reach these
requirements, the Protocol must store and archive
messages header information in “log” files for
subsequent audits and statistical analysis of the
system operation. The Protocol should only read the
message header, and should not perform any
filtering function on the information contained in the
messages.
3) Size – Size of data that the integration
between applications must handle (related to
volume). Big file sizes reflects on raising the
expected overheads. To avoid big overheads, the
Protocol does not read the information contained in
the messages body (only in the header), and does not
store or archive any information from the systems.
The Protocol should protect the contents of the
messages. Users responsible for the operation and
maintenance of the system should not be able to
access the information contained in the messages.
4) Frequency – Frequency of integration needed
between applications. Directly affects the operations.
The real time frequency is required for the Request /
Response services. For Publish / Subscribe services
can be defined a slightly longer time to interactions.
We found that the integration of heterogeneous
systems has been approached with different views
on the search for solutions. The development of the
generic protocol for message handling uses the
concepts of JC3IEDM, a data model defined by
NATO to allow interoperability between command
and control systems.
The service-oriented architecture (SOA) with the
use of Web Services technology was chosen because
of ease of learning and implementing this
technology. It has good interoperability, regardless
of the programming language and platform used,
despite the expected performance is not the best
possible. To increase the performance, the size of
message should be minimized. A middleware for
managing message queues is also necessary, as an
open source and free distribution software.
Regarding JC3IDEM study was carried out on
the model, which was confirmed ideas based on
previous work. It was found that the operational
vision should be focused on what are the processes
of command and control for joint operations, while
the technical vision should worry about what
formats to be used.
The C2 systems exchange messages through
mechanisms classified as MEM (Message Exchange
Mechanism), or message-driven pre-formatted. The
DEM (Data Exchange Mechanism) has focused on
the information modelled from the perspective of
object orientation, physically implemented in a
database. Based on this model, a simpler model was
created, to facilitate their understanding, and allow
its implementation in academic study projects.
Figure 3: Used Part of the JC3IEDM.
Using the part of data model shown above and the
Web Services technology, it is believed that there is
a synergy between the available data and services
offered by specialized suppliers. Web services allow
platform independence and programming language
because it uses the XML format for definitions and
communication. It also enables a strong definition of
messages and services through WSDL documents.
The use of HTTPS for transport will facilitate the
passage of information through firewalls without the
need to use specific ports.
4 EXAMPLE
This subsection presents three examples of
messages. The scenario is a Joint Force Operation,
ACTION
OBJECT-TYPE OBJECT-ITEM LOCATION
REPORTING-
DATA
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where Navy, Army and Air Forces are cooperating
to reach the same objective. The Armed Forces need
to share their informations to maintain an updated
situational awareness.
In the first example, a request of position is made
(LOCATION) of an operative unit (OBJECT-
ITEM), defined by its unique identifier (ObjId). The
second one presents the message carries a request
for verification of placement of units within a given
area defined by the geographical coordinates of its
two end points, northeast and southwest geographic
are points (neLat, neLong, swLat and swLon). The
third example is a response for a Position Request
Message, called Position Report Message. The
formatting of tags and spacing of them was changed
for fit to the paper columns.
4.1 Position per Unit Request Message
<soapenv:Envelope
xmlns:soapenv="http://schemas.xmlsoap.o
rg/
soap/envelope/"
xmlns:web="http://web.jc3v314/">
<soapenv:Header/>
<soapenv:Body>
<web:location>
<objId>?</objId>
</web:location>
</soapenv:Body>
</soapenv:Envelope>
4.2 Units per Area Request Message
<soapenv:Envelope
xmlns:soapenv="http://schemas.xmlsoap.o
rg/
soap/envelope/"
xmlns:web="http://web.jc3v314/">
<soapenv:Header/>
<soapenv:Body>
<web:request>
<areaRequest>
<areaCode>?</areaCode>
<description>?</description>
<messageId>?</messageId>
<neLat>?</neLat>
<neLon>?</neLon>
<requestTimestamp>?</requestTimestamp>
<requestor>?</requestor>
<swLat>?</swLat>
<swLon>?</swLon>
</areaRequest>
</web:request>
</soapenv:Body>
</soapenv:Envelope>
4.3 Position Report Message
<soapenv:Envelope
xmlns:soapenv="http://schemas.xmlsoap.o
rg/soap/envelope/"
xmlns:ws="http://ws/">
<soapenv:Header/>
<soapenv:Body>
<ws:positionReport>
<positionReport>
<areaCode>?</areaCode>
<description>?</description>
<latitude>?</latitude>
<longitude>?</longitude>
<messageId>?</messageId>
<requestTimestamp>?</requestTimestamp>
<requestor>?</requestor>
</positionReport>
</ws:positionReport>
</soapenv:Body>
</soapenv:Envelope>
5 RELATED WORK
Lund et al. presented that there is a focus on the
establishment of a service-oriented architecture
(SOA) to increase interaction within the allied forces
(Lund et al., 2007). However, this solution has been
adopted for environments with great data
communication capacities, which is the opposite of
military tactical networks. The study also
recommends the architectural principles and
technologies that are best suited to implement this
infrastructure information. Also recommended is the
use of IP as a common protocol for use in all types
of networks technologies, chosen to facilitate
interoperability, the easier for all types of network.
The main idea was to make SOA possible to take by
all military levels, from strategic to tactical
networks.
As presented above, SOA is commonly
performed through web services using XML-
formatted documents, but are designed to be used in
broadband networks and not in military networks
with limited capacity. The XML documents tend to
be large, having a significant overhead. This paper
proposed requirements to make a message handling
protocol, and few XML-formatted messages there
expected to reduce this overhead caused by the use
of Web Services in tactical networks environment.
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6 CONCLUSIONS AND FUTURE
WORKS
This paper proposes a study of the requirements of a
protocol and the examples for XML-formatted
messages that must be handling in a protocol, to
allow a satisfactory performance during the
integration process of command and control
systems. The solution has two approaches, both
equal important to establish a protocol. The first one,
the data model, which is supposed to be known,
common, and consolidated by all C2 systems, and
the second one, the integration technology used to
allow the message handling, where is typically used
Web Services, despite of all overhead expected on
the reading messages process.
SOA enable a strong decoupling between clients
and servers, and count with the existence of various
tools for project development. The use of the Web
Services technology allows a greater decoupling
between the systems, which leads to independent
programming language and platform for the existing
C2 systems.
The data model JC3IEDM defines a pattern for
information modelling, allowing the use of the same
vocabulary to all systems. Data is routed through
objects in messages handled by the protocol, using
request/response and publish/subscribe patterns,
which give systems the capacity of data refresh on
demand, or update periodically. The requirements of
the protocol, and the message examples listed above
are design to reduce this impact during joint
operations, allowing their success in battlefields.
This is an initial solution to the problem, using a
set of messages and rules to manage traffic between
C2S, using the protocol requirements listed on
section 3 to minimize the overhead caused by the
use of Web Services. These requirements were
based on a previous experience of specialists in
maritime situational awareness systems and on the
knowledge of the command and control doctrines
contained in the publications listed on section 7.
The future work will be based on design the
complete system protocol architecture to allow the
message handling in runtime. The implement of an
encryption layer is also desirable, that should be
strong enough to ensure the conduction of joint
operations exercises without any interference,
internal or external. This security layer must be
designed and implemented without compromising
the performance of the message exchange protocol.
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