A SERVICE-ORIENTED FRAMEWORK FOR MAS MODELING
Wautelet Yves, Achbany Youssef and Kolp Manuel
Info. Syst. Research Unit (ISYS), University of Louvain, Belgium
Keywords:
Requirements Engineering, service oriented modeling, i*, multi-Agent system.
Abstract:
This paper introduces an analysis framework made of different models proposing complementary views. First
view - the strategic services diagram (SSD) - is the most aggregate knowledge level; it uses services for rep-
resenting the system to be in a global manner. Second view offers a more detailed perspective of the agents
involved into the services using traditional i* Strategic Dependency (SDD) and Strategic Rationale Diagrams
(SRD). Finally, the third view - the Dynamic Services Hypergraph (DSH) - offers a dynamic approach of ser-
vices realization paths at various Qualities of Service (QoS). Using those models at analysis level is interesting
in a model driven software development approach. Indeed, the project stakeholders can share a common vision
through a lookup at the services the system has to offer, at the depender and dependee agents for the services
constituents and at the different realization paths and their QoS. The framework also offers the fundamental
elements to develop a complete model driven software project management framework. It can be considered
as a startup for a global broader software engineering method.
1 INTRODUCTION
Multi-Agent Systems (MAS) have become an impor-
tant and promising research area in computer science
in general and in software engineering in particular.
Applying agent technology to huge enterprise infor-
mation systems engineering is nevertheless seldom
done. One may wonder where this report comes from.
MAS development is maybe not mature enough to
be applied in large industrial software development.
Indeed, most of the research is focused on develop-
ing particular aspects of modeling, specifying, de-
signing or implementing collaborating agents. Global
frameworks for MAS model driven development and
software project management are, until now, seldom
approached in literature. Researchers need conse-
quently to understand what dimensions are required
to bring a technology to be used on a large scale and
to fill the gap between the research field and its prac-
tical application.
This paper is part of this effort: on the basis of
the weaknesses identified in the i*/Tropos MAS de-
velopment methodology, a generic framework for or-
ganizational modeling and requirements engineering
using higher abstraction level elements: the services.
The importance of distinguishing the system behavior
at such level will be characterized and a set of mod-
els allowing services representation through multiple
complementary views will be introduced. This frame-
work is composed of a static high level services view,
of a static and a dynamic decomposed services views.
The paper is structured as follows, Section 2
points the limitations of the traditional Strategic De-
pendencyand Strategic Rationale Diagrams for model
driven software development. Section 3 points to the
use of a framework based on services that can be ex-
tended for software project management. Section 4
formalizes the new diagrams included into the frame-
work through the use of a meta-model. Section 5 con-
cludes the paper.
2 PROBLEM STATEMENT
Some modern software development methodologies
are said to be Model Driven. In such methods, the en-
tire development process is deduced from the features
modelled in high level diagrams. Object-oriented de-
velopment methodologies such as the Unified Process
(IBM, 2003; Jacobson et al., 1999; Jacobson and By-
lund, 2000; Kruchten, 2003) are for example said to
be use case driven. This means that the entire devel-
120
Yves W., Youssef A. and Manuel K. (2008).
A SERVICE-ORIENTED FRAMEWORK FOR MAS MODELING.
In Proceedings of the Tenth International Conference on Enterprise Information Systems - ISAS, pages 120-128
DOI: 10.5220/0001708101200128
Copyright
c
SciTePress
opment process is driven by the use cases identified
in the analysis phases. Moreover effort estimation
techniques as Use-Case Points (Schneider and Win-
ters, 1998) directly use high level diagram elements -
the use cases - as fundamentals for effort estimation.
Such model elements called scope elements are con-
sequently usefull not only to share a common high
level vision with stakeholders, but also to estimate
the project effort on a non redundant basis, to eval-
uate related risks, to fix an acceptable level of qual-
ity, etc. Classical i*/Tropos developments using tra-
ditional Strategic Dependency (SD) and Strategic Ra-
tionale (SR) diagrams (Yu, 1995) for organisational
modelling and requierements engineering do unfortu-
nately not possess ideal elements to drive the devel-
opment process, this will be shown in this section.
2.1 Related Work
As pointed out earlier, considerable work has been
done in agent-orientedsoftware developmentmethod-
ologies. The traditional i* modeling framework has
however been poorly criticized and weaknesses as the
lack of higher abstraction level elements has been
only recently pointed out in literature (Pastor et al.,
2007). Similarly, considerations on software project
management using Tropos or other MAS methodolo-
gies are not easy to find in MAS literature. In the
same way, even if some attempts such as AUML ex-
ist, no dynamic dimension implying i* concepts has
been proposed and formalized. We willreference here
three approaches, each one addressing one of the pre-
viously mentioned aspects. We will also briefly com-
ment our view in regard to the aspects described in
those papers.
• The process followed in this paper has been
strongly inspired by the concepts introduced in
(Estrada et al., 2006; Pastor et al., 2007). Those
papers define a series of features for evaluating
the i* framework on the basis of case studies. The
empirical study addresses the weaknesses of the
approach and points to the use of higher level ab-
stractions called business services into i* devel-
opments. Our conclusions are rather the same and
we take their approach as a starting point for mul-
tiple view modeling framework.
• (Dubois et al., 2007) proposes to model threats
and vulnerabilities directly into SD and SR mod-
els and relates them directly with actors and goals.
We also propose a framework where threats (and
even opportunities) are incorporated into high
level models but we relate then to services not in
SD and SR diagrams. Furthermore operational so-
lutions are incorporated to keep/improve quality
of service.
• (Mouratidis and Giorgini, 2007) adresses i* se-
curity limitations and claims for the adoption of
secure Tropos, an extention to the Tropos pro-
cess incorporating security issues. Secure Tro-
pos offers extentions for modeling requirements
with security constraints. Moreover, in that pro-
cess, security is an issue only considered at late re-
quirement stage, the methodology partially iden-
tifies conflicts between security and other require-
ments. Our approach does not model security as
constraint but identifies the potential threats to de-
termine the most risky issues at the earliest stages
of the project.
2.2 The Lack of Scope Elements
One of the main problems in using the Tropos soft-
ware development methodology is to find an adequate
scope element to drive the software process.
Actors from the SD and SR models are involved in
dependencies of different intentional elements. The
goal is the only candidate as scope element since it
represents the most abstract functional issue. A com-
plete description of these elements can be found in
(Yu, 1995). However, goals are not considered as the
ideal scope element candidate since:
• The atomicity of the goal is not clearly defined
so that a goal decomposition can involve atomic
goals part of higher level goals consequently (i)
a great amount of goals – too many for keeping
an easily understandable vision of the software
project – can be present for a huge software pro-
jet; (ii) the goals are often at different levels of
atomicity so that they can be redundant which is a
major drawback to keep the simplest vision possi-
ble;
• The distinction between a task and a goal is not
always trivial; different persons can model simi-
lar behavior by interchanging those different con-
cepts.
Consequently, we need an element located at suf-
ficiently high level of abstraction to represent a ser-
vice the agents should provide in a non redundant
way. This element should provide a clear vision of
the project, allow to identify environmental threats for
risk management, time management, etc. This ele-
ment is called a service and is depicted in the next
section.
A SERVICE-ORIENTED FRAMEWORK FOR MAS MODELING
121
2.3 Contributions
Compared to the approach followed into (Estrada
et al., 2006; Pastor et al., 2007), we provide:
• A complete multiple view analysis framework
for service-oriented modeling using i*.The frame-
work also offers the fundamental elements to de-
velop a complete model driven software project
management framework. It can be considered as
a startup for a global broader software engineer-
ing method;
• A dynamic model for representing services real-
ization at defined quality of service level;
• Enhancements into the Strategic Services Model
to model system threats;
• A case study.
3 A UNIFIED-FRAMEWORK FOR
AGENT-ORIENTED
REQUIREMENTS
ENGINEERING
This section introduces the services approach and de-
picts the framework in an informal manner.
3.1 The Service Approach
In (Estrada et al., 2006; Pastor et al., 2007), the au-
thors describe business services as “an abstract set of
functionalities that are provided by a specific actor”,
they also specify that “an actor can be an organiza-
tional entity ... that uses or offers services”.
Services will be formalized in Section 4.2. In our
approach, they present the following properties:
• they represent the highest abstraction level entities
of the project, a service can encapsulate a large
amount of atomic agregate goals or tasks;
• they are independent but complementary to each
other in the sense that they do not overlap, but rep-
resent the whole of the system functionalities;
• they involve at highest level two super actors that
can be refined in multiple sub actors at lower lev-
els;
• their realization induces of different quality of ser-
vice (QoS) areas.
Moreover, we also propose to add concepts to
model environmental elements addressing a threat –
Figure 1: A Multiple View of the Framework.
potentially lowering QoS – or an opportunity poten-
tially raising QoS. Once identified, we can also rep-
resent in a generic and in a more detailed manner,
the measures that should be taken to fight against the
threats (to maintain QoS) or to put the opportunities
into practice (to raise QoS).
3.2 The Framework
To fix the weaknesses pointed out previously, a
service-oriented framework for organizational mod-
eling will be introduced. This framework is made of
two complementary views represented by four differ-
ent diagrams. Figure 1 depicts the framework dia-
grams hierarchy.
The first view called the static view allows to rep-
resent the services at two complementary abstraction
levels:
• the highest level is materialized through the
Strategic Services Diagram (SSD) described and
formalized in section 4.1. This level provides
a synthetic description of the services provided
at defined QoS by the organization and that will
be operationalized into the application. Environ-
mental factors influencing positively or negatively
the provided services as well as means to opera-
tionalize them are represented here. This diagram
can be used as a reference vision document for
stakeholders as well as a basis for iteration plan-
ning, risk management, quality management, ef-
fort planning, etc.(see Section 3.3);
• the lowest level is materialized through the tradi-
tional Strategic Dependency and Strategic Ratio-
nale Diagrams as described in (Yu, 1995). This
level provides a more detailed description of the
ICEIS 2008 - International Conference on Enterprise Information Systems
122
tasks, goals and resources involved in the achieve-
ment of all the services.
The second view called the dynamic view allows
to represent the service achievement through the use
of the Dynamic Service Hypergraph (DSH) described
and formalized in Section 4.2. The goals and tasks of
the multiple agents involved are sequentialized in the
graph to represent possible paths for service realiza-
tion at given QoS.
Taken as a whole, these views allow to represent
the multiple aspects of the services the system should
offer.
3.3 The FaMOs Framework - A Project
Management Perspective
As described previously, one of the main goals of the
framework is to allow model driven software devel-
opment. The main advantage of this type of approach
is to furnish structured developments methodologies
to software professionals. The framework was con-
ceived to provide this kind of achievement but also
furnish a broader range of possibilities.
Those services include:
• Risk Management. By allowing modeling ser-
vices threats and the operational solutions de-
signed to maintain QoS when those occur, the
framework includes some essential features for
risk management. The framework includes dif-
ferent levels of detail (abstraction) for modeling
those features.
• Quality Management. Quality indicators are
present through the use of a QoS-level so that
quality benchmarks for each service can be fixed
early into the project. Furthermore, through
the “services opportunities”, improvement fac-
tors that, once operationalized, allow to higher
QoS can be modelled at different levels. Finally,
the framework constitutes an extension of tradi-
tional i*/Tropos modelling diagrams so that soft-
goal modeling into the Strategic Dependency and
Strategic Rationale Diagrams remains possible.
• Time Management. Using the services as high
level abstractions and the DSH for the service
complexity evaluation, an approximate service
effort can be computed (as for example in the
Use Case Points methodology (Anda et al., 2002;
Schneider and Winters, 2001)). On the basis of
this evaluation, a project planning using waterfall
or better an iterative development life cycle can
be created. By including the number of human re-
sources, their role, their wages, etc. a project cost
evaluation can also be computed. The precision of
those evaluations will successively increase from
a project to another on the basis of the empirical
statistics collected during the previous ones.
Due to a lack of space, this paper will only fo-
cus on the models formalization. (Wautelet et al.,
2007) introduces a case study to illustrate the use
of the framework. it only uses elements of risk and
quality management but do not involve time and soft-
ware process management. A complete presentation
of the project management capabilities of the FaMOs-
framework is currently under development.
4 SERVICE DRIVEN AGENT
MODELING: A
FORMALIZATION
To drive the business and user services acquisi-
tion, we propose a meta-model which provides
modeling elements relevant for specifying both
strategic and operational aspects of the organiza-
tional context in which the future information sys-
tem will be deployed. This meta-model is made
of meta-concepts (e.g., “Actor”, “Dependencies”,
“Services”, etc.), meta-relationships relating meta-
concepts (e.g., “Performs”, “Operationalize”, “Act”,
etc.), meta-attributes of meta-concepts or meta-
relationships (e.g., “Probability of happening”, “Im-
provement rate”, etc.), and meta-constraints on meta-
concepts and meta-relationships (e.g., “An actor oc-
cupies a position if and only if that actor possesses all
the capabilities required to occupy it”).
4.1 Strategic Services Model
The Strategic Services Model (or SSM) supports the
acquisition, representation and reasoning about the
services that should be provided by the agents of the
application.
Figure 1 depicts the SSM. Actors are intentional
entities used to model people, physical devices or
software systems that are processor for some actions.
The inheritances from the Actor into Position, Agent
and Role as well as the linking with the Dependency
class have been inspired by the Tropos metamodel
presented in (Susi et al., 2005). A Position can cover
1 to n Roles, an Agent can play 0 to n Roles and can
occupy 0 to n Positions. Actors achieve some Ser-
vices which are functionalities they offer to others in
order to fulfil a portion of their goals and tasks (for
further formalization see section 4.2). The Service is
always achieved through an Actor Dependency. The
A SERVICE-ORIENTED FRAMEWORK FOR MAS MODELING
123
Figure 2: Strategic Services Diagram: A Meta-Model.
later relates two Actors: a depender and a dependee
as well as a dependum, the Service.
Since the aim of the diagram is to offer a high level
view of an under development enterprise information
system, there are basically two types of services that
need to be modelled: Business Services – business
processes achievedinto the company business domain
– as well as User Services – services provided to the
end user.
An Environmental Factor can be an external
Threat for the adequate fulfilment of the service (both
in terms of achievement and quality of service degra-
dation) or an opportunity that can potentially raise
the QoS. A service and its QoS are operationalized
into a digraph as depicted in section 4.2. Moreover a
Probability of happening is associated to each Threat
as well as an Improvement rate to each Opportunity.
Those features will be useful for the Threats and Op-
portunities prioritization into project planning.
An Operational Solution operationalizes an Envi-
ronmental Factor. In other words Threats and Op-
portunities are external factors that can lower or raise
QoS. To fight against a Threat or to benefit from an
opportunity measures need to be taken. Those can
be represented through the Operational Solution. The
later is specialized into the Risk Measure and the
Improvement Solution respectively aimed to model
the operational solution putted into practice to fight
against a threat and to take benefit of a potential op-
portunity. Note that once again an element (the oper-
ational solution) distinguished at SSD level induces a
higher level of abstraction that will be refined further
into the frameworkthrough SD/SR Models and DSH.
The elements of the SSM are instantiated to pro-
vide a Strategic Service Diagram (or SSD). An SSD
presents on the highest aggregationlevel of the frame-
work the services provided by each agent as well as
the potential threats and opportunities they are facing.
It also supports the identification of operational so-
Figure 3: Meta-Model of the Dynamic View.
lutions that can be taken to fight against the Threats
potentially lowering QoS and to take benefits of Op-
portunities potentially raising QoS. It shows the po-
tential problems that will be encountered when at-
tempting to achieve Services and, with the guidance
of the methodology, helps operationalizing them. By
essence, the SDD helps to understand the purpose of
the software project in terms of Services, the prob-
lems (i.e. Threats) they can face, the potential im-
provements (i.e. Opportunities) and the social struc-
ture (i.e. the Dependencies) which govern Actor in-
teractions.
4.2 Dynamic Service Model
In this section, we will bring the Dynamic Service
Model (DSM) to further formalization Figure 3 de-
picts the DSM. As the only properties of the agent
relevant for this dynamic view are the capabilities in
terms of tasks and goals it can execute along with its
advertised quality values, an agent will be defined as
follows
1
.
Definition 1. A tuple
h{(cp
i
, q
a
cp
i
), . . . , (cp
i+m
, q
a
cp
i+m
)}, Ag
a
i is called
an agent a, where cp
i
is a capability. The agent
advertises its capability to execute a task or goal to
the QoS level and cost q
a
cp
i
. The advertised level is
a vector of QoS- and cost-property and value pairs
following a QoS ontology. Ag
a
is assumed to contain
all additional properties of the agent irrelevant for
the present discussion, yet necessary when building a
MAS.
Format and content of Ag
a
will depend on the
agent programming language being used. A Capa-
bility is the generalization of Goal and Task. As it is
unimportant to know that an agent can perform more
1
Note that since, in this view, the service realization is
documented we refer to agent rather than to actors as in the
SSD.
ICEIS 2008 - International Conference on Enterprise Information Systems
124
than one capability, a specialist agent is defined over
a single capability.
Definition 2. ha, cp
i
, q
a
cp
i
i associating a capabil-
ity cp
i
to a quality level q
a
cp
i
advertised by the
agent a is a specialist agent a
SA
i
. The agent must
be capable of perfoming the capability: ∀a
SA
i
=
ha, cp
i
, q
a
cp
i
i, (cp
i
, q
a
cp
i
) ∈ a.
Any agent a that can accomplish m > 1 capabil-
ities can also be seen as a set of specialist agents:
{a
SA
i
, . . . , a
SA
i+m
}. It is necessary to have a more precise
idea of how capabilities and services are conceptual-
ized.
Definition 3. A capability cp
i
is hcp
pre
i
, τ
i
, cp
post
i
i,
where cp
pre
i
describes the capability precondition, τ
i
is a specification (in some language) of how the agent
is to execute the capability, and cp
post
i
describes the
conditions true after the capability is executed. Ca-
pabilities belong to the set CP.
Definition 4. hs
ι
j
, s
N
j
, s
E
j
, servTransit
j
, servState
j
i is a
service s
j
, where s
ι
j
provides the details of the func-
tional specification of the service, (s
N
j
, s
E
j
) defines
a directed acyclic graph. Nodes represent states,
and edges transitions between states. The two func-
tions label nodes and edges with capability infor-
mation: servTransit
j
: s
E
j
7−→ CP is a partial func-
tion returning the capability for a given edge in
the graph, while servState
j
: s
N
j
7−→ {cp
pre
i
}
cp
i
∈CP
∪
{cp
post
i
}
cp
i
∈CP
maps each edge to a condition from the
set of all capability preconditions (i.e., {cp
pre
i
}
cp
i
∈CP
)
and postconditions (i.e., {cp
post
i
}
cp
i
∈CP
). The capa-
bility specified on an edge must have the precondition
and postcondition corresponding to conditions given,
respectively, on its origin and its destination node.
A service can therefore be understood as a pro-
cess, composed of a set of Tasks and Goals (i.e.,
these are specializations of capability) ordered over
the graph representing the service. The functional
specification of the service, i.e., s
ι
j
is not of interest
here, but involves in practice, e.g., a specification of
interfaces, and other implementation considerations.
Requesting a service requires the specification of ex-
pected QoS, in addition to a deadline for providing
the service, minimal level of reputation for agents
that are to participate in service execution, the max-
imal monetary cost, and explicit user preferences on
agents to select (e.g., users may prefer globally the
services of some providers over others, regardless of
actual performance—this may occur with preferen-
tial threatment resulting from environment constraints
such as, e.g., legal constracts on cooperation between
organizations and/or individuals).
Figure 4: The service depicted as a labeled hypergraph.
Definition 5. A service request ˆs
j
is
hs
j
, s
QoS
j
, s
D
j
, s
R
j
, s
cost
j
, s
pref
j
i, where:
• s
j
is the service to provide.
• s
QoS
j
specifies expected qualities and their re-
quired level. Its definition follows a QoS ontology,
such as, e.g., the FIPA QoS ontology specification
(for Intelligent Physical Agents, 2002). What-
ever the specific QoS ontology, expected quali-
ties are likely to be specified as (at least) s
QoS
j
=
h(p
1
, d
1
, v
1
, u
1
), . . . , (p
r
, d
r
, v
r
, u
r
)i, where:
– p
k
is the name of the QoS parameter (e.g., con-
nection delay, standards compliance, and so
on).
– d
k
gives the type of the parameter (e.g., nomi-
nal, ordinal, interval, ratio).
– v
k
is the set of desired values of the parameter,
or the constraint <, ≤, =, ≥, > on the value of
the parameter.
– u
k
is the unit of the property value.
• s
D
j
is a deadline, specified as a natural.
• s
R
j
specifies minimal levels of reputation over task
quality parameters that any agent participating in
the provision of the given service must satisfy. It
is not necessary to specify reputation for all qual-
ities over all tasks, selective reputation expecta-
tions are admitted.
• s
cost
j
is the maximal monetary cost the user re-
questing the service is ready to pay to obtain the
service.
• s
pref
j
is a set of expressions that constrain the pool
of potential agents to which the service mediator
can allocate tasks.
By conceptualizing the service as suggested in
Def.4, the service is thus mapped onto a directed hy-
pergraph G where each node is a step in service pro-
vision and an edge in G corresponds to the execution
of a capability cp
k
by a specialist agent a
SA
k,u
, where u
ranges over specialists that can execute cp
k
according
to the criteria set in the service request. Each individ-
ual edge is labelled by a function of the criteria set,
A SERVICE-ORIENTED FRAMEWORK FOR MAS MODELING
125
Client
ServiceProvider
Travel Planner
Denial ofService
Lower Response Time
Use
a Task Allocation
Algorithm
Agent
Service
Threat
Opportunity
Operational solution
Security
Figure 5: Strategic Services Diagram - Travel Planner.
c(cp
k
, a
SA
k,u
), representing the QoS advertised by the
specialist a
SA
k,u
for performing the capability cp
k
. Each
path from the starting node (e.g., node s1 in Figure 4)
to the destination node (node s13 in Figure 4) thus
corresponds to a sequence of capabilities ensuring
the completion of the service within the prescribed
QoS. The model thus assumes that there are alterna-
tive ways for completing the service. The topology
of the graph—i.e., the node structure and the capabil-
ities associated to edges between the nodes—is pro-
vided by the designer through the service definition,
so that the graph is a graphical model of the different
ways the service can be performed as a sequence of
capabilities.
5 CASE STUDY
In this section, the framework is applied to a simpli-
fied case study: the travel planning service. Travel
planning regroups all the activities provided by a ser-
vice provider destined to organize a business or hol-
iday trip. Those activities include the booking of fa-
cilities such as an hotel, a flight, a car, a taxi, etc.
The different dimensions of a service description and
fulfillment will be envisaged, their complementarities
will be illustrated.
5.1 The Strategic Services Diagram
Figure 5 depicts the Travel Planner’s Strategic Ser-
vices Diagram.
In this service, the Customer addresses to a Travel
Planner for its travel organization. The Travel Planner
is in charge of the Commodities Booking to the Re-
source Provider (which can be an hotel resort, a flight
company, a taxi company, etc. i.e. all the companies
furnishing commodities to the Customer) for the des-
tination of the Customer on the basis of its Budget,
Proposed Date and Agreement.
Figure 6: Strategic Dependency Diagrams: Travel Planner.
Figure 7: Strategic Rationale Diagrams: Travel Planner.
5.2 Strategic Dependency Diagram
Figure 6 illustrates a strategic dependency diagram of
the Travel Planner system’s requirements. The system
is intended to support a customer and a travel planner
in travel related activities. Three actors are introduced
into this diagram: Travel Planner is responsible for
the organization of the travel and the necessary reser-
vations. Customer gives these preferences concerning
its travel which he wants to plan. Resource provider
deals with providing the various resources helping to
planning.
A strategic rationale diagram of the Travel Planner
system’s requirements is depicted in Figure 7. This
Figure details the various actors introduced into the
strategic dependency diagram.
5.3 Dynamic Services Hypergraph
Figure 8 represents fulfilment paths for the service
Travel Planner. Each node is a step in service provi-
sion and each edge corresponds to the execution of a
task t
k
by a specialist agent a
SA
k,u
, where u ranges over
specialists that can execute t
k
according to the crite-
ria set in the service request. A function of the crite-
ria set, c(t
k
, a
SA
k,u
), labels each edge and represents the
QoS advertised by the specialist a
SA
k,u
for performing
the task t
k
. Note that different paths offering different
ICEIS 2008 - International Conference on Enterprise Information Systems
126
Figure 8: Strategic Dynamic Diagram - Travel Planner.
QoS are available. Indeed, path < t
1
,t
2
,t
3
,t
4
,t
6
,t
7
>
offers alternative ways of fulfilling the service. The
following list gives a descritpion of each task used in
the Hypergraph.
• t
1
:The customer proposes a range of dates fitting
for his travel.
• t
2
:The customer expresses the maximal budget he
is able to allow for his travel.
• t
3
:The Resource Provider gets a list of proposition
for commodities on the basis of the customer con-
straints.
• t
4
:The customer selects its preferredcommodities.
• t
5
:On the basis of the constraints defined, the Ser-
vice provider organises a trip plan for the cus-
tomer. Finally, the Service Provider books the
commodities (i.e., flight, hotel, ...).
• t
6
:The customer accepts a list (date, budget, flight
and hotel) proposed.
• t
7
:The Resource Provider provides the resource to
the customer.
5.4 Lessons Learned
This simplified case study allowed illustrating:
• The use of different levels of knowledge:
– A first level materialized through the SSD
where stakeholders can have an aggregate view
of the services the system offers as well as the
threats and opportunities;
– A second level materialized through the SDM,
SDM and DSD to decompose the service in a
static and dynamic manner. In this view ana-
lysts can see respectively the actors involved as
well as the multiple realization paths.
• The alternative paths in the hypergraph with dif-
ferent QoS.
To demonstrate the real contribution of the frame-
work it should however be applied to a broader case
study implying multiple services. Due to the lack of
space this was not possible here.
6 CONCLUSIONS
As identified several times in literature, the Tropos
methodology in general and i* framework in partic-
ular lacks proper elements for driving the soft pro-
cess. Indeed, even if the qualities and advantages of
the strategic dependency and strategic rationale mod-
els has been recognized, redundancy, various levels
of aggregation and alternative modeling ways make
them hard to use in the context of model driven soft-
ware development. That is why a broader framework
for analysis stages of i*/Tropos is needed.
The framework furnishes multiple views for
model driven software development. This framework
includes a high level service view allowing to iden-
tify in a non redundant way the services that must be
fulfilled by the system as well as elements raising or
lowering QoS. Such framework is much broader than
only allowing organisational modeling and require-
ments engineering. Indeed the framework can be ex-
tended for risk, quality or time management. The aim
is consequently to create a complete software project
management dimension for Tropos based on the mod-
els of the framework; this work is in progress; a CASE
Tool is also under development.
Future research directions will include systematic
forward engineering rules based on the models in
the framework. This work has partially been done
in (Do et al., 2003) but needs to be extended to in-
clude the benefits of dynamic models as the Strategic
Services Hypergraph. Such systematic approach will
provide guidelines to software designers to facilitate
the framework adoption.
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