Toward User Profile Representation in Adapted Mediation Systems
Sara Ouaftouh, Ahmed Zellou and Ali Idri
Mohammed V University In Rabat, Rabat, Morocco
Keywords: User Modeling, Mediation Systems, User Model Representation.
Abstract: The amount of information offered by different software systems is growing exponentially and the need of
personalized approaches for information access increases. This personalization aims to offer the user the
pertinent information corresponding to his needs basing on his profile. For the same purpose, mediation
systems have to identify user preferences in order to offer him the most relevant information .In this work
we discuss different representations of user profile models designed for providing personalized information
access in order to make a comparison and identify the most appropriate for our context in mediation systems.
1 INTRODUCTION
Today, the amount of information available in the
different information systems is increasing expo-
nentially. This information can be in heterogeneous
sources: relational or object sources, flat files,
structured data, applications, web services, etc.
In order to integrate these heterogeneous
information sources and offer an added value to its
services, information systems in different domain
are using data integration technologies. We basically
distinguish between two principle integration
methods: physical integration (J. Widom, 1995) and
virtual integration. The virtual integration also called
mediation allows combining a set of different
information sources by allowing a real-time access
to the sources while concealing their particularities
(G. Wiederhold, 1992). The mediation system must
be able to intercept user queries on the information
system and return appropriate responses.
However, any system that doesn't know who is
asking for information and for what purpose, will
never be able to provide more than general answers.
Therefore, we need a mechanism to adapt the
behavior of information systems to user's preferen-
ces. When a system integrates this mechanism of
adaptation, it is called an «Adaptive system» (K.
Cheverst et al., 2002). These mechanisms must be
able to provide the system with some "context
awareness" by extracting from the user context, the
information needed to identify his preferences. The
system will then provide the user with personalized
services. The personalization or adaptation in
information system is based on the concept of user
profile.
The user profile is defined as a set of information
describing the user and simulating his preferences.
The user profile is considered as a set of structured
data describing the interaction environment between
a user and a system (Y. Elallioui and O. El Beqqali,
2012). In the domain of Internet search engines (S.
Calegari and G. Pasi, 2010), the user profile is used
in order to have structured representation of user’s
interests.
The implementation of a user profile requires the
creation of a user model (R. Guha et al., 2015).
Adaptation via user modeling has started by the end
of the 1970s before the introduction of the Web (A.
Kobsa, 2001), recently it has become a main compo-
nent of many web applications and information
systems in general.
In this work we present a comparison between
the different representations of a user profile in order
to deduce the most appropriate to adapt in the
context of mediation system personalization.
The remaining parts of this paper can be
summarized as following: in section two, we present
mediation systems. Section three describes the
different factors that made the personalization of
mediation system a necessity to satisfy user’s
expectations while section four is dedicated to
discuss the different representations of user models
that will be compared and discussed in section Five.
We conclude then this paper and shares some future
works.
Ouaftouh, S., Zellou, A. and Idri, A.
Toward User Profile Representation in Adapted Mediation Systems.
DOI: 10.5220/0006043000810087
In Proceedings of the 8th International Joint Conference on Knowledge Discovery, Knowledge Engineering and Knowledge Management (IC3K 2016) - Volume 2: KEOD, pages 81-87
ISBN: 978-989-758-203-5
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
81
2 MEDIATION SYSTEMS
Integration systems permit to link together
information coming from sources that are often
heterogeneous and distributed in order to provide a
global view of information to users.
In our work, we focus on the mediator approach
(G. Wiederhold, 1995) which consists of a mediation
layer between the user and information sources in
order to provide the user with a centralized and
uniform view of information by hiding specific
characteristics of their location, access methods and
formats. An information source can be in different
formats.
Figure 1: Mediation architecture.
In a general manner, the user interacts with the
system by querying a global schema (M. Lenzerini,
2002) which is a virtual representation of the data on
the sources. In the one hand, the mediation system
will perform the sources processing task to retrieve
information satisfying the user query. On the other
hand, the mediation system will hold an internal
representation of information sources, called source
or local schema, so that relations exists between
global entities and the local schema: the mapping
represents these relationships. Some software
modules called wrappers hide source characteristics
to facilitate the interaction between the mediation
system and the sources.
Mediation systems are very useful in the
presence of heterogeneous data sources, because
they make the user feel like using a homogeneous
system. Among the different categories of mediation
systems applications, we can mention the
information retrieval applications; online decision
support systems and more generally, knowledge
manage-ment applications.
However, mediation systems represent some
limitations, including the fact that query rewriting in
terms of data sources views requires the knowledge
of the sources. There is also the risk of non-
availability of all information sources needed to
build a response at the time of issuing the request by
the user. Furthermore, it is important to address the
problem of adaptability of the mediation system to
users’ needs due to the large number of data sources,
which may contain redundant information and
varying quality. In our work, we are interested in
how to personalize mediation systems in order to
resolve this last problem.
3 NECESSITY TO PERSONALIZE
MEDIATION SYSTEMS
As we presented in the previous section, despite the
benefits of mediation systems, they suffer from
some inconvenient. The one we are interested in our
work is caused by the big number of information
sources, which may contain redundant information
in addition to vocabulary problems like polysemy
and synonymy. In general, the evaluation of a user
query is independent of the context and the needs of
the user who issued it. Therefore, the same query
submitted by two different users, produces the same
results even if these users have different
expectations which could make the search results of
mediation systems not beneficial to the user. The
user is then faced to a large number of information
that doesn’t correspond to his expectations when he
submitted the request. However in personalized
systems, the user preferences are included. Applying
personalisation in an e-commerce context for
example, if two different users send the same query
to look for shoes, they could get different results.
Considering that the first user is a girl who lives in
Brazil; she will get as propositions, teenager sandals
style corresponding to the warm weather in Brazil.
The second user who is a 60 years old man living in
Germany will get shoes corresponding to old people
generation. In addition to adapted results, e-
commerce web site implement the concept of
recommender systems that permit the possibility to
give the user suggestion about recommended content
that could interest him according to his profile.
In order to offer the user the personalised answer
adapted to his expectations, we need first to identify
his needs and preferences. Many works in the
literature discusses how information systems are
being adapted to user’s expectations. Adapted
systems take into account the different
characteristics of the user and his situations in
different contexts basing on the concept of user
profile.
KEOD 2016 - 8th International Conference on Knowledge Engineering and Ontology Development
82
We usually distinguish two phases in the
modelling of the user profile: initialization and
update. In fact, the profile is initialized on the first
use of the system. The first elementary step to build
the user profile is the collect of user’s information (S.
Schiaffino and A. Amandi, 2009). We separate here
between three methods: Explicit, implicit and hybrid
information gathering. To build a user profile
different dimensions are considered: user’s
knowledge, preferences, habits, physical abilities,
intentions, psychological states and geographical
location (S. Ouaftouh et al., 2015). This list is not
exhaustive, it could include, for example, personal
data about the user, his professional or social role,
etc. These dimensions can represent relatively stable
characteristics over time or changing ones that are
therefore updated over the time. In general, the
nature of the information contained in the user
profile strongly depends on the application and
purpose of the system that implements it. The user
profile is then evaluated, modelled and represented
in a particular form. In this context and in a
perspective of user profile integration in the
conception of mediation systems, what is the most
appropriate user profile representation?
4 USER MODEL
REPRESENTATIONS
Adaptive systems are based on user model in order
to have different behaviors for different users. The
User Model is a representation of the information
about a specific user. In literature, we find different
categorizations for user models basing on different
characteristics.
A. Keyword-based User Modeling:
Keyword-based user modeling was initiated in the
domain of information retrieval and filtering (P.
Brusilovsky and C. Tasso, 2004), where the content
of a document is represented as a vector of terms
called keywords, extracted from the text. The
adaptive information retrieval and filtering applica-
tions combined for example a history of user’s
queries, accessed documents, e-mails, chat, etc. in a
form of a keyword vector and use this vector for
adapting a future retrieval or filtering process.
Many adaptive systems model users’ information
interests or needs as vectors of keywords extracted
from the documents that the users have browsed or
requested. Figure 2 is an example of a keyword
vector representation that models user interest in a
particular domain of interest, each keyword «K
i
»,
corresponds to a term found in the content of
document consulted by the user. Each keyword «K
i
»
is associated with a numerical weight «W
i
»
representing its importance in the profile.
(W
i,
K
i
)
Domain of interest
W
1
W
2
W
3
… W
n
K
1
K
2
K
3
… K
n
Figure 2: Keyword-based user model representation.
Each keyword can represent a topic of interest.
Keywords can be grouped in categories to reflect a
more standard representation of users’ interests.
Some systems model users’ interests as networks of
keywords instead of plain lists, where nodes
represent keywords and arcs connect keywords co-
occurring in the content.
Keyword-based modeling support only simple
content data. To remedy problems like homonymy
and synonymy, Natural Language (NL) technologies
are required. Pure keyword based modeling is not
able to represent the true meaning of the content. It
relies on statistical regularities within the text and
provides a framework for retrieving statistically
close documents.
B. Overlay User Modeling:
This approach also called concept user modeling,
was employed for the first time in 1988. It’s about
graining the domain knowledge into elementary
components and using them to evaluate user’s
knowledge. The domain knowledge components
have been named differently by different authors:
topics, knowledge elements and – the most used –
concepts.
Figure 3: Overlay user model.
A concept represents an atomic piece of
declarative domain knowledge, coherent and
semantically complete. An aggregate of concepts
forms the domain model. The overlay user model
Toward User Profile Representation in Adapted Mediation Systems
83
consists on a set of concept-value pairs, where the
value represents an assessment of a particular
concept. The user is characterized in terms of user’s
knowledge about these concepts in relation to the
top level knowledge.
As shown in figure 3, «Ci», correspond to the
different concepts from a domain knowledge, the
user model represent user knowledge about these
concepts in relation to the ideal knowledge level.
The benefit of the overlay user model is its precision
and flexibility. An overlay model is capable to
dynamically and precisely reflect the evolution of
users’ characteristics.
C. Stereotype User Modeling:
The main goal of adaptive systems is to adjust its
behavior to each user’s needs. However, for some
contexts it is possible to identify typical categories
of users that use the system the same way, expect
from it similar reactions and can be described by
similar characteristics. These categories are called
stereotypes. Stereotype user modeling is one of the
oldest approaches to user modeling. It was
developed in the works of Elaine Rich (E. Rich,
1997). An adaptive system using stereotype-based
modeling does not update every single feature of the
user model directly; it uses a stock of preset
stereotype profiles. Hence, the application can make
expectations about a user even though there could be
no data about that specific area, because studies have
shown that other users in this stereotype have the
same characteristics. Such categories are called
stereotypes.
Figure 4: stereotype user model.
As shown in figure 4, an adaptive system in a
specific context can identify a set of stereotypes Si
and each user «U
i
» of the system is assigned to a
stereotype. A stereotype can correspond to one or
many users.
As an example of stereotype-based user modeling is
linear set of categories for typical levels of user
proficiency: novice, beginner, intermediate, and
expert.
Stereotype-based user modeling is advantageous
when from a little evidence about a user the system
should infer a great deal of modeling information.
However, for modeling fine-grained characteristics
about users as is the case in knowledge level of a
particular concept, the overlay models should be
employed.
D. Constraint-based user Modeling:
Constraint-Based model is a way to represent the
domain knowledge as a set of constraints. It is
mostly used for modeling users in Intelligent
Tutoring Systems (A. Mitrovic, 2012). Constraint-
based tutors are Intelligent Tutoring Systems that
use Constraint-Based modeling to represent the user
model as a set of information about abilities,
knowledge and needs of the user. Constraint-based
tutors are problem-solving environments; in order to
provide personalized instruction; they diagnose users’
actions, and maintain user models. These models are
then used to provide appropriate examples and offer
hints and help where the user is most likely to need
them. In this approach, every constraint represents
an acceptable set of equivalent problem states and a
violated constraint indicates an error.
Each constraint consists of an ordered pair (Cr, Cs),
where Cr is the relevance condition and Cs is the
satisfaction condition. The relevance condition
checks whether the constraint is applicable to the
user solution by testing the features of the solution.
The satisfaction condition specifies additional test
that must be met by correct solutions. If the
relevance condition is met, but the satisfaction
condition is not, then the user’s solution is incorrect.
Therefore, the general form of a constraint as
presented in figure 5 is:
(Cr ,Cs)
If <
Cr > is true,
Then <
Cs > had better also be true.
Figure 5: Constraint-based user modelling.
E. Collaborative Filtering:
Being different from user modeling technologies
cited before, this approach relies on modeling the
user in terms of his relationships with other users. A
typical collaborative user model is based on a vector
of ratings that the user provided for particular items.
The original implementation of this approach is
recommender systems (N. Tintarev and J. Masthoff,,
2011), they recommend to the active user the items
that other users with similar preferences liked in the
past. The similarity in preference of two users is
calculated based on the similarity in the rating
history of the different users. The central hypothesis
KEOD 2016 - 8th International Conference on Knowledge Engineering and Ontology Development
84
behind this method is that other users’ opinions can
be selected and combined in such a way to provide a
reasonable prediction of the active user’s preference.
Intuitively, we assume that, if users agree about the
quality or relevance of some items, then they will
likely agree also about other items.
The information domain of a collaborative filtering
system consists of users which have expressed
preferences for various items. A preference
expressed by a user for an item is called a rating and
is frequently represented as a (User, Item, Rating)
triple. These ratings can take many forms, depending
on the system. Some systems use real or integer
valued rating scales such as 0–5 stars, while others
use binary (like/dislike) scales (J. B. Schafer et al.,
2007). As represented in the example in table 1, the
set of all rating triples forms a matrix referred to as
the ratings matrix. The values of R
j
correspond to
the rating each user U
i
gave to a specific item I
k
.
(User, Item) pairs where the user has not expressed a
preference for the item are unknown values in this
matrix and are marked with ‘?’ to indicate unknown
values i.e. the user has not rated that item.
(U
i,
R
j,
I
k
)
I
1
I
2
I
3
… I
m
U
1
R
1
? R
2
… R
3
U
2
? R
4
R
5
… ?
… … … … … …
U
n
R
6
R
7
R
8
… ?
Figure 6: Collaborative filtering using ratings matrix.
Given a user and an item, what is the user’s likely
preference for the item? If the ratings matrix is
viewed as a sampling of values from a complete
user–item preference matrix, than the predict task
for a recommender is equivalent to the matrix
missing values problem.
Recommender technology, often based on
collaborative filtering, has been integrated into many
e-commerce and online systems. An important
motivation for doing this is to increase sales volume;
customers will likely buy an item if it is suggested to
them but may not otherwise.
F. Bayesian Networks:
Bayesian Networks are probabilistic graphical models
that consist of a qualitative and a quantitative part.
The qualitative part is the structure of the network: a
directed acyclic graph where nodes correspond to
variables and arcs representing influences between
variables. The quantitative part provides the condi-
tional probability tables that make up the network
settings.
More precisely, a Bayesian Network is a set
consisting of a directed acyclic graph and n random
variables
(X
l
, X
2
, .. , X
n
) such that there is a bijection between
the set of vertices graph and the set of random
variables and that:
P(X1, X2, .. , Xn) =
∏
P(Xi|pa(Xi))
where pa(Xi)
is the set of parents of X
i
in the graph.
Multiple systems used Bayesian Networks to model
the relations between different components or
dimensions of a user model, such as emotions, goals
and knowledge (X. Zhou and C. Conati, 2003).
Other systems used them to implement an overlay
user model with internal inference capabilities, where
every node represents a domain concept and links
represents the concept relations (F. De Rosis, et
al.,1992).
In the e-commerce applications, it is often useful
to model a customer without developing any explicit
modeling rules about him, but only by identifying
certain statistical predictabilities that can be used for
constructing an effective selling strategy. A user
model in this case can contain a set of transactions
matched against an association rule of items bought
together or satisfying some conditions of buyers’
behavior, or belonging to a cluster of similar buyers
(S. Sosnovsky, 2010).
5 COMPARISON AND
DISCUSSION
A. Comparison:
After having presented the different categories of
user models and the different representations, we
constructed a table summarizing each type of user
model representation to help us make a comparison.
Table I represent for each category, the definition,
representation, explication, principle domain of use,
advantages and disadvantages.
After having presented the different categories of
user models and the different representations, we
constructed a table summarizing each type of user
model representation to help us make a comparison.
The keyword based modeling approach can be
considered lightly similar to overlay user modeling
because it uses elements of domain representation as
a reference to express user characteristics. Overlay
user modeling is most used to model student
knowledge in e-learning systems while keyword
based models are used to model user interests for
example in the domain of information retrieval and
filtering. Constraint-based models are also used in
Toward User Profile Representation in Adapted Mediation Systems
85
Table 1: Comparison table between different user model representations.
Name Overlay Keyword Stereotype Constraint-based
Collaborative
Filtering
Bayesian
Network
Principe
Measure how well
a user knows a
concept.
Measure user’s
interests on a
specific keyword
Define typical
categories of users.
Define a set of
constraints
representing
domain
knowledge.
Model user in
terms of his
relationships with
other users.
Model the
relations between
the components of
a user model
Representation
Vector of Concept-
value pairs.
Vector of
keywords-value.
Set of preset
profiles.
Set of constraints. Vector of ratings :
(User, Item,
Rating)
Directed acyclic
graph
Explication
Concepts are
subset of domain
knowledge.
Keyword extracted
from the text
consulted by the
user.
Users that belong
to the same
stereotype
described by
similar
characteristics.
Diagnose of user’s
actions to provide
personalized
instructions and
decisions.
Predict user
interest basing
similar user’s
feedback.
Nodes of the graph
represent variables
and arcs represent
influences between
variables.
Principle
Domain of use
E-learning:
Modeling user’s
knowledge.
Information
retrieval and
filtering.
Model user
interests.
Modelling groups
of users.
Modeling user’s
knowledge in
Intelligent
Tutoring Systems
Recommender
system: predicting
user's interests and
preferences.
Modeling
emotions, goals
and knowledge.
Advantages
Automatic
modeling of
content.
Faster results Make expectations
about a user even
though there is no
data about him
Encodes
correct domain
knowledge
No need to
additional
information about
user except
ratings.
Model a user only
by identifying
certain statistical
predictabilities
Disadvantages
Support only
simple content.
Support only
simple content
data.
Lack of semantics
and Polysemy.
Use of preset
profiles, no update
to users’ features
Overspecificity: a
highly detailed
model of user’s
knowledge
Cold-start
problem : no rating
available in the
start of the system
Difficult reaching
agreement on the
Bayesian network
structure with
experts
the domain of e-learning especially for intelligent
tutoring systems to model students’ knowledge
basing on a set of constraint.
For its part stereotype user modelling can be used
to model groups of users in the case the categories of
system’s user are predefined.
Collaborative filtering modeling is mainly used in
recommender systems to predict user’s interests and
preferences. This method utilizes only ratings and do
not require any additional information about users or
items. The principal disadvantage of Collaborative
filtering systems is the Cold-Start problem which
cannot produce recommendations if there are no
ratings available.
To model emotions, goals and also knowledge,
the Bayesian network approach can be used with the
advantage of modeling the user only by identifying
certain statistical predictabilities.
B. Discussion:
Roughly, the user dimension considered in a
particular system depends on the intended field of
application. For example, in the domain of e-
learning we are mainly interested to model user’s
knowledge, skills and interests. In e-commerce
context, it’s more interesting to know user’s
preferences. Among the deductions of our
comparison between the different user models
representation, each representation is satisfying the
particularities of a certain application domain.
In order to select the suitable user model
representation for our context, which is mediation
systems, we have to specify our system’s
characteristics. To personalize a mediation system,
we are interested to model the most of user’s
dimensions. Mediation systems are characterized
with a set of exchanges between the mediator and
sources (couple of requests and responses). We can
then recommend the use of keyword based user
modeling or collaborative filtering as the most
appropriate to be applied in a mediation system
context.
KEOD 2016 - 8th International Conference on Knowledge Engineering and Ontology Development
86
6 CONCLUSIONS AND
PERSPECTIVES
A mediation system is a powerful tool allowing easy
access to different information collected from
distributed data sources that can be heterogeneous. It
must integrate diverse information in order to
provide the user with a centralized and uniform view
of data by masking the specific characteristics of
their location, access methods and formats. In a
perspective of mediation system improvement, it has
been necessary to adapt system’s responses to user’s
expectations, represented by his profile, via the
implementation of a user model.
The user profile corresponds to a set of
information describing the user. It contains data that
represent user preferences. The implementation of a
user profile requires the creation of a user model. To
identify the most suitable user model representation
in a mediation system, we presented a study about
the different approaches found in the literature.
Many authors have classified user modeling
approaches basing on a variety of criteria.
As our goal is to evaluate the user profile, we
were based on user model representation and
distinguish between overlay, keyword, stereotype,
constraint-based, collaborative filtering and
Bayesian network models. Each representation is
mainly used to model a set of user’s dimension and
is generally applied in a particular domain of use.
Practically, the user dimension considered in a
particular system depends on the envisioned field of
application. Referring to the particularity of
mediation system and as deduced from the
comparison table of user models that we constructed,
we recommend the use of keyword user model or
collaborative filtering approach.
In our future work, we will focus on applying
one of the suggested representations to personalize
mediation systems. This model will implement a set
of dimension that we qualified necessary in a
mediation system.
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