Towards a Dynamic Adaptation of Documents within Pervasive

Information Systems

Karim Djemal

, Chantal Soule-Dupuy

and Nathalie Valles-Parlangeau

BSC France, Tour Montparnasse, 33 Avenue du Maine, 75755 Paris, France

IRIT/ University of Toulouse, 118 Route de Narbonne, F-31062 Toulouse Cedex 9, France

Keywords: Pervasive Computing, Document Adaptation, Dynamic Adaptation, Multistructurality, Contextual View,

Adaptation Process.

Abstract: Nowadays, Pervasive Information Systems has increasingly become a focus of communication technologies

development. In this paper, we focus on document adaptation within Pervasive Systems. Such adaptation is

reached using document multistructurality. In fact, each document structure may represent a different

document view which is adapted to a particular context. Thus, we introduce the MVDM model which

ensures on the one hand, the multistructured document management, and on the other hand, the generation

of new contextual views that are suited to different uses. In order to illustrate the feasibility of our approach,

we provide a process of document adaptation based on the MVDM model.

1 INTRODUCTION

With the advent of new information and

communication technologies, new needs have

emerged mainly requirements dealing with

exploitation of document that represents the biggest

information source. In fact, the rapid development of

mobile computing (mobile phone, laptop, PDA and

so on...) induces new applications and new

challenges. This development has promoted the

notion of Pervasive Computing. To be in such

context requires the design and the development of

the reliable and powerful methods and tools that

exploit the document information. These methods

and tools must make the information accessible at

anytime and anywhere, regardless of the devices

used.

The main goal of our work is to propose a

solution to dynamically manage and create adapted

document representations from the integration of all

available document information in function of

contextual situation. Thus, we present a solution for

the document adaptation in response to a user

request in a given context. The capacity offered by a

model of multistructured documents include the

consideration of different views attached to a

document, but also offer the option to add other

views linked to that document. These views can

generate different contextual representations of a

document adapted to context.

After presenting the general context of our work,

we present some related works which deal with

adaptation. In this paper we focus on the document

adaptation and therefore we detail the various issues

involved. We propose a solution based on the

document multistructurality. Thus, we formalize a

methodology for modeling these documents. This

methodology is based on a fragmentation technique:

the document is divided into structural nodes

connected by relations. This fragmentation allows to

link each piece to one or more views. From these

views, we propose to generate contextual

representations of the document. To illustrate our

proposal, we treat the example of a medical file that

must be adapted to the context of its use. Through

this example, we present some instantiations of our

model. Finally, we propose a process of dynamic

adaptation of documents. This process describes the

various possible cases of adaptation.

2 PROBLEM AND AIMS

Ubiquitous systems are designed to make

information available at anytime and anywhere.

These systems must be used in different contexts

according to user's profile, location, application and

devices (see Figure 1).

176

Djemal K., Soule-Dupuy C. and Valles-Parlangeau N..

Towards a Dynamic Adaptation of Documents within Pervasive Information Systems.

DOI: 10.5220/0004002001760182

In Proceedings of the 14th International Conference on Enterprise Information Systems (ICEIS-2012), pages 176-182

ISBN: 978-989-8565-11-2

 2012 SCITEPRESS (Science and Technology Publications, Lda.)

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TowardsaDynamicAdaptationofDocumentswithinPervasiveInformationSystems

177

document. (Mogul, 2001) focuses on the

transcript image for the web. The advantage of

these works is the centralization of adaptation

mechanisms. Thus, the entity adaptation for a

particular context is applied only once on the

server. Conversely, poor knowledge of the

client’s characteristics may be source of

erroneous information and therefore a source of

a bad adaptation. Moreover, despite their ability

of processing, the servers may be congested due

to many requests and may not be able to satisfy

some clients. To resolve this problem, (Luo et

al., 2004) have proposed an adaptation by

rewriting queries. This solution allows to secure

data exchanged through the creation of virtual

views.

In this paper we focus on the dynamic adaptation

of document content on the server side. The question

that arises is how to deliver the adapted document

for a suitable context. Should we define in advance

the contextual situations and jointly document

descriptions arising? Or must we generate

dynamically an adapted document according to a

suitable context?

The definition and storage of different document

versions according to any contextual situation ensure

adequate adaptation because there are as many

document versions as possible contextual

combinations. However, this solution generates a

complexity, redundant storage and a lack of

flexibility due to the difficulty of taking account of a

not predefined contextual situation.

The ad hoc generation of contextual

representations of the document provides a dynamic

adaptation. This generation may be done by a direct

matching between the original structure of the

document and the structure defined by the context.

In this case, the problem is the reliability of results

given the heterogeneity that might exist between the

two structures to compare.

3 FROM

MULTISTRUCTURALITY TO

ADAPTATION

Documents, complex or not, can be defined and

described through different structures that are linked

to the nature of documents or related to the uses that

may be done. These structures may be more or less

independent. They might contain their own

fragments or use those of one or many structures

while adding additional information. Therefore, a

same document may be represented through several

structures having a same nature according to the

context for using this document. The use of these

structures seems to be an appropriate solution to

generate a contextual representation of the

document. In fact, each structure has a particular

document organization. It allows to identify

unambiguously the information fragments that

compose the document, and their emplacement.

Thus, to be able to adapt the description of

document to any content, it is necessary to fragment

this document in structural nodes that are connected

through various kinds of relations. A relation

connects two nodes according to a particular view.

Each view represents a sub-structure of the overall

structure of a document. It is then composed of a set

of nodes included in the set of nodes extracted from

this document. The view notion is used to define the

several types of structures (Djemal et al., 2008).

Taking into account the different views related of

a same document seems to be an appropriate

solution to find the adequate document

representation according to a particular context.

Each view represents a particular context. For

example, we can get an “expert” view and a

“framework” view, etc.

Thus, we defined two types of views:

 Structural views: to identify the different types

of structures.

 Contextual views: to take into account the

various contextual representations of a

document.

To describe these structural and contextual

views, we propose the model MVDM presented in

what following, as well as adaptation capabilities it

offers.

3.1 MVDM Model

The model MVDM “Multi View Document Model”

is designed to manage multistructured documents. It

includes both levels generic one and specific one

(Djemal et al., 2008).

Generic Level. The generic level provides a

meta representation of documents. In this level, the

views are described of a generic way regardless of

the document specifications.

The notion of generic structure (GS) allows to

group documents in classes. Each document class is

considered as an homogenous and coherent

document set of a structural point of view.

Specific Level. The specific level characterizes

the special document features. Therefore, it

identifies the different fragments of this document

ICEIS2012-14thInternationalConferenceonEnterpriseInformationSystems

178

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TowardsaDynamicAdaptationofDocumentswithinPervasiveInformationSystems

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ICEIS2012-14thInternationalConferenceonEnterpriseInformationSystems

180

Figure 5 in APPENDIX).

5 CONCLUSIONS

This paper proposes a solution for the document

adaptation within pervasive information systems.

This solution is based on the management of

document representations through contextual views.

The representation and the coordination of these

views are established according to MVDM Model.

In fact, this model manages two kinds of views:

structural views and contextual views. Through

these views, it is possible to define several structures

for a same document. From these structures, context

adapted documents are generated.

To achieve these goals, we propose an adaptation

process based on the MVDM Model. This process

ensures:

 the document adaptation to a contextual

predefined situation. This kind of adaptation is

guaranteed by the matching between the SS of

the original document and the GV representing

the contextual situation,

 the document adaptation to a undefined

contextual situation. This done through the

generation of new GVs adapted to new contexts.

There are two approaches to manage the

multistructurality: one based on models (Bruno et

al., 2006) (Chatti et al., 2007) (Le Maitre, 2006) and

another based on syntax (Huitfeldt, 1993) (Sperberg-

McQueen et al., 2004). The MVDM model is part of

the first category of approaches. The breakdown of

multistructurality related works is presented in

(Djemal et al., 2008). The use of approaches has

shown the need of further treatment to exploit these

documents. In fact, the syntactic approaches require

a specific parser to the proposed solution, while the

approaches based on models require specific

language (for example some extensions of XQuery

languages).

The originality of the MVDM model lies on the

definition of the generic level. This level has two

particular meta classes: “GenStr” and “GenView”.

The “GensStr” serves as a grammar or schema for a

multistructured document. “GenView” represents

one of the structural descriptions of this document.

Thus, each GV allows to define clearly the structural

organization of a SV which is used to generate the

adapted version of a document.

Our proposals have been validated through a tool

entitled MDOCREP (Multimedia Document

Repository), which integrates and analyzes the

multistructured documents and especially

multimedia documents. We have shown the ability

of this tool to manage the incorporation of multiple

views of a document. Therefore, it can generate the

adapted documents according to these views.

The evaluation of our system within dynamic

context is a major concern, which we will consider

in our future work. Concretely, we will try to define

interchange mechanisms and protocols in order to

transfer contextual parameters and adapted

documents. These must be done within an

architecture specific to our proposals.

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