DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE
MANAGEMENT FRAMEWORK FOR PROFESSIONAL
VIRTUAL COMMUNITY IN KNOWLEDGE-INTENSIVE
SERVICE INDUSTRIES
Yuh-Jen Chen
Department of Accounting and Information Systems, National Kaohsiung First University of Science and Technology
Kaohsiung, Taiwan, China
Meng-Sheng Wu
Institute of Manufacturing Information and Systems, National Cheng Kung University, Tainan, Taiwan, China
Wei-Kun Kuo
China Steel Corporation, Kaohsiung, Taiwan, China
Keywords: Knowledge-intensive service industries (KISI), Professional virtual community, Knowledge management,
Empirical knowledge.
Abstract: With the advent of service-oriented knowledge economy in the 21st century, knowledge-intensive service
industries (KISI) have become a trend nowadays for industrial development. In knowledge-intensive service
industries, enterprise activities have highly creativeness. By performing and achieving each enterprise
activity, the domain professional knowledge and experiences involving various ideas such as service
innovation or service value-added are employed. Therefore, it is most urgent task for implementing
knowledge management effectively, to quickly accumulate knowledge assets of enterprise and increase the
efficiency of knowledge-intensive service industries. Professional virtual community is an interactive
platform for enterprise experts to mutual creating and sharing empirical knowledge in knowledge-intensive
service industries. The platform has recorded high-volume rubbish information and empirical knowledge
during the expert discussion. Therefore, how to manage and share these useful contents of knowledge
discussion has become an important issue for empirical knowledge management in professional virtual
community. This study presents a systematic approach to developing a framework for empirical knowledge
management to support professional virtual community in knowledge-intensive service industries. The
approach presented in this study comprises three phases: (i) proposing an empirical knowledge management
model for professional virtual community, (ii) designing an empirical knowledge management system
framework for professional virtual community, and (iii) implementing an empirical knowledge management
system prototype for professional virtual community. Results of this study facilitate efforts within the
professional virtual community to extract, verify, store, and share empirical knowledge in order to
effectively assist knowledge-intensive service industries enhancing service innovative abilities and creating
the best services for customers' requirements.
1 INTRODUCTION
With the advent of service-oriented knowledge
economy in the 21st century, knowledge has become
an important source for an enterprise to promote its
competition advantage while service is a critical
value for enterprises to push the economic growth.
Thus, knowledge-intensive service industries (KISI)
have become a trend nowadays for industrial
development (Bryson and Rusten, 2005; Chen
2009).
Enterprise activities have highly creativeness in
5
Chen Y., Wu M. and Kuo W..
DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE MANAGEMENT FRAMEWORK FOR PROFESSIONAL VIRTUAL COMMUNITY IN KNOWLEDGE-
INTENSIVE SERVICE INDUSTRIES.
DOI: 10.5220/0003430200050014
In Proceedings of the 13th International Conference on Enterprise Information Systems (ICEIS-2011), pages 5-14
ISBN: 978-989-8425-55-3
Copyright
c
2011 SCITEPRESS (Science and Technology Publications, Lda.)
knowledge-intensive service industries. By
performing and accomplishing each enterprise
activity, the domain professional knowledge and
experiences involving various ideas such as service
innovation or service value-added are used.
Therefore, it is most urgent task for implementing
knowledge management effectively, to rapidly
accumulate knowledge assets of enterprise and
enhance the efficiency of knowledge-intensive
service industries.
Enterprise knowledge management can be
implemented as either a systematization strategy or a
personalization strategy (Hansen, Nohria, and
Tierney, 1999; Nonaka and Takeuchi 1995).
Systematization strategy is to manage explicit
knowledge and enhance the spread and distribution
of explicit knowledge through information systems.
Personalization strategy allows an expert to share
other experts’ own tacit knowledge (empirical
knowledge) by cooperating and communicating with
those experts. Meanwhile, tacit knowledge
symbolizes the value of an enterprise and is
generally hidden inside of personal mental models.
The inability to transfer tacit knowledge to
organizational knowledge (explicit knowledge)
would cause it to be disappeared while knowledge
workers leave their posts, ultimately losing
important intellectual assets for enterprises.
Professional virtual community is an interactive
platform for enterprise experts to mutual creating
and sharing empirical knowledge in knowledge-
intensive service industries (Pan and Leidner, 2003;
Wenger 1998). The platform has recorded high-
volume rubbish information and empirical
knowledge during the expert discussion. Therefore,
how to manage and share these useful contents of
knowledge discussion has become an important
issue for empirical knowledge management in
professional virtual community.
In recent years, the proposed researches for
virtual community are increasingly (Lin and Hsueh,
2006, Chang et al., 2008, Li and Wu, 2010).
However, these recent studies focused mainly on
managing and searching for explicit knowledge from
documents and information in virtual community.
They still do not have a completed solution for
managing and sharing empirical knowledge from
professional knowledge and experiences. Therefore,
experts' empirical knowledge requirements in
professional virtual community can not be satisfied,
and furthermore can not create services that would
meet customer's satisfaction.
Hence, this study develops a framework for
empirical knowledge management to support
professional virtual community in knowledge-
intensive service industries and effectively assist
knowledge-intensive service industries enhancing
service innovative abilities. To accomplish this
objective, the following tasks are performed: (i)
propose an empirical knowledge management model
for professional virtual community, (ii) design an
empirical knowledge management system
framework for professional virtual community, and
(iii) implement an empirical knowledge management
system prototype for professional virtual
community.
2 DESIGN OF EMPIRICAL
KNOWLEDGE MANAGEMENT
MODEL FOR PROFESSIONAL
VIRTUAL COMMUNITY
This section first defines the knowledge-intensive
service industry and analyzes its characteristics.
Then, empirical knowledge for professional virtual
community in knowledge-intensive service
industries is modeled. Based on the modeled
empirical knowledge, an empirical knowledge
management model is finally designed to pave the
way for system framework design.
2.1 Definition and Characteristics
Analysis for KISI
Knowledge-intensive service industries (KISI) are a
service value chain of higher knowledge contents,
which have been established by utilizing cooperation
modes as well as by combining sources from
science, engineering and academia. Knowledge-
intensive service industries use innovative
operational modes and technology application
techniques to pursue the innovations of product,
brand management, operation mode and service
through conducting technologies, internet,
professional knowledge, and services. Knowledge-
intensive service industries involve business
services, communication services, financial services,
educational services, legal consultation services,
distribution services, and health services.
Based on the definition of knowledge-intensive
service industry, it has the following characteristics:
(1) Knowledge-oriented: In knowledge-intensive
service industries, the performance and
accomplishment of each enterprise activity must
highly rely on the utilization of domain knowledge
and experience to ensure that their business models
ICEIS 2011 - 13th International Conference on Enterprise Information Systems
6
would normally be operated. Finally, the customers’
satisfaction and the enterprise market
competitiveness are increased.
(2) Knowledge expertise: Knowledge-intensive
service industries are a service value chain of higher
knowledge contents. The establishment and supply
of these professional services are mostly based on
professional knowledge. Therefore, the knowledge
expertise must be checked in collecting knowledge
to create quality services for customers’
requirements.
(3) Knowledge innovation: Service innovation is the
goal for knowledge-intensive service industries. To
provide better services to customers, enterprises
generally promote their service innovative abilities
by knowledge innovation that relies on the exchange
and communication of empirical knowledge.
(4) Knowledge value-added: Collaboration is one of
the important strategies of increasing competitive
advantage for knowledge-intensive service
industries. Thus, the scope of knowledge
requirement has been extended from the “point”
mode in the past into the “plane” mode nowadays so
that more completed knowledge value-added
services can be provided to customers.
2.2 Empirical Knowledge Modeling for
Professional Virtual Community
Empirical knowledge in a professional virtual
community can be exchanged and shared effectively
through interaction among experts, and it involves
extensive knowledge range. Thus, the empirical
knowledge exchanged and shared among experts in
a professional virtual community is modeled, as
shown in Fig. 1. In understanding the empirical
knowledge, experts first focus on the discussion
topic for exchanging and sharing empirical
knowledge. Then, the definition, purpose, and
implementation steps for the topic are shared and
understood respectively. Meanwhile, experts can use
the function of document search in virtual
community to search for and refer to other related
definitions, purposes, and implementation steps for
the topic. From these reference documents, related
discussion topics can be identified. Moreover, the
published dates and publishers would be referred
while experts understand the topic definitions.
Figure 1: Empirical knowledge model for professional
virtual community.
2.3 Empirical Knowledge Management
Model Design for Professional
Virtual Community
Based on the above characteristics of knowledge-
intensive service industries and the empirical
knowledge model for professional virtual
community, the empirical knowledge management
model for professional virtual community is
designed. As shown in Fig. 2, the business model of
knowledge-intensive service industry must be
performed and achieved by knowledge workers
using empirical knowledge to satisfy customer
groups from different service activities. However, to
enhance customers’ satisfaction degree effectively,
knowledge workers generally use the professional
virtual community to mutually create and share each
other’s empirical knowledge to promote themselves
knowledge innovative abilities and create quality
services that meet customers’ satisfaction. In the
professional virtual community, knowledge
discussion contents during the expert discussion are
important sources for accumulating an enterprise’s
empirical knowledge. This precious empirical
knowledge can be managed and reused effectively
through knowledge extraction, verification, storage,
reasoning, adaptation, and expert recommendation
and consultation in order to achieve the goal of
DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE MANAGEMENT FRAMEWORK FOR PROFESSIONAL
VIRTUAL COMMUNITY IN KNOWLEDGE-INTENSIVE SERVICE INDUSTRIES
7
service innovation for knowledge-intensive service
industries.
Empirical Knowledge Management for
Professional Virtual Community
Knowledge-Intensive Service Industry (Site A)
Knowledge
Workers
Service
Activity
Service
Activity
Service
Activity
Customers
Customer
Requirements
Knowledge-Oriented
Business Model
Customers
Customers
Knowledge
Flow
Knowledge
Flow
Knowledge-Intensive Service Industry (Site N)
Knowledge
Workers
Service
Activity
Service
Activity
Service
Activity
Customers
Customer
Requirements
Customers
Customers
Knowledge
Flow
Knowledge
Flow
‧‧‧
Professional
Virtual
Community
Professional
Virtual
Community
Knowledge-Oriented
Business Model
Knowledge
Discussion Contents
Empirical
Knowledge
Extraction
Empirical
Knowledge
Verification
Empirical
Knowledge
Types
Knowledge
Workers
(Experts)
Expert
Recommendation
and Consultation
Empirical
Knowledge
Storage
Knowledge Innovation
by Empirical Knowledge Sharing
INTERNET
/INTRANT
Knowledge-Intensive
Service Industry (Site F)
Experts
Service
Innovation
Service
Innovation
Empirical
Knowledge
Reasoning and
Representation
Knowledge
Workers
Empirical
Knowledge
Adaptation
Know-
What
Know-
Why
Know-
How
Know-
When
Know-
Where
Know-
Who
Know-
With
Figure 2: Empirical knowledge management model for
professional virtual community.
3 DESIGN OF EMPIRICAL
KNOWLEDGE MANAGEMENT
SYSTEM FRAMEWORK FOR
PROFESSIONAL VIRTUAL
COMMUNITY
To effectively support the characteristics of
knowledge-intensive service industries and the
empirical knowledge management model for
professional virtual community as well as manage
the identified empirical knowledge from
professional virtual community in Section 2, this
section first analyzes the functional requirements for
empirical knowledge management system. Based on
these functional requirements, the agent-based
empirical knowledge management system
framework is then designed by utilizing software
agent technology.
3.1 Functional Requirements Analysis
The aim of empirical knowledge management
system is two-fold: (i) to manage the empirical
knowledge from each service activity in knowledge-
intensive service industries and (ii) to share the
empirical knowledge based on the knowledge
workers’ knowledge requirements, in order to
facilitate the knowledge innovation and the service
innovation in knowledge-intensive service
industries.
To accomplish the system objective above, the
functional requirements analysis is performed
through two phases of “system environment
management functions” and “system use functions”.
They are discussed follows.
(1) System environment management functions
(i) Service process configuration management:
Service process in knowledge-intensive service
industries is a mutual-participation process with
one leading enterprise and several allied
enterprises according to different service
requirements. Thus, the leading enterprise must
be able to perform service process
reconfiguration and system reconfiguration for
allied enterprises which are comprised with
different service requirements.
(ii) Distributed management: Distributed
collaboration has become one of the important
strategies for knowledge-intensive service
industries to enhance their competitive
advantage. To effectively support the distributed
collaborative environment, the abilities of remote
control, coordination, and communication should
be provided in exchanging and communicating
empirical knowledge.
(iii) Empirical knowledge maintenance: To
supply correct empirical knowledge to suitable
knowledge workers at right time, the system
must periodically maintain empirical knowledge
to ensure the correctness and completeness of
empirical knowledge.
(iv) Knowledge access control: Service
innovation in knowledge-intensive service
industries depends on the innovation of domain
knowledge, while the innovation of domain
knowledge thus relies on managing and sharing
knowledge. To assist knowledge workers in
sharing correct empirical knowledge at the right
time and place, the system needs to set different
knowledge access authorizations according to
different users’ authorities in order to protect the
confidentiality of empirical knowledge in sharing
empirical knowledge.
(2) System use functions
(i) Knowledge worker registration: Knowledge
workers are important sources of empirical
knowledge. Hence, knowledge workers must
perform the knowledge registration before they
enter into a professional virtual community and
post knowledge discussion contents. The way
can facilitate the expert recommendation for em-
ICEIS 2011 - 13th International Conference on Enterprise Information Systems
8
pirical knowledge sharing.
(ii) Expert withdrawal: Service process in a
knowledge-intensive service industry is dynamic.
Experts in allied enterprises can flexibly choose
to join or withdraw from the collaborative
environment. In this situation, the function of
expert withdrawal must be considered to ensure
the time effectiveness of empirical knowledge
sharing.
(iii) Empirical knowledge extraction: In the
expert discussion in professional virtual
community, high-volume and precious empirical
knowledge hidden behind the knowledge
discussion contents should be effectively
extracted to be managed and shared.
(iv) Empirical knowledge verification:
According to the extracted empirical knowledge,
the logics of empirical knowledge should be
verified effectively before archiving such
valuable empirical knowledge into an enterprise
knowledge repository to ensure the correctness
of empirical knowledge and provide knowledge
workers with reliable knowledge decision
support.
(v) Empirical knowledge storage: After
verifying the empirical knowledge, it can be
represented by a structured knowledge
representation method and stored into an
enterprise knowledge repository for later reuse.
(vi) Empirical knowledge reasoning: To satisfy
knowledge workers’ empirical knowledge
requirements, knowledge workers can describe
and inquire the encountered problems in the
topic discussion to match and obtain related
empirical knowledge and solutions by using the
knowledge reasoning.
(vii) Empirical knowledge adaptation:
According to knowledge workers’ past usage
behaviors, the suitable empirical knowledge
ontology can be adapted to satisfy every
knowledge worker’s knowledge requirements,
and ultimately to enhance the reuse value of
knowledge.
(viii) Expert recommendation: Based on
knowledge workers’ knowledge requirements,
they can search for appropriate experts from the
enterprise knowledge repository for knowledge
consultation to increase the sharing effect of
empirical knowledge.
(ix) Empirical knowledge communication: As
recommended appropriate experts, knowledge
workers can consult and communicate the
empirical knowledge with these experts through
online video conference systems such as
VidiNOW, Co-Life, and NetMeeting.
3.2 Agent-based Empirical Knowledge
Management System Framework
Design
According to the system functional requirements
analyzed in Subsection 3.1, this section adopts the
concept of software agent technology (Danesh and
Jin 2001, Luck, Ashri, and D'Inverno, 2004) to
design an agent-based empirical knowledge
management system framework. As shown in Fig. 3,
the system environment management functions
include agents of system management, service
process, collaborative activity, empirical knowledge
maintenance, and knowledge access. Meanwhile,
each collaborative activity agent can collaboratively
perform and complete a service activity by one or
more personal knowledge management agents.
Through the empirical knowledge management
agent, each personal knowledge management agent
can use system use functions including knowledge
extraction agent, knowledge verification agent,
knowledge storage agent, and expert
recommendation agent to extract, verify, and store
empirical knowledge as well as recommend experts.
Based on the recommended experts, knowledge
workers can actually consult and communicate
empirical knowledge with these experts through the
knowledge communication agent. Furthermore, each
personal knowledge management agent can reason
and retrieve empirical knowledge through the
knowledge access agent and the empirical
knowledge reasoning agent. In reasoning and
retrieving the empirical knowledge, the empirical
knowledge adaptation agent can adapt a suitable
empirical knowledge ontology according to
knowledge workers’ use behaviors so that the
reasoned and retrieved empirical knowledge would
be better to satisfy knowledge workers’ knowledge
requirements. Finally, the knowledge worker
registration and withdrawal agent is provided to
register or withdraw an expert for sharing empirical
knowledge.
4 MODELING OF EMPIRICAL
KNOWLEDGE MANAGEMENT
SYSTEM
System modeling defines system-level details in
terms of a set of models.
DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE MANAGEMENT FRAMEWORK FOR PROFESSIONAL
VIRTUAL COMMUNITY IN KNOWLEDGE-INTENSIVE SERVICE INDUSTRIES
9
Figure 3: The agent-based empirical knowledge
management system framework.
Two rationales are applied to system modeling.
First, to fully embrace and comply with industry
standard object models and architectures to enable
the interoperability with other empirical knowledge
management modules and a wide variety of other
software systems. Second, to employ industry best-
practice modeling techniques in a proposed
development process to facilitate the management of
system complexity.
As Unified Modeling Language (UML) (Booch,
Rumbaugh, and Jacobson, 1999; Jacobson,
Christerson, Jonsson, and Overgaard, 1992) has
emerged as the notational standard for object-
oriented modeling and is relatively comprehensive,
UML was utilized during the system modeling
phase. Using standard modeling techniques may
standardize and facilitate the development process
(Rational Unified Process, RUP) by using common
concepts, notations and supporting tools, and
consequently increase system compatibility with
other software systems.
System modeling can be classified into dynamic
aspect and static aspect. Meanwhile, the dynamic
aspect mainly describes system behavior (i.e.,
behavioral diagrams) which includes use case
diagram and sequence diagram. The static aspect
represents system structure (i.e. structural diagrams)
which includes class diagram and deployment
diagram. They are described below.
4.1 Behavioural Diagrams (Dynamic
Aspect)
4.1.1 Use Case Diagram
Use case diagram mainly describes the interactive
behavior between actor and system. Figure 4
presents the use case diagram of empirical
knowledge management system.
Figure 4: Use case diagram for empirical knowledge
management system.
4.1.2 Sequence Diagram
Sequence diagram describes the dynamic behaviors
of message transmission among objects in a system.
Figures 5 and 6 depict the sequence diagrams of
empirical knowledge reasoning and verification,
respectively.
Figure 5: Sequence diagram for the “Empirical
Knowledge Reasoning”.
ICEIS 2011 - 13th International Conference on Enterprise Information Systems
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Figure 6: Sequence diagram for the “Empirical
Knowledge Verification”.
4.2 Structural Diagrams (Static Aspect)
4.2.1 Class Diagram
Class diagram presents the types of classes in a
system and the static relationships between classes.
Figure 7 shows the class diagram of empirical
knowledge management system.
Figure 7: Class diagram for empirical knowledge
management system.
4.2.2 Deployment Diagram
Deployment diagram represents the static structural
relationship between hard/software components in a
system and explains the details of its establishment.
As shown in Fig. 8, it displays the deployment
diagram of empirical knowledge management
system.
5 SYSTEM IMPLEMENTATION
According to the above results of system framework
design and system modeling, a prototype was
implemented to demonstrate the proposed empirical
knowledge management system for professional
virtual community. The implementation
environment and implementation results with an
illustrative example were explained below.
Figure 8: Deployment diagram for empirical knowledge
management system.
5.1 Implementation Environment
The implementation environment of this empirical
knowledge management system prototype for
professional virtual community was as follows:
‧PCs: Two Intel Pentium4-2.8G PCs.
‧Operation systems: MS Windows XP Professional
with Service Pack 3 and Linux Red Hat 9.0.
‧Web server: Tomcat 5.5 (Apache).
‧Web pages and core components: The Java Serve
Pages (JSP) programming language and Java Agent
Development Framework (JADE) were utilized to
build the web pages and work on agent
development.
‧Databases: My SQL 5.1.41 and Xindice XML
database.
‧Knowledge reasoning tools: Protégé 3.4.4 and
Pellet 1.5.2.
5.2 Implementation Results with a
Stock Investment Example
Based on the results of system modeling in Section
4, this section utilizes an example of stock
investment to explain the implementation of
functions of empirical knowledge verification and
DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE MANAGEMENT FRAMEWORK FOR PROFESSIONAL
VIRTUAL COMMUNITY IN KNOWLEDGE-INTENSIVE SERVICE INDUSTRIES
11
reasoning.
Empirical Knowledge Verification: Figure 9
presents an empirical knowledge structure of stock
investment that has not yet been verified.
Meanwhile, the knowledge concepts “Share Issue”
and “Commercial Paper” are the sub-concepts of the
knowledge concept “Stock Exchange Market”, while
the knowledge concept “Government Bond” is the
sub-concept of the knowledge concept “OTC
Market”. By performing the knowledge verification,
the logic errors in the knowledge structure are
detected. Thus, the knowledge concept “Share
Issue” is modified as a sub-concept of the
knowledge concept “Corporate Bond” as well as the
knowledge concepts “Commercial Paper” and
“Government Bond” are modified as sub-concepts
of the knowledge concept “Stock”, as shown in Fig.
10. Figure 11 shows the OWL-based stock
investment knowledge representation before
verification and Fig. 12 shows the OWL-based stock
investment knowledge representation after
verification.
Figure 9: Stock investment knowledge before verification
(conceptual model).
Figure 10: Stock investment knowledge after verification
(conceptual model).
Table 1: The empirical knowledge reasoning rule.
OWL
Reasoning
Syntax
(?P rdf:type owl:TransitiveProperty)^
(?A ?P ?B)^(?B ?P ?C)→(?A ?P ?C)
Empirical
Knowledge
Reasoning
Result
(?Is_a rdf:type owl:TransitiveProperty)^
(?Stock ?Is_a ?Corporate Bond)^
(?Corporate Bond ?Is_a ?Ordinary Stock)→(?Stock ?Is_a
?Ordinary Stock)
NOTE: Parameter P denotes the transitive property. Parameters A,
B, and C represent the concept names of empirical knowledge.
Symbol “^” indicates the logical operator AND.
Figure 11: OWL-based stock investment knowledge
representation before verification.
Figure 12: OWL-based stock investment knowledge
representation after verification.
ICEIS 2011 - 13th International Conference on Enterprise Information Systems
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Empirical Knowledge Reasoning: Figure 13
displays a stock investment ontology constructed by
the ontology editor Protégé. According to the
defined reasoning rule in Table 1, the relationship
“Is_a” between knowledge concepts “Stock” and
“Ordinary Stock” can be reasoned, as shown in Fig.
14.
Figure 13: Stock investment knowledge before the rule
reasoning in Protégé.
Figure 14: Stock investment knowledge after the rule
reasoning in Protégé.
6 CONCLUSIONS AND FUTURE
WORKS
This study first defined the knowledge-intensive
service industry and analyzed its characteristics.
Then, the empirical knowledge from professional
virtual community was identified and modeled.
According to the definition, characteristics, and
empirical knowledge of knowledge-intensive service
industry, the empirical knowledge management
model for professional virtual community was
designed. Moreover, the software agent technology
was adopted to design the agent-based empirical
knowledge management system framework. Finally,
the empirical knowledge management system and
core techniques were implemented using UML
modeling techniques, object-oriented programming
language, and JADE. The primary results and
contributions of this study are summarized as
follows:
(1) Empirical knowledge management model for
professional virtual community: This study proposed
an empirical knowledge management model for
professional virtual community, which can be an
important reference model for implementing the
empirical knowledge management in other learning
organizations.
(2) Agent-based empirical knowledge management
system framework and core techniques: The
developed system framework and core techniques
can effectively extract, verify, store, reason, and
adapt the empirical knowledge from knowledge
discussion contents in professional virtual
community, to assist enterprises in fulfilling the
empirical knowledge management.
Results of this study facilitate the realization of
empirical knowledge management for knowledge-
intensive service industries to satisfy experts’
empirical knowledge requirements, and thus
promote service innovative capabilities, and
ultimately increase customers’ satisfaction as well as
enhance industrial competitiveness.
For the proposed core techniques in this study,
the following future research issues are
recommended: (i) In the process of empirical
knowledge verification, the knowledge structure is
validated and modified by experts. Thus, an artificial
intelligent-based method for automatic validation
and modification should be considered, and (ii)
Empirical knowledge is associated with situation
property. Situated empirical knowledge can
comprise basic elements such as spatial relation and
temporal relation. Therefore, future studies should
consider the situation property of empirical
knowledge to develop a method of situated empirical
knowledge representation and reasoning in order to
deduce a more suitable empirical knowledge that
would satisfy the requirements from a knowledge
requester under certain circumstances.
DEVELOPMENT OF AN EMPIRICAL KNOWLEDGE MANAGEMENT FRAMEWORK FOR PROFESSIONAL
VIRTUAL COMMUNITY IN KNOWLEDGE-INTENSIVE SERVICE INDUSTRIES
13
ACKNOWLEDGEMENTS
The authors would like to thank the National
Science Council of the Republic of China, Taiwan,
for financially supporting this research under
Contract Nos. NSC98-2221-E-327-039 and NSC99-
2221-E-327-036.
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