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A framework for modelling enterprisecompetencies: from theory to practice inenterprise architecture
Reza Vatankhah Barenji, Majid Hashemipour & David A. Guerra-Zubiaga
To cite this article: Reza Vatankhah Barenji, Majid Hashemipour & David A. Guerra-Zubiaga
(2015) A framework for modelling enterprise competencies: from theory to practice inenterprise architecture, International Journal of Computer Integrated Manufacturing, 28:8,
791-810, DOI: 10.1080/0951192X.2014.901563
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A framework for modelling enterprise competencies: from theory to practice
in enterprise architectureReza Vatankhah Barenji
a *, Majid Hashemipour
a and David A. Guerra-Zubiaga
b
a Department of Mechanical Engineering EMU, Eastern Mediterranean University, Mersin, Turkey;
bCIDESI, Texas A&M University,
College Station, CO, USA
( Received 6 October 2012; accepted 3 March 2014)
Enterprise competency refers to knowledge that describes the skills and abilities possessed by a particular enterprise. This paper proposes a new framework for intra-enterprise competency modelling. First, formal denitions of enterprisecompetency and related aspects (i.e. resource, activity, and knowledge) are presented. Second, conceptual subcategories(i.e. capability, cross-functional co-ordination, and cross-functional integration) are discussed for the purposes of capabilityand competency modelling. The framework is illustrated by developing a competency knowledge base for a bicycle plant with two sectors. The competency knowledge base provides information important to decision-making, and can act as anindicator for an enterprise’s willingness to engage in robust collaboration.
Keywords: capability concept; competency modeling; competency management; enterprise modeling; enterprise engineering
1. Introduction
Nowadays, enterprises use comprehensive assemblage knowl-
edge to meet customers’ requirements and offer competitive
prices for their products or services (Paiva, Roth, and
Fensterseifer 2002; Baxter et al. 2009). An enterprise seeks to
preserve, manage, maintain, transfer, and enhance their knowl-
edge to improve their decision-making processes and obtain
competitive advantages (Chen, Doumeingts, and Vernadat
2008; Weston 2013). Among industrial practitioners, there is
an increasing interest in capitalising on both theoretical and
practical enterprise knowledge (Usman et al. 2013).
Knowledge capitalisation is the process of reusing previously
stored and modelled knowledge of a given domain as a means
to performnew tasks (Guerra-Zubiagaand Young2008b). The
purpose of capitalisation is to locate and illuminate enterprise
knowledge, maintain, access, and actualise it, understand how
to better use and diffuse it, and to synergise and valorise it
(Cantú et al. 2009; Gunasekaran and Ngai 2007).
Within the literature, enterprise models and ontologies
have continuously been used to capitalise knowledge in an
explicit and structured manner (Molina et al. 2007;
Vernadat 2002). The goal of the enterprise model is to
dene the semantics associated with enterprise knowledgein an easy-to-understand way (Vernadat 2007). Ultimately,
the primary objectives of enterprise ontology are to
create easy-to-understand denitions of the enterprise’s
(Vernadat 2010, 2007; Tarasov, Sandkuhl, and Henoch
2006): (a) business entities and relationships; (b) processes
and planning; (c) organisational structure; (d) market
details and products/services; and (e) high-level planning
and preferences. The articial intelligence and enterprise
modelling communities have developed important enter-
prise models and/or ontologies, including the Toronto
Virtual Enterprise (TOVE), the Open Information
Model (OIM), Computer Integrated Manufacturing Open
System Architecture (CIMOSA), ISTI Distributed Enterprise
Ontology, Business Process Modelling Language (BPML),
and Collaborative Network Organisation (CNO). A
detailed review of these ontologies and other relevant enter-
prise ontologies and modelling frameworks is provided in
reference Abdmouleh, Spadoni, and Vernadat (2004).
In addition to the enterprise model, it is important to
capture and manage the knowledge and skills of enterprises’
internal competencies (Ljungquist 2008). Enterprise
Competency is a crucial factor in business scenarios, in that it
provides a more nuanced description of an enterprise’s
(Ljungquist 2007; Javidan 1998) or individual’s (Harzallah
and Vernadat 2002) prole. Such a prole demonstrates the
knowledge, skills, experience, and attributes necessary to
effectively implement a dened function (Berio, and
Vernadat 2006; Harzallah and Vernadat 2002; Harzallah).
That Competency is an essential component of enterpriseengineering, acting as a new means to consider knowledge
capitalisation (Huat Lim, Juster, and de Pennington 1997),
associated with a new vision of performance (Trejo et al.
2002; Capece and Bazzica 2013), as well as new forms of
ontology (Khilwani, Harding, and Tiwari 2011; Barenji,
Hashemipour, and Guerra-Zubiaga 2013a). First, the
*Corresponding author. Email: [email protected] This article was originally published with errors. This version has been corrected. Please see Erratum (http://dx.doi.org/10.1080/ 0951192X.2014.928113)
International Journal of Computer Integrated Manufacturing , 2015
Vol. 28, No. 8, 791 – 810, http://dx.doi.org/10.1080/0951192X.2014.901563
© 2014 Taylor & Francis
http://dx.doi.org/10.1080/0951192X.2014.928113http://dx.doi.org/10.1080/0951192X.2014.928113http://dx.doi.org/10.1080/0951192X.2014.928113http://dx.doi.org/10.1080/0951192X.2014.928113
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understanding and auditing of competencies acquired,
required, and desired by a company and second, representing
them in a structured manner are benecial steps for enhancing
the company’s performance (Jussupova-Mariethoz and Probst
2007; Chungoora et al. 2013).
Researchers have explored the importance of enter-
prise Competency in several ways: by suggesting coreCompetency models to sustain competitive advantage
(Draganidis, Chamopoulou, and Mentzas 2006;
Ljungquist 2008), by building on the concept ’s basic
tenets to invent similar concepts (Pareto and Snis 2007,
September ; Ljungquist 2008), and by developing pro-
cesses for its identication and management (Javidan
1998; Ljungquist 2007). One body of existing work
focuses on ways to empirically model competencies
using company task forces and resources, as well as cap-
ability concepts as part of the identication and manage-
ment process (Kristianto, Helo, and Takala 2011;
Rahimifard and Weston 2009).
Ermilova and Afsarmanesh (2010) recognise threelevels of abstraction for Competency modelling: (1)
intra-enterprise, (2) inter-enterprise, and (3) network. The
major motivation for enterprise competency modelling is
at network level (i.e. Collaboration Networks (CNs))
(Cheikhrouhou, Tawil, and Choudhary 2013). In the crea-
tion phase of a network, it is vital to have a robust
enterprise knowledge base embedded with partners’ com-
petencies. Most competency modelling purposes are typi-
cally considered at these three levels (Khilwani, Harding,
and Choudhary 2009).
Because only a few experiential studies exist on the
topic, it has recently been suggested that there is a lack of
knowledge about enterprise internal Competency model-ling (Macris, Papadimitriou, and Vassilacopoulos 2008;
Cantú et al. 2009). In small size enterprises, enterprise
competencies’ modelling is typically based on oral infor-
mation and general applications. In more complex enter-
prises, however, Competency modelling on a human basis
is not any more effective (Chungoora, Canciglieri, and
Young 2010).
Extant research has been valuable for clarifying
Competency, effective Competency management practices
(Molina et al. 2007; Panetto and Molina 2008) and the
ways in which enterprise competencies can be identied
(Harzallah and Vernadat 2002; Javidan 1998; Zoiopoulos,
Morris, and Smyth 2008). However, one shortcomings of
the literature is the lack of clear empirical denitions
for associated concepts (e.g. resource, capability)
(Ljungquist 2008). In addition, a signicant contribution
is made for competency modelling and management at
concept and/or basic levels, and there has been a small
number of contributions to enterprise competency model-
ling at tangible detail level (Pertusa-Ortega, Molina-
Azorín, and Claver-Cortés 2010; Pépiot et al. 2007).
Moreover, there has been a substantial amount of research
within managerial sciences and industrial engineering
(Barenji and Hashemipour 2014; Cui and Weston 2012)
related to enterprise competency modelling and manage-
ment, but few of these efforts have considered enterprise
competency from an enterprise information technology
perspective. Instead, research within these domains has
largely focused on manufacturing companies. From this brief state of the art, a major need appears that is not only
clarifying competency related ‘associated concepts’ but
also detail modelling of enterprise competency from IT
points of view.
A framework has been developed to model intra-
enterprise competency to provide important decision-mak-
ing information for the people with moderate knowledge
on enterprise engineering. It can be derived and adapted to
every enterprise’s need. This framework was applied to a
bicycle plant with two sectors. To do this, we rst analyse
the concept of competency and its aspects (i.e. resource,
activity, and knowledge). Next, intra-enterprise compe-
tency modelling subcategories (i.e. capability, cross-func-tional co-ordination (CFC), and cross-functional
integration (CFI)) are presented in terms of its entities
and relationships. Then, we discuss the necessary steps
for operationalising this framework through a case study.
Finally, we present a relational knowledge base model of
the case study and its various functionalities and offer
some concluding remarks.
2. Enterprise competency: concept and trends
Enterprise competency is an important paradigm for obtain-
ing competitive advantages and leverage by using a ‘know-
how’ approach (Tarasov 2012). It refers to the skills andabilities of an organisation needed to carry out certain tasks
based on knowledge and experience of its methods and
resources (Pépiot et al. 2007). Understanding and sharing
competencies improves rm performance in a number of
respects (Cuenca, Ortiz, and Vernadat 2006; Huat Lim,
Juster, and de Pennington 1997; Barenji et al. 2012;
Jardim-Goncalves, Agostinho, and Steiger-Garcao 2012):
(a) attracting, retaining, and improving the best available
resources for creating and realising continuous value crea-
tion and distribution; (b) publishing the competency of
one’s own rm in the market and identifying potential
opportunities for co-operation; (c) increasing awareness
about one’s own current capabilities as well as understand-
ing competencies that other companies can offer (thereby
allowing for the identication of areas for future develop-
ment); and (d) initiating or mediating new partnerships.
In earlier denitions and models, competency primar-
ily refers to capabilities. As a result, ‘competency’ and
‘capability’ are often considered synonymous. For exam-
ple, Gallon, Stillman, and Coates (1995, 24) dene com-
petency as ‘aggregation of capabilities, where synergy that
is created has sustainable value and broad applicability’.
792 R.V. Barenji et al.
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Javidan (1998) proposed a different denition to supple-
ment the conceptualisation proposed by Gallon and
Stillman. While the traditional denition did not account
for an enterprise’s multi-functionality, the denition pro-
posed by Javidan is based on an enterprise’s functions
(e.g. manufacturing and marketing sectors). He concep-
tually distinguished the associated concepts in a ‘
compe-tencies hierarchy’. The hierarchy treats resources as the
foundation. Capabilities are modelled such that they are
built upon resources. Finally, competencies are built upon
resources and capabilities.
Attempts at modelling enterprise competency are typi-
cally carried out within two distinct research communities
(Berio and Harzallah 2005): (a) managerial sciences and
industrial engineering and (b) information/knowledge man-
agerial sciences. The focus on intra-enterprise competency
modelling gives rise to the question of how internal com-
petencies of an enterprise can be identied, captured, and
modelled in a manner identiable by human and machine,
allowing an enterprise to successfully engage global com- petition and endure uctuating market conditions. There
has been a substantial amount of research within manage-
rial sciences and industrial engineering (Abel 2008; Bodea
et al. 2010; Ermilova and Afsarmanesh 2010) related to
enterprise competency modelling and management, but
few of these efforts have considered enterprise competency
from an enterprise information technology perspective
(Berio and Harzallah 2005; Bernus and Schmidt 2006).
Instead, research within these domains has largely focused
on manufacturing capabilities. As a starting point for this,
Molina et al. (1995) propose a model for manufacturing
capability to support concurrent engineering. The authors
introduced manufacturing capability as combination of
processes, resources, and strategies in a specic work ow.
Further, they believe that manufacturing capability models
can be used to support concurrent engineering. A number
of researchers have applied Molina and Bell’s manufactur-
ing capability model to create knowledge base. Most nota- bly Zhao, Cheung, and Young (1999) proposed a model to
support virtual enterprises. Liu and Young (2004) utilise
information and knowledge models to support global man-
ufacturing co-ordination decisions. Further, Guerra-
Zubiaga and Young (2008a) developed a manufacturing
knowledge model to facilitate decision-making. Further
research work on manufacturing capability and decision
support systems focuses on contexts can be found at
Kandjani and Bernus (2011), Kim et al. (2013), Macris
et al. (2009), Rajpathak and Chougule (2011), Barenji
(2013), and Barenji, Barenji, and Hashemipour (2014).
To summarise, (1) resource, activity, and manufacturing
strategy are three fundamental components for capabilitymodelling, (2) extant research has mapped manufacturing
strategy as knowledge related to processes and resources
(knowledge), and (3) capabilities are the building blocks of
the enterprise’s competencies.
In the context of a complex paradigm like competency,
modelling is fundamental for understanding, managing,
simulating, and predicting the attribute of the paradigm,
and especially for software development (Büyüközkan and
Arsenyan 2012; Scheuermann and Leukel 2013). Figure 1
illust rates some of the important questions that a modeller
may pose when attempting to model competency at the
Figure 1. Examples of modelling purposes.
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intra-enterprise level. Certainly, many other relevant ques-
tions may be asked in relation to competency modelling.
There are several models for enterprise competency
within the research communities outlined earlier. These
models, though related to each other, have different areas
of application. Therefore, the models themselves differ. For
the purpose of explication, Table 1 summarises the most oft-cited research for enterprise competency modelling.
3. Enterprise data infrastructure
An enterprise’s data infrastructure is a layered set of data
that provides a foundation for strategic initiatives such as
(a) outlining the business’s aims and objectives for
improved collection and use of data, (b) improving business
processes, (c) making decisions regarding the future of new
and changed systems, and (d) integrating, warehousing, and
reporting initiatives. An enterprise data infrastructure is not
fully represented by a set of detailed models of individual
systems, because the models cannot convey the macro-level
information required to meet the stated strategic initiatives.Additionally, top-level models cannot be used exclusively,
as they fail to include suf cient detail for answering impor-
tant questions. Instead, enterprise data infrastructure is
mapped as a generic tree structure to model existing enter-
prise data. To highlight enterprise competency, the infra-
structure proposed in this this paper is shown in Figure 2.
The infrastructure has been divided into four key tiers:
Table 1. Current competency.
Reference Research contribution Modelling area
Intra-enterprise (managerial sciences)
(Prahalad and Hamel 1990) Core competency notation Organisation competency, denition at concept level
(Javidan 1998) (Ljungquist 2007)
Core competency hierarchy Organisation competency, concept model
(Gilgeous and Parveen 2001,222)
‘To assist in core competence management an enablingcore competence lens model was presented together with a framework for core competence maintenance’
Enterprise competency, organisationcompetency, at detail level
(Bhamra, Dani, and Bhamra2011, 2738)
‘Investigating the existence and nature of corecompetency concepts within a section of UK SMEmanufacturing organizations’
Organisation competency, concept and basic level
Intra-enterprise (Information/knowledge managerial sciences)(Zhang and Lado 2001) Analyse IS role in raising organisational competencies
and prompting the CFI necessary to achieve scale,scope, and learning curve economies for an enterprise.
organisational competency at concept level
(Walsh and Linton 2001) Develop a framework for enterprise competencymodelling
Enterprise competency, organisationcompetency at concept level
(Harzallah and Vernadat 2002) Competency modelling and management Enterprise competency, and individualcompetency at basic level
Inter-enterprise (managerial sciences)((HR-XML 2001) Partner selection Sharing competency, at organisational
level
Inter-enterprise (Information/knowledge managerial sciences)(HR-XML 2001) Providing trading partners standardised and practical
means to exchange information about competencieswithin a variety of business contexts
Sharing competency, at organisationallevel
Network (managerial sciences)(Molina and Flores 1999) Core competencies in the manufacturing clusters Organisation competency at concept
level
Network (information/knowledge managerial sciences)(Müller 2006) Planning of production system for the competency cell-
based networksEnterprise competency, basic and detail
level(Paszkiewicz and Picard 2011) Partner selection in Virtual Organisation Breeding
EnvironmentsEnterprise competency modelling at
detail level(Cheikhrouhou, Tawil, and
Choudhary 2013, 2142)‘Extension of the competence-oriented modeling
approach through a unied enterprise competencemodeling language (UECML), based on enterprisearchitecture models, to virtual organizations’
Enterprise competency, modelling at basic level and detail level
(Ermilova and Afsarmanesh2010)
Competency modelling for collaborative network organisations
Organisation competency, basic anddetail level
794 R.V. Barenji et al.
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Enterprise General Information, Enterprise Workplace
Information, Enterprise-wide Technical Information, and
Manage Effectiveness Information. The infrastructure
representation begins with Enterprise General Information,
which captures basic information about the enterprise.Enterprise General Information contains four subclasses of
information, including enterprise name, enterprise story,
address(s), and key persons. The second tier, Enterprise
Workplace Information, is intended to capture the market
details of the enterprise. It includes information about the
sector (e.g. mining, farming, construction, and manufactur-
ing), the products/services offered by the enterprise, both
existing and target consumers, and commercial nancial
highlights (e.g. revenue, prot, income, and employees).
The third tier is Enterprise-wide Technical Information,
which is intended to capture an enterprise’s competencies.
Competencies consist of all assets, tangible and intangible,
human and non-human, that are possessed and controlled
by the company that permit it to devise and apply value-
enhancing strategies (Chen and Vernadat 2004). This tier
contains three subclasses, including processes, resources,
and knowledge related to process(es) and resource(s). The
Manage Effectiveness Information tier contains the infor-
mation that an enterprise publishes to draw the attention of
consumers and vendors for new business opportunities. The
subclasses included in this tier are: past projects, relation-
ships (e.g. relevant with other enterprises), and achieve-
ments (e.g. parents and standards). The focus of this paper
is on the third tier of this infrastructure.
4. Competency: subcategories and modelling aspects
Enterprise competency models are generally used for repre-
senting relevant business activities and products or services
offered by a company (Tripathi and Suri 2010). In this paper,
we use Javidan’s (1998, 261) enterprise competency deni-
tion to explore competencies ‘across functional co-ordina-
tion and integration of capabilities’. This denition includes
three broad subcategories: co-ordination, integration, and
capability. First, co-ordination, according to Barenji,
Hashemipour, and Guerra-Zubiaga (2013, 114), ‘is orderly
arrangement of activities to provide unity of action in the
pursuit of common goals within a sector ’. Second, integra-
tion is dened as ‘establishing mechanisms and links that
facilitate the needed integration of the activities of different
functions to ensure that these functions work together effec-tively to achieve the overall objectives of the enterprise’
(Peñaranda et al. 2010, 864). Finally, capability is dened
as a sector ’s capability represented by a set of information
that is embodied by all available resources and correspond-
ing activities that can be performed by those resources, as
well as the knowledge about how these resources and activ-
ities can be used effectively, ef ciently, and economically
(Guerra-Zubiaga and Young 2008a). The sector ’s capability
denition contains three aspects (Tripathi and Suri 2010) (i.e.
resource, activity, and knowledge):
● Resource: the building block of capabilities (Javidan
1998). Resources can be categorised into threegroups: physical resources (e.g. plant, equipment),
human resources (e.g. manpower, management
team, training, experiences), and organisational
resources (e.g. brand name). While resources are
tangible (e.g. equipment), others are intangible (e.g.
nancial resources) (Vichare et al. 2009).
● Activity: according to Camarinha-Matos (2001,
1014), ‘from a bottom-up perspective, activities
carried out by a company are usually organised in
“clust ers” of inter-related activities called processes
(business processes). The composition of each pro-
cess is designed in order to achieve a (partial)
specic goal’. Alternatively, from top-down view,a process can be decomposed into a hierarchy of
sub-process and activities.
● Strategies (Knowledge): decisions are made regard-
ing the use and organisation of resources and activ-
ities (e.g. constraints imposed on the use of a certain
type of resources and/or activates) (Kandjani and
Bernus 2013). In the capability model, knowledge
represents how resources and activities are struc-
tured and used to support the function to achieve
the objectives of a sector.
One major dif culty associated with modelling enterprise
competency is the ‘CFC’ and ‘CFI’ of the sectors’ capabil-
ities with varied backgrounds and priorities. For example,
in a manufacturing enterprise, capabilities of the design
sector often fall in the domain of striking aesthetics, the
manufacturing sector is drawn toward standardised designs,
the research and development (R&D) sector scientists are
drawn toward novel technological applications, and the
marketing sector seeks industry benchmarks and require-
ments for customer satisfaction. These different orientations
may generate priorities that are opposed to one another,
Figure 2. Enterprise data infrastructure.
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resulting in unco-operative behaviours for CFC and CFI of
the capabilities. Unsurprisingly, ‘CFC’ and ‘CFI’ in sectors’
capabilities have become a challenging concern for enter-
prise competency modelling. In particular, there are two
important issues for enterprise competency modelling.
First, what are the best methods for strengthening ‘CFC’
in sector ’s capabilities? Second, what are the best strategies
for strengthening ‘CFI’ in sectors’ capabilities within the
enterprise? Figure 3 illustrates an enterprise competency
model in terms of sectors’
capabilities, ‘
CFC’
and ‘
CFI’.
As shown in this gure, from bottom to top, each sector
contains one or many capabilities origin from its divisions.
These capabilities are ingredients for ‘CFC’ process aiming
to generate a sector ’s capability. The ‘CFI’ process on the
sectors capabilities will result enterprise competency.
5. Proposed multi-level intra-enterprise competency
modelling framework
In this section, a multi-level framework is developed to
capture and model enterprise competency. This framework
is based on a set of aspects and subcategories required to
describe enterprise competency. For the sake of consis-
tency, we have named our framework the Multi-Level
Intra-Enterprise Competency Modelling Framework and
adopted the abbreviation MICMF for use throughout the
text. MICMF is based on three high-level concepts that
collectively represent an enterprise’s competency (see
Figure 4).
● Basic Integration and Co-operation (BIC) Level.
The BIC captures fundamental aspects information
regarding each sector ’s competency. The fundamen-
tal aspects of information for competency are
resource(s) information, activity(ies) information,
and knowledge related to resources and processes.
● Sector’s Capability Functionalities (SCF) Level.
SCF intended to model sector capability (SC) in
accordance with sector-specic goals. In other
words, the SCF level deals with modelling the cap-
abilities of sectors at division layers towards the
accomplishment of its assigned capabilities for intra-enterprise competency.
● Intra-Enterprise Competency Functionalities
(ICF) Level. ICF is intended to accomplish the
‘CFC’ and ‘CFI’ processes on sectors’ capabilities
in accordance to each sector-specic goal and the
enterprise global goal(s).
As shown in Figure 4, MICMF contains BIC, SCF, and
ICF levels. In MICMF, each level’s output is input for the
next level. These graphics are intended to represent a
sequence of level attainments, which begin at the bottom
level and work upward. The inputs for the BIC level are
resource(s) information, activity(ies) information, and
knowledge. The BIC level assigns suitable data to the
appropriate capabilities. Ultimately, the output produced
at the ICF level is enterprise competency. The SCF level is
in charge of sectors capability modelling. Based on cap-
abilities from the previous level, the key responsibility of
the ICF level is enterprise-level competency modelling.
The interface between the levels is shown with thick and
break lines, where a thick line represents capabilities
associated aspects information. Break lines illustrate
Figure 3. Enterprise competency subcategories.
796 R.V. Barenji et al.
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sector-level capabilities. Next, BIC, SCF, and ICF levels
of the MICMF are claried in detail.
5.1. BIC level
Capabilities are scattered throughout an enterprise’s var-
ious sectors (Agyapong-Kodua, Weston, and Ratchev
2012). Because capability can be decomposed into a hier-
archy of sub-capabilities, the sector ’s capabilities must be
considered at different levels of abstraction (Ajaefobi and
Weston 2009). To structure a SC, four levels have beendened: Division, Group, Class, and Subclass. The use of
four levels is consistent with the classication structure of
CPC (dened by the UN Statistical Division).
As an example in a manufacturing enterprise:
Sector: Department (e.g. production department anddesign department)
Division: Factory of a department (engine factory of pro-duction department)
Group: Shop at a factory (e.g. crank shaft shop at enginefactory)
Class: Cell at a shop (e.g. crank shaft grinding cell at crank shaft shop)
Subclass: Station at a cell (e.g. centre less grinding stationat the crank shaft grinding cell).
Within the literature, several terms indicate the funda-
mental aspects of competency, including production
skills, technologies, resources, capabilities, processes,
and actors. Boucher, Bonjour, and Grabot (2007)
Figure 4. Multi-level intra-enterprise competency modelling framework.
Figure 5. Functional hierarchy and capability representation.
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consider professional situation, actor, and resource in
their analyses. Müller (2006) considers humans,
resources, and fullled tasks as fundamental components.
The authors adapts the Molina and Bell (1999) research
on manufacturing data modelling, and distinguishes
resource, activity, and knowledge for each of the sectors
within the enterprise as the fundamental aspects for enterprise competency.
The basic premise of BIC level is to organise enter-
prise data as set of distinct components that can be inde-
pendently gathered to develop a variety of capabilities
through the combined components. From a top-down per-
spective, capabilities implemented by a sector are usually
organised into ‘clusters’ of inter-related capabilities from
different divisions, groups, classes and subclasses. These
capabilities have heterogeneous data type that is often
hard to interoperability (Trejo et al. 2002).
Assume a sector contains l capabilities, SC = {C 1,C 2,
…,C l } and a capability consists of mi divisions, C i = ( X i;1,
X i;2,… X i;mi ), where X i; j is a sub-capability a division j in capability i and contains nm groups, X i; j = ( xi; j ;1,
xi; j ;2; . . . ; x i; j ;nm Þ and t n classes, xi; j ;k = ( yi; j ;k ;1, yi; j ;k ;2,…, yi; j ;k ;t n ). For each yi; j ;k ;h capability at class layer, at the
subclass level there are three distinct compounds:
resource, process, and knowledge.
Figure 6 shows the functional hierarchy for engine
production capability and the hierarchical levels for repre-
senting this capability.
5.2. SCF level
The basic idea for the SCF level of MICMF is capability
modelling. A generic SC model in the top-level diagram,
which is composed of all the main classes and their
relationships, makes possible the realisation of a single
conceptual capability model. A SC model is illustrated
in Figure 6, where a facility is considered to be
composed of one or many resources, activities, and
knowledge. Among resources, activities, and knowl-
edge, there are many associated relationships. The role
names of the associations between classes show that
resources perform activities, and knowledge constrains
both resources and activit ies. The hierarchal structure for
resources has been modelled as: human, physical, ICT,and organisational resources. In the same way as for the
resource class, an activity hierarchal structure has been
identied, as has the relationships between classes. Any
one instance of an activity is related to one or many
instances of the resources features that specify the pre-
condition and post-condition of that activity. Any
resource feature can be achieved by one or multiple
different activities. Knowledge restricts the use of
resources and activities.
The formalisation of SC is as follows. Let us consider
for subsequent modelling a set of sectors at an enterprise
E = {S1, S2, S3, …}.
Denition 1 (SC) – Capability can be understood as
sector ’s ability to perform activities, tasks, acts, or pro-
cesses possible through corresponding resources and
knowledge, aimed at achieving a specied number of
outcomes.
For modelling the remaining concept, let us consider
the set of capabilities at sector α: C α ¼ C α1;fC α2; . . . ; C αng in which each element C αi stands for acapability. The following denition introduces the concept
of capability, which is built upon three building aspects. It
can be specied as a set
C αi ¼ X αi; Rαi; K αif g; i ¼ 1; . . . ; n
Such that:
Figure 6. Sector capability (SC) model (Guerra-Zubiaga and Young 2008a).
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X αi ¼ xα1; xα2; x3α; ::; xα j
¼ f xα j j xα j is a activity; task ;act or process for ith capability at sector αg;i ¼ 1; . . . ; n; j ¼ 1; . . . ; m
Rαi ¼ r α1;r α2; r 3α; ::; r α j
¼ fr α j jr α j is a resource for ithcapability at sector αg; i ¼ 1; . . . ; n; j ¼ 1; . . . ; m
K αi ¼ k α1;k α2; k 3α; ::; k α j
¼ fk α j jk α j is a knowledge for
ith capability at sector α
g; i ¼ 1; . . . ; n; j ¼ 1; . . . ; m
Denition 2 (Sector’s task-oriented capability) – A
subset of a sector capabilities set represents capabilities
which are needed to run a specic outcome or specic goal.
For sector α it can be shown as C α where:
C α C i
C α ¼ fC /1; C /2; C /3; . . . ; C /ng ¼ fC /k j C /k is a selected
capabilityat sector α for a specific task g; k ¼ 1; :::; n
5.3. ICF level
The basic idea at ICF level of MICMF is ‘CFC’ and
‘CFI’ of capabilities. CFC of capabilities of a sector has
been identied as a key operation for enterprise compe-
tency creation process (Müller 2006). The successful
achievement of the enterprise’s global goals depends
not only on the appropriate co-ordination of sectors’
capabilities, but the proper integration of the capabilities
at enterprise level is also vital. Additionally, a potential
defect in one node (sector capabilities) may jeopardise
the enterprise competency model. As shown in Figure 7,
the competency may, on its (their) turn, be decomposed
into several sub-capabilities whose activities are sup-
ported (performed) by various service functions avail-
able in the sectors. The interdependencies (sequence/
parallelism, synchronisation, data ow, and precedence
conditions) among capabilities, at the various sectors,
must be properly integrated in order to achieve the
enterprise global goals. ‘CFC’ and ‘CFI’ of capabilities
are dened as:
De
nition 3 (CFC of capabilities) –
CFC is a link among capabilities within a sector; this link seeks to fund
relations between the activities of the capabilities using
sector ’s ‘ product/service work ow diagram’. CFC
acts as union for the other component of the capability
(i.e. resource f Rα1 ̈Rα2 ̈Rα3¨ . . . ̈Rαng and knowl-edge f K α1 ̈K α2 ̈K α3¨ . . . ̈K αmg). CFC is the set of ordered pairs ð x; fxÞ; where x is the independent activityand the x is dependent on x.
CFC C ð Þ ¼ f x; xð Þ j x 2 C and CFC xð Þ ¼ Xg
CFC xð Þ ¼ 0; if a is not sector to the other activities¼ x; is reachable from product =service workflow
diagram:
where:
● C is a capability set
x; x; x are activity, task, act or process.
Denition 4 (CFI of capabilities) – CFI is a link among
capabilities of sectors within an enterprise. This link seeks
to fund relations among the activities of the capabilities at
the enterprise using enterprise’s ‘ product or servicestructural model’. CFI acts as union for the other compo-
nent of the capability between sectors (i.e. resource
f Rα1 ̈Rα2 ̈Rα3¨ . . . ̈Rαng and knowledge f K α1 ̈K α2 ̈K α3¨ . . . ̈K αmg).
CFIαβ C α; C β
¼ f xα; X β
j x 2 C α and CFI xαð Þ ¼ x β g
CFI xαð Þ¼ 0;if xα is not sector on the other activities at
sector β
¼ n β ; is reachable based on product =service
8<:
structural model:
Denition 5 (Enterprise’s competency) – It is
dened as CFC and CFI of task-oriented capabilities
aimed at achieving a global outcome or goal.
Enterprise’s competency denition can be formu-
lated as:
Competencyj1;2G ¼ C 1 C
2 ¼ CFI12 CFC
ni¼1fC
1ig
;
CFC mi¼1fC
2ig
Figure 7. Cross functional integration/co-operation.
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Competencyj1;2;3G ¼ C 1 C
2 C
3 ¼ CFI12 CFC
ni¼1fC
1ig
;
CFC mi¼1fC
2ig
; CFC mi¼1fC
3ig
Competencyj1;2;::;nG ¼ C 1 C
2 . . . C
n ¼ CFI12... n 1ð Þ
CFI12... n2ð Þ . . . CFI12½ ½CFC ni¼1fC 1ig
;
CFC mi¼1fC 2ig
; . . .; CFC k i¼1fC
nig
where:
● G represents a specic outcome or goal.
● 1, 2, 3,…, n is an index for representing sectors.
● C m is task-oriented capability for sector m as
dened previously.
● n
i¼1fC αig ¼ C α1¨C α2¨C α3¨ . . .¨C αnf g.
● CFI and CFC
○
CFInm is cross-function integration between sec-tor n and sector m.
○ CFC is cross function co-ordination.
6. A case study
The manufacturing system where this case study was
carried out is in the custom-designed bicycle industry.
This industry has been operating for over 15 years in
Cyprus and has a growing market demand – generally of
European origin – for its products. To exemplify the
operation of the MICMF, let us deliberate on two sectors
in this industry. These sectors co-operate to design and
fabricate a new bicycle’
s frame. In this scenario, sector A prepares detail model of the desired frame using a CAD
system and denes some additional characteristics for this
part. This technical specication is then sent to sector B.
Sector B might accept the proposed design or suggest
changes that have to be negotiated with sector A until an
agreement is reached. Finally, sector B is responsible for
fabricating the frames. Competency modelling objectives
at this example concern the identication, updating, and
exploitation of the intra-enterprise competency. The fra-
mework of Figure 4 was adapted to the domain study.
MICMF is grouped into three operational levels,
which facilitate the competency modelling. These levels
groups tasks according to their competency modellingaspects and/or subcategories. Each level is useful in cer-
tain situations.
BIC Level:
(a) Identify and list required capabilities of the sector,
(b) Assign resources, activities, and knowledge to the
sequenced capabilities.
SCF Level:
(a) Interactions of capabilities within sectors and
between the sectors
(b) SC model.
ICF Level:
(a) CFC of capabilities within a sector, and CFI of
capabilities between sectors
(b) Competency representation
BIC Level:
(a) Identify and list required capabilities of sector.
The rst step for competency modelling is identication
and evaluation of the exist capabilities at the sectors.
Work-station oriented (or goal-oriented) approach is
used for identication and evaluation of necessary andacquired capabilities at the sectors. This process include
four stages: (1) analysis of goal; (2) deriving the structure
of goal; (3) determination of the various capabilities
needed to overcome goal; and (4) sequencing those
acquired.
There are methods for identication and evaluation
of necessary capabilities at a sector. Among the exist-
ing methods, the observation, the description, the inter-
view, the method of the critical incidents, and the grid
of Kelly can be mentioned (Harzallah and Vernadat
2002). Here, the method used to identify capabilities
is based on the interview approach. In this example the
goal of the sector A is design, prototyping and testing anew bicycle’s frame and for sector B is fabricate and
quality control of the new frame. Furthermore, the
enterprise global goal is offering a new designed
bicycle to the market. After ident ication process, the
listed capabilities are then sequenced so that they fol-
low the order in which they will be performed.
Successful completion of these attempts often requires
a good knowledge of process planning, manufacturing
features and manufacturing resources. In this example,
C Mfg : and C Desgi n: are the set of capabilities for sector A
and B of the enterprise, respectively:
C Mfg : ¼ ‘Cutting’; ‘Forming’; ‘Joining’; ‘Weighing’;f
‘Painting’; ‘Finalisation’; ‘Quality control’g
C Lab ¼ ‘Conceptdesign’;‘Prototyping’;‘Analysis’;f
‘Test ’;‘Detail design’g
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(b) Assign resources, activities, and knowledge to the
sequenced capabilities
To complete the BIC level, it is necessary that the
resources (e.g. machines and tools) and activities (e.g.
manufacturing processes), as well as the knowledge that
is needed for each capability are assigned. For theresources, activity, and knowledge assign processes of
acquired capabilities, interviews of personal appreciation,
samples, and references are used. The ‘Detail design’ at
sector A furthermore ‘Cutting’ and ‘Forming’ capabilities
at sector B have the following sub elements:
Tables 2 and 3 demonstrate the assigned resources, activ-
ities, and knowledge for the capabilities of the sectors.
SCF Level:
(a) Interactions of capabilities within sectors and
between the sectors
Clarication of the interactions between the capabilities
within the sector and among sectors of an enterprise is
vital since it will be used at next level of the framework.
For simple cases, numbers (also called capability numbers)
indicate the sequence in which the capabilities will take
place. For example, in sector B, rst the cutting capability
must be nished, and then the forming capability, before
painting capability takes place. Sometime a capability can
have a exible sequence and sometimes two or more
capabilities can take place simultaneously. In a similar
way, specic interactions between the capabilities have to
be done for each of the sectors of the enterprise. For a case
with numerous interactions between the capabilitiessequence diagrams are applicable for this purpose.
Figures 8 and 9 illustrate the sequence diagrams for the
interactions of capabilities within the sector A and B.
Furthermore, the sequence diagram in Figure10 demon-
strates the interaction of capabilities among sector A and B.
(b) Capability modelling
To store competency aspects in a structural manner, it is
signicant to model the capabilities within the sectors.
Thus the study has been oriented to create capabilitymodels. The capability model which is introduced pre-
viously (Denition 3 – shown in Figure 6) was adapted to
all the identied capabilities at the enterprise. This model
is used to capture all the aspects (i.e. resource, activity,
and knowledge) of the capabilities. Figure 11 shows what
a more comprehensive and detailed the cutting capability
would look like when performed with a model.
A capability knowledge base is developed to assure
that the knowledge of capabilities at the sectors is
Cutting@ Mfg : ¼
fCentre cutting; Curve cuttingg
fCentre Cutting fixture; Curve Cutting fixture; Tool1; Tool2; Cutting M2; T1; T2g
fCutting M1 Manual; Cutting M2 Manual; Center Cutting Handbook ; Curve Cutting HandBook g
8><>:
9>=>;
¼
xC 1;; xC 2 r C 1;r C 2;r C 3r C 4;r C 5; r C 6; r C 7; r C 8
k C 1;k C 2;k C 3; k C 4
8><>:
9>=>;
Forming@ Mfg : ¼
Tube forming; Bendingf g
Tube forming Die; Tube forming press; Bending M; T3; T4f g
Tube forming HandBook ; Bending HandBook ; Tube formingpress manualf g
8><>:
9>=>;
x F 1;; x F 2
r F 1;r F 2;r F 3r F 4;r F 5
k F 1;k F 2;k F 3
8><>:
9>=>;
Quality Control@ Mfg : ¼
NDT testingf g
Ultrasonic NDT Machine; T7f g
Testing eorksheet ; Ultrasonic NDT machine manualsf g
8>:
9>=>; ¼
xQC 1;
r QC 1;r QC 2 k QC 1;k QC 2
8>:
9>=>;
Detail desgin@ Desgin: ¼
Partdesgin; Assembling; Drawingf g
CADf g
Detail desgin skillf g
8><>:
9>=>; ¼
x DD1; x DD2; x DD3f g
r DD1f g
k DD1f g
8><>:
9>=>;
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Table 2. The resource, activity, and knowledge assuaged to the capabilities at sector A.
Resource Process Knowledge
Concept capabilityDrawing tablet Quick sketching a few concepts Design skillDrawing tools Shading and reningTechnical software Choosing-one
designer type 1 3D modellingRening 3D model
Prototyping capabilityRapid prototyping Proof-of-Principle Prototyping prototyping technicalmachine Form Study Prototyping worksheet Common hand tools User Experience Prototyping RP machine manualsTechnician type 8 Visual Prototyping
Functional PrototypingTest and analysis capabilityStatic test apparatus Static test ABAQUS document Dynamic test Dynamic test Static test worksheet apparatus Structural analysis Dynamic test worksheet ABAQUS software Aerodynamic test Aerodynamic test Aerodynamic test worksheet apparatus Static test apparatus
Technician type 8 manualTechnician type 9 Dynamic test apparatus manual
Aerodynamic test apparatus manualDetail designCAD Part design Detail design skill
Assemblies designDrawing
Table 3. The resource, activity, and knowledge assuaged to the capabilities at sector B.
Resource Process Knowledge
Cutting capabilityCentre Cutting xture Centre Cutting (CC) Cutting Machine1Manual
Curve Cutting Fixture Curve Cutting (CuC) Cutting Machine2 ManualTool 1 – Tool 2 Centre Cutting Process Hand Book Cutting Machine 1 Curve Cutting Hand Book Cutting Machine 2Technician type 1Technician type 2Forming CapabilityTube forming Die Tube forming Tube forming process Hand Book Tube forming press Bending Bending process Hand Book Bending Machine Tube forming press manualTechnician type 3Technician type 4Joining capabilityOxyacetylene welding system Gas welding Welding process Hand Book Welding xture Welding machine manualsElectrodeTechnician type 5Painting capabilityHand abrasive machine Paint preparation Paint preparation worksheet Painting oven Painting Painting oven manualTechnician type 6Finalisation CapabilityTechnician type 7 Cleaning Cleaning worksheet Cleaning machine Labelling Cleaning machine manualQuality control capabilityUltrasonic NDT machine NDT testing Testing worksheet Technician type 7 Ultrasonic NDT machine manuals
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capitalised. At present, the knowledge base is developed
under Microsoft Access and is operational. The relational
model of the capability knowledge base is represented in
Figure 12. The use of a standard incoming application
adds knowledge gathering process (Figure 13) to thecapability knowledge base system.
ICF Level:
(a) ‘CFC’ and ‘CFI’ of capabilities
Three main subcategories of enterprise competency
exploitation are dened as: (1) SC; (2) CFC; and (3)
CFI. The SC subcategory concerns the store of enterprise
competency aspects (i.e. resource, activity, and knowl-
edge) which is resulted as a capability-based knowledge
base. The ‘CFC’ and ‘CFI’ subcategories concern the
linking of enterprise competency aspects.
The ‘CFC’ process (Denition 3) was adapted to allthe identied capabilities at the sectors. To do this, the
sector ’s capabilities sequence diagram (Figures 9 and 10)
is used. As examples:
CFC Cutting→ Forming:
fð xC 1;0Þ; ð xC 2;0Þgr C 1;r C 2;; r C 3;r C 4;r C 5;; r C 6;r C 7;r C 8;r F 1;r F 2;r F 3r F 4;r F 5
k C 1;k C 2;k C 3;k C 4;k F 1;k F 2;k F 3
8<:
9=;
Figure 8. Interactions of capabilities at design sector.
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CFC Cutting→ Quality Control:
fð xC 1; xQC 1Þ; ð xC 2; xQC 1Þgr C 1;r C 2;; r C 3;r C 4;r C 5;; r C 6;r C 7;r C 8;r QC 1;r QC 2
k C 1;k C 2;k C 3;k C 4;k QC 1;k QC 2
8<:
9=;
Using the capabilities sequence diagram among the sec-tors (Figure 11), the ‘CFI’ process (Denition 4) was
adapted to the identied capabilities at the enterprise. As
an example:
CFI Detail Design →Cutting:
fð x DD1; xC 1Þ; ð x DD1; xC 2;Þ; ð x DD2;0Þ; ð x DD3;0Þgr DD1; r C 1; r C 2; r C 3f g
k DD1; k C 1; k C 2; k C 3; k C 4; k C 5f g
8<:
9=;
Figure 14 illustrates the application which is developed
for ‘CFC’ and ‘CFI’ processes, aiming to appreciate this
processes using the knowledge base and the sector ’s
‘capabilities sequence diagrams’ at the sector or the
enterprise. The ‘CFC’ and ‘CFI’ processes were sepa-
rately adapted to each of the identied capabilities at the
enterprise.
(b) Enterprise competency representation
At this stage all the competency aspects were stored, and all
the competency associated subcategories were linked as well;the next step is to represent enterprise competency. Using
enterprise competency denition (Denition 5), the example
given below depicts competency creation process at the
enterprise. For simplication in this example, only three
capabilities (detail design from sector A, and cutting and
quality control from sector B) are taken in to consideration.
Competency (Cutting, Quality Control) →(Detail Design):
fð xC 1; xQC 1; x DD1Þ; ð xC 2; xQC 1; x DD1Þgr C 1;r C 2;; r C 3;r C 4;r C 5;; r C 6;r C 7;r C 8;r QC 1;r QC 2
k C 1;k C 2;k C 3;k C 4;k QC 1;k QC 2
8<:
9=;
Figure 15 depicts the dialog boxes in which the com-
petency are shown. The dialog boxes also show the fea-
tures of the competency stored in the knowledge base. The
experimental software developed can show capability
attributes by clicking on the particular sign beside each
row. For example, two existing activity instances can be
observed: (a) curve cutting, and (b) tube forming. For the
curve cutting process there exist two boxes entitled as
Figure 9. Interactions of capabilities at manufacturing sector.
Figure 10. Interactions of capabilities among the design andmanufacturing sectors.
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curve cutting record N1 and record N2. Within each boxes
the interrelated activity which are resulted from CFC
process is listed. Furthermore, external related activity
which results from CFI process and its desired capability
is listed in another row. It is important to emphasise that
by clicking on a capability at the boxes, the activity and
resource information and the activity and resource knowl-
edge will be displayed in separate dialog boxes. The
developed prototype application and competency knowl-
edge base captured, managed, and published the enterprise
Figure 11. The capability model for the cutting capability.
Figure 12. Relational model of capability knowledge base.
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internal competency knowledge with a consisted set of
concepts and aspects. The contents of competency knowl-
edge base is demonstrated in two human usage and
machine readable (XML) formats. This knowledge base
can be used to support various enterprise applications
related to competences of an enterprise and presents a
clear understanding of the enterprise detail area of
expertise.
7. Conclusions
The paper rst presents an overview of work in the area of
enterprise’s competency modelling from two different per-
spectives, namely ‘managerial science and industrial engi-
neering’ and ‘IT managerial science’. The need for an
empirical competency modelling from IT managerial per-
spective is discussed in detail, and the shortcoming of the
existing competency models is discussed. An enterprise
data infrastructure for integrating knowledge of the enter-
prise is presented and the responsibility of the competency
model at intra-enterprise data infrastructure is highlighted.
A multi-level competency modelling framework for intra-
enterprise is presented. The need for a multi-level model-
ling framework for CFC and CFI for sector ’s capabilities
is discussed in detail and the resulting requirements are
represented. Based on previous contributions for capabil-
ity modelling, a generic SC model is proposed, and CFC
and CFI of the capabilities are deed as major advance-
ments for intra-enterprise competency modelling. An
example based on the proposed framework is currently
under implementation. The developed experimental sys-
tem offers four benets, in that they (a) enhance the
organisations willingness to collaborate, (b) boost the
organisation’s competitiveness, (c) facilitate appropriate
decision-making, and (d) nally help to integrate the entire
organisation.
Figure 13. Screen shot of the application for entering resource and activity information and knowledge for capability modelling purpose.
Figure 14. Screen shot of the application for CFC and CFI processes.
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