A MEASUREMENT INSTRUMENT FOR INDIVIDUAL
INFORMATION COMPETENCY IN AN ENTERPRISE
INFORMATION ENVIRONMENT
Chui Young Yoon and Keon Myung Lee
College of Electrical & Computer Engineering, Chungbuk National University, 410 Sungbong-Ro (Gaeshin-dong)
Heungduk-gu, Cheongju city, Chungbuk, 361-763, South Korea
Keywords: Information Competency, Measurement Factor, Measurement Instrument, Measurement Process.
Abstract: An instrument that can efficiently measure individual information competency is presented to develop and
manage the information application ability of individual working in an enterprise information environment.
The measurement items are extracted from the major components of a competency. By factor analysis and
reliability analysis, a 14-item instrument is proposed to entirely measure individual information capability.
The tool’s application and utilization are discussed through a case study and the presentation of its results.
1 INTRODUCTION
Today, information technology (IT) progression
makes data resources and information systems (IS)
become firm’s critical strategic resources. (Wu et al.,
2005). The efficient utilization of IT in a firm is a
critical factor to effectively improve its task
performance and competitiveness in an information
environment. It is important for human resources
working in an enterprise information environment to
have the capability to effectively execute the given
tasks by applying their information systems to their
business. (Mathis and Jackson, 2000; O’Leary,
2002). An individual who directly executes his or
her business needs the ability to efficiently perform
individual tasks by applying IT and information
systems to his or her business in an enterprise
information environment.
Hence, this study presents an instrument to
measure the individual information competency,
which focuses on the entire information capability
that an individual can efficiently use information for
his or her tasks in an enterprise information
environment.
2 THEORETICAL RESEARCH
In previous literature, an end-user was defined as a
person who directly interacts with his or her
computer. (McHaney et al., 2002; Rondeau et al.,
2006; Wu et al., 2007). Based on these studies, we
can define an individual as a person who directly
interacts with his or her information systems.
In previous literature, competency was defined
as effective application of available knowledge,
skills, attitudes, and values in complex situations.
(Govindarajulu and Reithel, 1998; Bassellier et al.,
2001; Tanner, 2001). Namely, the major components
of a competency are knowledge, skills, concepts,
and development. Individual competency is used to
deal with the competence of a person, the collective
competency is used to deal with the competence
emerging from a group of persons, and global
competency is used to describe the organizational
ability of an enterprise. (Boucher et al., 2007).
By summarizing prior researches, an individual
information competency (IIC) can be defined as the
total capability that an individual can efficiently
apply information knowledge, skills, attitudes, and
values to his or her tasks to execute the given tasks
in an enterprise information environment. In other
words, IIC is defined as the total capability that an
individual directly interacts with his or her
information systems to efficiently perform the given
tasks through using an organizational data and
solutions on information systems. IIC is the entire
information capability that an individual can
effectively do his or her tasks on an enterprise
information system. Based on the definitions and
components of IIC, this study generated the 27
101
Young Yoon C. and Myung Lee K. (2010).
A MEASUREMENT INSTRUMENT FOR INDIVIDUAL INFORMATION COMPETENCY IN AN ENTERPRISE INFORMATION ENVIRONMENT.
In Proceedings of the International Conference on e-Business, pages 101-106
DOI: 10.5220/0003045601010106
Copyright
c
SciTePress
measurement items that can gauge IIC in an
enterprise information environment. (Govindarajulu
and Reithel, 1998; Bassellier et al., 2001; Tanner,
2001; Boucher et al., 2007; Torkzadeh and Lee,
2003; McCoy, 2001).
3 METHODS
Previous literature proposed methods to verify the
validity and reliability of the model construct. Most
studies presented two methods for a model construct
validation: (1) correlations between total scores and
item scores, and (2) factor analysis. (Brancheau and
Brown, 2002; McClelland, 1973; Boyatiz, 1982;
Jacobs, 2002). Torkzadeh and Doll (1999) and
Torkzadeh and Lee (2003) used correlation analysis
to verify the validity of the model construct. Etezadi-
Amoli and Farhoomand (1996), and McHancy et al.
(2002) utilized factor analysis to verify the validity
of the model construct. We verify the validity and
reliability of the instrument construct and extracted
adequate measurement items by factor analysis and
reliability analysis. The ratio of sample size to
number of measurement items (11:1) was above the
minimum (10:1) ratio suggested for factor analysis
by previous literature. (Torkzadeh and Lee, 2003;
Rodriguez et al., 2002). The measurement
questionnaire used a five-point Likert-type scale;
where, 1: not at all; 2: a little; 3: moderately; 4:
much; 5: a great deal. The questionnaire is
composed of two response domains: one is answer
to general data of respondents, such as degree, age,
gender, major field, industry and business
department, business position level and years of job
experience; the other is response to the measurement
items.
3.1 Sample Characteristics
A sample of 243 usable responses was obtained
from a variety of industries and business
departments, and from management levels. The
respondents in terms of business departments were
identified as strategy planning (21.1%), development
and maintenance (26.8%), business application
(38.4%), and administration support (13.7%). The
respondents identified themselves as top manager
(3.7%), middle manager (44.7%), and worker
(51.6%). The respondent had on average of 8.9 years
of experience (S.D. =1.118) in their field, their
average age was 32.9 years old (S.D. =6.473), and
their gender, male (79.8%) and female (20.2%).
3.2 Analysis and Discussion
Items were excluded when their correlation with the
collected item-total was < 0.5 or when their
correlation with the criterion scales was < 0.6.
(Torkzadeh and Lee, 2003; Rifkin et al., 1999;
McCoy, 2001). The correlations with the corrected
item-total and the criterion item were significant at p
0.01 and similar to those used by others in
previous researches. (Torkzadeh and Lee, 2003;
Rifkin et al., 1999; McCoy, 2001). After these
analyses, the first 27 measurement items were
reduced to 14 items, with 13 items were deleted. The
elimination was sufficiently considered to ensure
that the retained items were adequate measures of
IIC. The validity and reliability of the instrument
were verified by factor analysis and reliability
analysis. They were used to identify the underlying
factors or components that comprise the IIC
construct. These deletions resulted in a 14-item scale
for measuring IIC. Each of the 14 items had a factor
loading > 0.637. The reliability coefficients
(Cronbach’s alpha) of four potential factors had
values > 0.797, above the threshold recommended
for exploratory research. (Rodriguez, 2002). The
descriptions and loadings for the 14 items are
presented in Table 1 and Table 2.
Table 1: Factor loadings obtained from factor analysis.
0.659V26
0.732V19
0.756V23
0.779V17
0.794V16
0.811V12
0.872V18
0.699V11
0.741V13
0.765V08
0.881V10
0.637V03
0.762V06
0.794V04
Factor 4Factor 3Factor 2Factor 1
Factor Loadings
Variable
0.659V26
0.732V19
0.756V23
0.779V17
0.794V16
0.811V12
0.872V18
0.699V11
0.741V13
0.765V08
0.881V10
0.637V03
0.762V06
0.794V04
Factor 4Factor 3Factor 2Factor 1
Factor Loadings
Variable
To examine the reliability and validity of the
measures, we calculated the corrected item-total
correlations between each variable and its
corresponding factor. These correlations along with
alpha coefficients of each factor are presented in
Table 2. This also shows the alpha coefficients for
the measurement of factors if a measure was deleted
from the scale. These coefficients indicate the
relative contribution of a measure to the construction
of a scale for measuring a particular factor. They are
all in the acceptable range. Most corrected item-total
ICE-B 2010 - International Conference on e-Business
102
correlations were greater than 0.600, showing that
the individual measures are good indicators of their
corresponding factors.
Table 2: Corrected item-total correlations and the
coefficient alphas of 14-measurement items.
0.7120.679V19
Coefficient alpha for the above 3 items as a composite measure of
Factor =0.797
0.6120.648V26
0.7210.819V23
0.8020.735V17
Coefficient alpha for the above 4 items as a composite measure of
Factor =0.813
0.8490.821V16
0.7780.785V12
0.8170.841V18
Coefficient alpha for the above 4 items as a composite measure of
Factor =0.903
0.7360.789V11
0.7490.781V13
0.8120.744V08
0.8450.812V10
Coefficient alpha for the above 3 items as a composite measure of
Factor =0.823
0.6530.670V03
0.7910.721V06
0.7350.681V04
Alpha if item deleted
Corrected item-total
correlation
Variable
0.7120.679V19
Coefficient alpha for the above 3 items as a composite measure of
Factor =0.797
0.6120.648V26
0.7210.819V23
0.8020.735V17
Coefficient alpha for the above 4 items as a composite measure of
Factor =0.813
0.8490.821V16
0.7780.785V12
0.8170.841V18
Coefficient alpha for the above 4 items as a composite measure of
Factor =0.903
0.7360.789V11
0.7490.781V13
0.8120.744V08
0.8450.812V10
Coefficient alpha for the above 3 items as a composite measure of
Factor =0.823
0.6530.670V03
0.7910.721V06
0.7350.681V04
Alpha if item deleted
Corrected item-total
correlation
Variable
Hence, the measurement items, with a validity and
reliability, were extracted by carrying two analyses
as shown in Table 1 and Table 2.
4 MEASUREMENT
INSTRUMENT
These analyses classified the extracted items as 4
factor groups. These factor groups indicate the
potential major factors to measure the IIC. With
investigating the measurement items of each factor,
we generated the 4 potential factors as follows:
factor 1: information concepts; factor 2: information
knowledge; factor 3: information utilization; and
factor 4: information development. The 4 potential
factors are considered the major factors of the
instrument construct. Figure 1 shows the structure of
the measurement instrument based on the 4 potential
factors and 14 items. Each factor has three or four
measurement items as shown in Figure 1.
Information Concepts (IC)
IC04 Do you understand future information progress ?
IC06 Do you think that information is important for management activities ?
IC03 Do you consider ethics and morality when using information ?
Information Knowledge (IK)
IK10 Do you know your firm’s information systems ?
IK08 Do you know of the solutions of your firm’s information systems ?
IK13 Do you know security measures for your firm’s information systems ?
IK11 Do you know packaged application software in your firm’s information systems ?
Information Utilization (IU)
IS18 Can you perform your tasks in your firm’s information systems?
IS12 Can you use packaged application software in your firm’s information systems?
IS16 Can you use your information systems for e-Business and m-Business ?
IS19 Can you use a groupware solution to efficiently execute a team project ?
Information Development (ID)
IV17 Do you have obtained degrees or certificates related to information departments ?
IV23 Do you have completed the education and training related to information
departments ?
IV26 Do you have suggested the improvement of your firm’s information systems ?
Information Concepts (IC)
IC04 Do you understand future information progress ?
IC06 Do you think that information is important for management activities ?
IC03 Do you consider ethics and morality when using information ?
Information Knowledge (IK)
IK10 Do you know your firm’s information systems ?
IK08 Do you know of the solutions of your firm’s information systems ?
IK13 Do you know security measures for your firm’s information systems ?
IK11 Do you know packaged application software in your firm’s information systems ?
Information Utilization (IU)
IS18 Can you perform your tasks in your firm’s information systems?
IS12 Can you use packaged application software in your firm’s information systems?
IS16 Can you use your information systems for e-Business and m-Business ?
IS19 Can you use a groupware solution to efficiently execute a team project ?
Information Development (ID)
IV17 Do you have obtained degrees or certificates related to information departments ?
IV23 Do you have completed the education and training related to information
departments ?
IV26 Do you have suggested the improvement of your firm’s information systems ?
Measurement
Instrument of
IIC
Information
Concepts
(IC)
Information
Utilization
(IU)
Information
Knowledge
(IK)
Information
Development
(ID)
V04 V06 V03 V10 V13 V11 V18 V19 V17 V23 V26
V08 V16V12
Figure 1: Structure of measurement instrument.
4.1 Measurement Factors and Items
This instrument has 4 major factors to measure IIC
in an enterprise information environment.
Information concepts mean state of mind,
feelings, and belief related to IT. It includes the
measurement items that can identify individual
attitude on the future IT progress, IT importance for
a firm, and ethic and morality in using information
on an enterprise information system.
Information knowledge indicates complex
process of remembering, relating or judging
information to efficiently use an information system.
Namely, information knowledge represents IT
knowledge to effectively perform the given tasks on
an enterprise information system. It comprises the
items that can gauge IT knowledge related to
hardware, software, networks, and database for a
firm information system, knowledge of packaged
application software related to ERP, SCM, and CRM,
knowledge related to e-Business (B2E, B2C, and
B2B), and knowledge related to security measures in
a firm’s information system.
Information utilization is the ability that utilizes
information to perform specific mental or physical
tasks, and includes mental or cognitive skills.
Information skills mean the ability that an individual
utilize IT knowledge, solutions, and information
systems to his or her tasks. It contains the skills as
follows: utilization of network and server; use of
A MEASUREMENT INSTRUMENT FOR INDIVIDUAL INFORMATION COMPETENCY IN AN ENTERPRISE
INFORMATION ENVIRONMENT
103
packaged application software, such as ERP, SCM,
and CRM; use of the information systems for e-
business of the form B to E, B to C, and B to B; and
the skills to use the security measures in a firm’s
information system.
Information development refers to the endeavor
to improve knowledge and skills related to
information. It provides the potential ability to
efficiently improve IIC. It has the items that can
measure an individual mind on degrees and
certificates, domestic and overseas educations and
trainings, and suggestion for the improvement of
your information systems. This is the important
factor for the extension of information capability in
terms of the breadth and depth of IIC.
This instrument is a crucial theoretical construct
to measure an individual’s total information ability
that can efficiently do his or her tasks in an
enterprise information environment.
5 MEASUREMENT PROCESS
5.1 Framework of Measurement
Process
The measurement process has two main stages,
including the measurement stage and presentation
stage of the measurement results (Figure 2). The
measurement stage examines individuals by a
questionnaire based on 4 measurement factors and
14 items. The measurement results are analyzed by
extracting the measurement values of each factor
and by applying each weight value to the
measurement values of each factor.
The presentation stage provides the measurement
results based on each factor. The results are
explained by each measurement index extracted
from each factor. The interpretation of the results
presents the present states and problems of the IIC,
and the directions and methods to efficiently
improve the IIC based on the extracted measurement
indices.
5.2 Measurement Method
We used the weight values for each measurement
factor in order to develop an efficient instrument
considered the relative importance of each factor in
measuring IIC. The weight values, Table 3, were
extracted from the analysis results of the
questionnaire survey (AHP) for about 30 experts
working in our IT research center.
Start
Measurement Instrument
(IT Concepts, Knowledge,
Utilization, and Development)
Measurement
Item
Database
Performing
Measurement or Checking
Results ?
Measurement Execution
(4 Measurement Factors/14 Items)
Measurement System
(ID/PW)
Personal
Information
Database
Analysis of Measurement Results
(Extraction of Measurement Index)
Presentation of Measurement Results
(Problems and Improvement Methods)
Weight Value
Database
(4 Factors)
End
Measurement
Results
Database
Check
Perform
Start
Measurement Instrument
(IT Concepts, Knowledge,
Utilization, and Development)
Measurement
Item
Database
Performing
Measurement or Checking
Results ?
Measurement Execution
(4 Measurement Factors/14 Items)
Measurement System
(ID/PW)
Personal
Information
Database
Analysis of Measurement Results
(Extraction of Measurement Index)
Presentation of Measurement Results
(Problems and Improvement Methods)
Weight Value
Database
(4 Factors)
End
Measurement
Results
Database
Check
Perform
Figure 2: Measurement process.
The measurement method first calculates the
measurement values of each factor based on the
analysis results that an individual is tested by the
measurement items of each factor. It figures out the
measurement indices of each factor by multiplying
each weight value by the measurement value of each
factor.
Table 3: Weight values for each measurement factor.
0.22Information Development
0.33Information Utilization
0.25Information Knowledge
0.20Information Concepts
Weight ValueMeasurement Factor
0.22Information Development
0.33Information Utilization
0.25Information Knowledge
0.20Information Concepts
Weight ValueMeasurement Factor
The measurement index (MI) means the value
extracted by multiplying the weight value by the
measurement value. The sum of the measurement
indices of each factor becomes the individual entire
MI.
Hence, the measurement index (MI) of each
factor can be presented as Equation (1).
MI
MFi
= MV
MFi
x WV
MFi
(1)
Where, MI
MFi
: Measurement index (MI) of the i th
Measurement Factor
MV
MFi
: Measurement Value (MV) of the i th
Measurement Factor
ICE-B 2010 - International Conference on e-Business
104
WV
MFi
: Weight Value (WV) of the i th
Measurement Factor
Here, the sum of the weight values of each factor
is 1.00 and i = 1, 2, 3 and 4 indicate four
measurement factors.
Therefore, the total MI can be defined as Equation
(2) by Equation (1):
4
Total MI = MI
MFi
i=1
(2)
Here, the i = 1, 2, 3 and 4 mean the four
measurement factors.
In this way, this instrument presents the
measurement results of IIC based on the total MI
and measurement indices of each factor. The
problems of the IIC are presented by the results. The
efficient methods to improve the IIC are also
provided by the total MI and measurement indices of
each factor.
6 CASE STUDY AND
DISCUSSION
This case study applied the developed tool to 137
workers working in “B” enterprise, Republic of
Korea.
6.1 Analysis and Discussion: Overall
Organization
We presented the measurement results of each
business department and overall organization. The
total MI of the overall organization was 62.73, and it
was quite high. The business application department
(BAD) and the administration support department
(ASD) were 65.27 and 63.16 as shown in Figure 3.
The measurement results of each business
department represented that the MI of the BAD was
higher than those of the other departments. This is
due to the ability to effectively accomplish their
tasks by frequently applying information knowledge
and systems to e-Business of the form B to C, B to B
and B to E, and the knowledge and abilities to utilize
the various solutions, such as ERP, SCM, and CRM
to effectively perform their business tasks on an
enterprise information system.
63.16
65.27
60.36
62.14
62.73
56
58
60
62
64
66
Total
Measurement
Index
Strategy
Plan
Department
Development
Maintenance
Department
Business
Application
Department
Administration
Support
Department
Figure 3: Measurement indices of each business
department and overall organization.
Figure 4 presents the measurement indices of each
factor for each business department within the
organization. The MI of the BAD in all
measurement factors was higher than those of the
other departments. Especially, the BAD was very
high level in information utilization. It indicates that
the BAD had the distinguished skills to utilize
information solutions and systems to efficiently
perform the given tasks. The strategy plan
department (SPD) was quite high in the information
development. It means that they completed the
endeavor to improve knowledge and skills related to
information
65.27
62.36
62.06
61.89
62.25
62.14
59.34
60.04
58.85
60.36
63.21
61.95
70.26
66.29
62.58
60.16
66.43
64.21
61.84
63.16
52
54
56
58
60
62
64
66
68
70
72
Total MI Information
Concepts
Information
Knowledge
Information
Utilization
Information
Development
SPD DMD BAD ASD
Figure 4: Measurement indices of each factor for each
business department.
6.2 Analysis and Discussion: an
Individual
The total MI of the individual was 64.89, and it was
a little high. Especially, the MI of the information
utilization was very high. This means the
outstanding skills to utilize the information
knowledge, solutions, and systems to his or her tasks
in an enterprise information environment. However,
A MEASUREMENT INSTRUMENT FOR INDIVIDUAL INFORMATION COMPETENCY IN AN ENTERPRISE
INFORMATION ENVIRONMENT
105
the MI of the information concepts and development
were low as indicated in Figure 6.
62.47
64.01
63.16
68.17
64.89
58
60
62
64
66
68
70
Total
Measurement Index (MI)
Information
Concepts (IC)
Information
Knowledge (IK)
Information
Utilization (IU)
Information
Development (ID)
Total
Measurement Index (MI)
Information
Concepts (IC)
Information
Knowledge (IK)
Information
Utilization (IU)
Information
Development (ID)
Figure 6: Measurement indices of an individual in the
BAD.
Therefore, this individual should make an effort to
improve the information concepts and development
to effectively raise his or her information
competency in general.
7 CONCLUSIONS
We presented an instrument that can efficiently
measure an IIC in an enterprise information
environment. This instrument includes structure,
concrete items, and measurement process and
method. This instrument has a nature as a global
standard across industries, and business departments
and positions.
Therefore, this study provides an instrument that
can measure IIC required to efficiently execute an
individual’s given tasks in an enterprise information
environment.
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