Critical Success Factors for the of Acceptance and Use of an LMS
The Case of e-CLASS
Stavros Valsamidis
1
, Ioannis Kazanidis
1
, Vasilios Aggelidis
2
, Sotirios Kontogiannis
3
and Alexandros Karakos
4
1
Department of Accounting and Finance, TEI of East Macedonia and Thrace, Agios Loukas, 65404 Kavala, Greece
2
Department of Business Administration, TEI of East Macedonia and Thrace, Agios Loukas, 65404 Kavala, Greece
3
Department of Business Administration, TEI of West Macedonia,
6th National Road Kozani Grevena, 51100 Grevena, Greece
4
Department of Electrical and Computer Engineering, Democritus University of Thrace,
University Campus Kimeria, 67100 Xanthi, Greece
Keywords: e-Learning, Critical Success Factors, Instructor, Student, Technology, Support.
Abstract: Nowadays, as e-learning is increasingly used in education, it is useful to know what are the critical factors
for its successful implementation in higher education institutes. This research has two main objectives. The
initial objective is to clarify and categorize the Critical Success Factors (CSF) of education with the use of a
Learning Management System (LMS) from the perspective of students and then to investigate the
relationships among these factors, suggesting a new causal model. To achieve the above objectives, an
extensive, detailed and systematic study of available literature sources was held. Then, the critical success
factors were separated in four (4) broad categories: instructors' characteristics, students' characteristics,
information and communications technology used and technical support provided by the technical staff.
Each factor contains a number of deterministic variables which were adopted mainly by previous studies.
Also, for the collection of data for analysis, a questionnaire was distributed to students who use the LMS.
Technical multivariate analysis was used to examine the relevance of each variable determinant factor,
while for the evaluation of the causal model, structural equation systems were used.
1 INTRODUCTION
The use of Internet in education has created a new
context known as e-learning or web-based education
process, in which large amounts of information
about teaching–learning interaction are endlessly
generated and ubiquitously available. e-Learning is
one of the tools emerged from information
technology and it has been integrated in many
university programs. e-Learning describes the ability
to electronically transfer, manage, support, and
supervise learning and learning materials (Normark,
and Cetindamar, 2005). In its broadest sense e-
Learning can be defined as instruction delivered via
all electronic media including the Internet, intranets,
extranets, satellite broadcasts, audio/videotape,
interactive TV and CD-Rom (Urdanand Weggen,
2000).
e-Learning has been viewed as synonymous with
web-based learning (WBL), Internet-based training
(IBT), advanced distributed learning (ADL), web-
based instruction (WBI), online learning (OL) and
open/flexible learning (OFL) (Khan, 2001). e-
Learning is the effective learning process created by
combining digitally delivered content with learning
support services (Hara & Kling, 1999). Above are
the varied definitions and meanings that can be
ascribed to the modern pedagogy known as e-
learning. The categories of eLearning are depicted in
figure 1 (Siemens, 2004). e-Learning for the
purposes of this article refers to teaching and
learning that is web-enabled (Govindasamy, 2002).
The growth of e-learning led to the appearance of
Learning Management Systems (LMSs), which
provide a variety of features and operations
including the development, management,
distribution, diffusion and presentation of the
educational material as well as tools for the
management of users and courses. Some of the most
well-known commercial LMS are Blackboard,
Valsamidis, S., Kazanidis, I., Aggelidis, V., Kontogiannis, S. and Karakos, A.
Critical Success Factors for the of Acceptance and Use of an LMS - The Case of e-CLASS.
In Proceedings of the 8th International Conference on Computer Supported Education (CSEDU 2016) - Volume 2, pages 331-338
ISBN: 978-989-758-179-3
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
331
WebCT and TopClass while Moodle, Claroline and
aTutor are free distributed (Romero et al., 2008). In
Greece, the Greek University Network (GUNet) uses
Open eClass platform (GUNet, 2015), which is an
evolution of Claroline (Claroline, 2009). This
system is an asynchronous distant education
platform and is open source under a General Public
Licence (GPL).
Figure 1: Categories of eLearning.
Ingramet et al., (2000) argue that the term
Critical success factor (CSF) was coined in the
1980s. The fact that some organizations seemed to
be more successful than others caused the
investigation for this. Some factors appeared to be
critical for this success and characterized as critical.
A factor that is critical to the success of the project is
intuitively referred to as a Critical Success factor
(CSF). Therefore, critical success factors (CSFs) are
variables that are fundamental to the success of the
implementation, and an organization must handle
these CSFs well in order to have a successful
implementation (Frimpon, 2011). CSFs are “those
things that must be done if an organization is to be
successful” (Freund, 1988).
A complex technological initiative like an e-
learning deployment is an undertaking involving a
multiplicity of factors that impact the
implementation to varying degrees. In literature for
e-learning there is not much work for critical success
factors.
Drennan et al., (2005) derived measures of
perceptions of technology from research on the
Technology Acceptance Model and used locus of
control and innovative attitude as indicators of an
autonomous and innovative learning mode.
Sela and Sivan (2009) proposed nine success
factors for enterprise-wide e-learning. These factors
are divided into two categories: “must-have” factors
and “nice-to-have” factors. The must-have factors
include: useful and easy to use e-learning tools,
marketing, management support, the right
organizational culture, and the existence of a real
need for the organization. The “nice to have” factors
include: time to learn, support, mandatory learning,
and incentives.
Researchers have identified different CSFs in e-
learning. Volery and Lord (2000) identified
technology, instructor and previous use of
technology from a student’s perspective as the CSFs
in e-learning. More specifically define technology as
the factor that has relation with navigation and easy
of access as well as the interface of the LMS.
Regarding authors they measure attitudes towards
students and classroom interaction. Similarly Soong,
Chan, Chua, and Loh (2001)identified as e-learning
CSFs the human factors, technical competency of
participants, e-learning mindset, collaboration
between participants, and perceived information
technology infrastructure.At the same direction other
studiespropose as CSFs the technology, instructor
characteristics, and student characteristics (Leidner
and Jarvenpaa 1993; Guawardena, 1995).
According to Selim (2007), four CSFs were
identified and measured, namely instructor
characteristics, student characteristics, technology
infrastructure, and university support. Similar is the
approach by Frimpon (2001). Seventeen critical
success factors (CSFs) were obtained through an
exhaustive search, and were partitioned into 4
natural roles of Student, Instructor, Technology, and
Institution. The latter two papers inspired us for this
study.
In this paper, two main objectives have been set.
First, to clarify and categorize the Critical Success
Factors (CSFs) in an LMS from the perspective of
students and then, to investigate the relationships
between these factors, suggesting a new causal
model. 400 students from two departments of the
school of Business and Economy of TEI of East
Macedonia and Thrace were involved. They use the
LMS e-class taking advantage of most of its
features. E-class is installed and functions for almost
two decades in TEI of East Macedonia and Thrace
(former TEI of Kavala).The techniques of simple
descriptive statistics and multivariate analysis
techniques were used.
For the exploratory factor analysis and
descriptive statistics, correlations and reliability
validation, the statistical package SPSS 19 was used.
For the confirmatory factor analysis the structural
equation systems (Structural Equation Modeling -
SEM) with the AMOS software packagewas used.
CSEDU 2016 - 8th International Conference on Computer Supported Education
332
2 APPROACH
2.1 The Proposed Model
Four variables were defined as critical factors in the
proposed model; Instructors' characteristics
(Instructor), Students' characteristics (Student),
Information and Communications Technology
(Technology) and the Support by the school
(Support). Finally to measure the intention of
students to use the e-class, a fifth deterministic
variable (Intention to Use) is used.
A questionnaire that is consisting of 56 questions
was completed by students. The deterministic
variables are the questions of our questionnaire.
After a thorough analysis, the questionnaire
responses show us if the deterministic variables are
suitable to measure the hidden variables and how
they affect the formation of the students' intention in
the adoption and use of an LMS. The analysis of our
model, is focused on the four hidden variables
(factors), each determined by some deterministic
variables.
Figure 2: The Research Model and its Assumptions.
The proposed model, for the acceptance of online
education by students is depicted in Figure 2. The
five variables are: (A1.) Instructors' characteristics,
(A2.) Students' characteristics, (A3.) Information
and Communications Technology, (A4.) The
information technology used by the school
(Support), (A6.) Intention of use of the LMS (e-
class).
In our research, the factor Instructors'
characteristics includes thirteen (13) deterministic
variables (A1.1-A1.13), in order to explore these
characteristics. The deterministic variables A1.1-
A1.7 were adopted by Selim (2007) and were
previously used by Volery and Lord (2000), to
examine the teaching styles. The deterministic
variables A1.8 and A1.9 were adopted by Lim et al.
(2008) to measure the availability of the instructor.
The deterministic variables A1.10-A1.11 were
adopted by the Selim (2007) and were previously
used by Volery and Lord (2000). The deterministic
variables A1.12-A1.13 were adopted by the Selim
(2007) and were previously used by Soong et al.
(2001). The deterministic variables A1.10-A1.13
will be used to verify the relationship of teacher
education through the LMS (e-class).
In order to determine the factor Students'
characteristics, twenty (20) deterministic variables
(A2.1-A2.20) were included. The deterministic
variables A2.1 and A2.2 measure the student's
motivation for use of education through the Internet.
The deterministic variables A2.3-A2.7 measured the
technical ability of the student. The deterministic
variables A2.8 - A2.14 measure the effectiveness of
the content of the course through the Internet as well
as the structure and design as perceived by students.
The deterministic variables A2.15-A2.20 are used, to
measure attitudes and behaviors of students toward
education through Internet. The first fourteen (14)
deterministic variables adopted by Selim (2007) and
the rest of the Lim et al. (2008). The deterministic
variables A2.1-A2.7 had been also previously used
by Soong et al. (2001).
The factor Information and Communications
Technology includes thirteen (13) deterministic
variables (A3.1-A3.13). These will be used to
measure the reliability, richness, consistency and
effectiveness of technology in the school.
The factor Support from the educational
institution was covered by five (5) deterministic
variables (A4.1-A4.5), which were adopted by Selim
(2007) and were used to investigate the effectiveness
and efficiency of technical support by the school,
library services, and the reliability of computer
laboratories.
For the factor Intention to use the e-class, five (5)
deterministic variables (A6.1 - A6.5) were used,
which has also been adopted by Selim (2007), in
order to m1easure the intention of the students to use
e-class. In other words, we want to measure how
willing are the students to follow that kind of
learning that was unknown to them.
2.2 Hypotheses
According to the research model (depicted in Figure
2), the instructors' characteristics, the students'
characteristics, the support and the technology
aresufficient to describe the acceptance of online
education from students' point of view and their
Critical Success Factors for the of Acceptance and Use of an LMS - The Case of e-CLASS
333
intention to use it as well. Therefore, we suggest the
following assumptions:
H1: The technology will positively affect
instructors' characteristics.
H2: The technology will positively affect students'
characteristics.
H3: The technology would have an immediate
positive effect on the intention to use.
H4: The technology will positively influence the
support.
H5: The support will positively affect the
instructors' characteristics.
H6: The support will positively affect students'
characteristics.
H7: The support will have a direct positive effect
on intention to use.
H8: The instructors' characteristics will have a
direct positive effect on intention to use.
H9: The students' characteristics will have a direct
positive effect on intention to use.
2.3 Test of the Research Hypotheses
For the test of research hypotheses, we estimate the
structural part of the research model, which
evaluates the causal relationships among factors that
make up the model. Consequently, the structural part
answers the research hypotheses of the research. The
assessment’s purpose of the overall adaptation of a
model is the degree of determination in the model
that is compatible with the empirical data.
For the implementation of this test, a
confirmatory factor analysis will be performed in a
model, which shows the averages of the variables
that define the conceptual factors. According to
Grapentine (1997, 2000), by using the above model,
allows better management of side effects resulting
from the multicollinearity of the variables that
determine the factors and focus more attention on
the concerned factors and the relationships between
them, despite the deterministic variables that are
used only to measure these factors.
The results of this analysis answer to the research
hypotheses and evaluate accordingly with regard: (a)
the accepted limits of adaptability coefficients, (b)
the recommendations of the modification indices
and (c) the statistical significance of the causal links
(paths of the model).
Based on the updated indices, some variables
were removed so as to maximize the adjustment of
the model. The decision to remove a variable or
relationship or the addition of a relationship, based
on revisions and corrections, reflects the substance.
So, for the redefinition of the model, only the
statistical significance of the relationship must be
taken into account, as well as the recommendations
of modification coefficients that should have such
values that the adaptability indices are within
acceptable limits of the adopted methodology
(Bollen, 1989; Green et al., 1999). In this way,
variables or relationship are deleted, when it is no
longer necessary to maintain the adjustment of the
model.
3 RESULTS
The results of confirmatory factor analysis, as
depicted in Figure 3, according to the statistical
significance of the relationship with the values of
adaptability coefficients suggest removing two
causal relationships of the model and the
simultaneous rejection of corresponding research
hypotheses (H1: technology affects directly and
positively to the formation of instructors'
characteristics, H6: Support directly and positively
affects the students' characteristics).
Figure 3: Schematic confirmatory factor analysis of the
research model (first step).
After removing the two relationships, a
confirmatory factor analysis again is performed. The
results show all the remaining causal relationships,
which are statistically significant (Figure 4).
But according to the modification indices, to
increase the reliability, validity and adaptability of
the model, a new relationship between the factor
instructors' characteristics and the factor students'
characteristics is necessary to insert, as depicted in
Figure 5.
CSEDU 2016 - 8th International Conference on Computer Supported Education
334
Figure 4: Schematic confirmatory factor analysis of the
research model (second step).
Figure 5: Schematic confirmatory factor analysis of the
research model (third step).
After the insertion of the new causal relationship,
taking into account the acceptable margins of the
adaptability coefficients, a generally very good fit of
the data with the concerned model is observed. In
particular, the indices CFI, GFI, RMR and NFI get
value greater than 0.9, which is considered the
threshold of reliability, validity and adaptability to
the data. The value of the index x
2
for the degrees of
freedom to be with less than 3 and the value of
RMSEA index is less than 0.1; these values were
adopted as the upper limit of a fitness model. So,
according to the values of adaptability coefficients,
the model is proved as a valid and reliable model for
analysis of the results and draw conclusions. Figure
5depicts the final proposed model for acceptance
and use of the LMS. It includes also the capacity of
causal relationships between factors that compose it,
and the explained rate fluctuates as well.
Table 1 contains the research hypotheses, as
these were determined during the creation of the
hypothetical research model, as well as a new
research hypothesis which has been added according
to the modification indexes. It also contains the
statistical analysis values, as those were resulted
from the confirmatory factor analysis
Table 1: The research hypotheses of acceptance and use
model of the LMS.
Research Hypotheses Estimate S.E. C.R P
Η1
Instructors'
characteristics
Technology
characteristics
0,133 0,088 1,508 0,132
Η2
Students'
characteristics
Technology
characteristics
0,224 0,057 3,918 ***
Η3
Intention of
use of e-class
Technology
characteristics
0,242 0,049 4,929 ***
Η4
Support
Characteristics
Technology
characteristics
0,523 0,093 5,638 ***
Η5
Instructors'
characteristics
Support
Characteristics
0,169 0,055 3,078 0,002
Η6
Students'
characteristics
Support
Characteristics
0,013 0,042
-
0,302
0,762
Η7
Intention of
use of e-class
Support
Characteristics
0,212 0,032 6,656 ***
Η8
Intention of
use of e-class
Instructors'
characteristics
0,259 0,037 7,018 ***
Η9
Intention of
use of e-class
Instructors'
characteristics
0,252 0,052 4,863 ***
Η10
Students'
characteristics
Instructors'
characteristics
0,208 0,044 4,731 ***
Table 2: Direct, indirect and total normalized effects
between the factors that make up the proposed model of
acceptance and use of LMS (D = Direct, I=Indirect, Τ =
Total Effect).
Technology
characteristics
Support
Characteristics
Instructors'
characteristics
Students'
characteristics
Support
Characteristics
D
0,346
I
T
0,346
Instructors'
characteristics
D
0,198
I
0,068
T
0,068 0,198
Students'
characteristics
D
0,239 0,289
I
0,020 0,057
T
0,259 0,057 0,289
Intention of use
D 0,243 0,321 0,336 0,236
I 0,195 0,080 0,068
T 0,438 0,401 0,404 0,236
In conclusion, table 2 presents the determinant of
direct, indirect and total normalized (in unit) effects
among the factors that comprise the proposed model
for the acceptance and use of the LMS by the
students. The coefficients of the paths can be used to
Critical Success Factors for the of Acceptance and Use of an LMS - The Case of e-CLASS
335
decompose the correlations between the factors,
which form the model of direct and indirect effects,
corresponding to the direct and indirect paths shown
by the arrows of causality model. The indirect effect
of a variable i to variable j, according to the rules of
linear systems, is calculated from the summary of
the coefficients multiplications of all the indirect
paths from i to j.
4 DISCUSSION AND
CONCLUSIONS
As the results from the descriptive and statistical
analysis reported and interpreted above, here we will
report and explain the results from the test of the
hypotheses.
A) The model was initiated, having set these
hypotheses for the relationships between the factors
to be considered together and the intended use of
students on the e-class. However, other cases were
confirmed and others were rejected. Especially, after
the analysis, a new relationship between two factors
derived. More specifically, the relationship between
Technology and Instructors' Characteristics and the
relationship between the Support and Students'
characteristics were rejected. On the other hand, a
new relationship between Instructors' Characteristics
and Students' characteristics arose.
These findings are reasonable, as the technical
background of the instructor is not affected by the
Institute's technology but also the characteristics of
students are not affected by the quality and quantity
of technical support. On the other hand, the
characteristics of students are affected and shaped by
the characteristics of instructors. Every instructor
should be the coach and the advisor of the student.
Generally, the characteristics and the progress of
each student are dependent, to some extent, on the
interactions s/he had with his/her instructors.
B) It is worth noting that the strongest relationship
in our final model, is that between technology and
the support from the school. The weakest is
observed between the support of the educational
institute and instructor's characteristics. This makes
sense because a school as good technical support
has, the better it will be or at least seems to be the
technology to students. And vice-versa, as finer
technology has, the better it will be or at least seems
to students, the technical support. On the other hand,
the only relationship between instructor and support
is when the instructor assumes such responsibility,
i.e. to fix something or help a student to something
relevant.
C) The order of significancy among the five factors,
based on the average of the coefficients are:
students' characteristics, the intention of use, the
technology, the instructors' characteristics and the
support from the school. This result does not agree
with the corresponding conclusion of Lim et al.
(2008), who had found as the most significant factor
the technical support from the school. It agrees, with
Poon et al., (2004), who had also found students'
characteristics, as the most important category.
D) Table 2 can give us enough results worth
interpret. Initially, we observe that the instructor's
characteristics have the strongest direct relationship
with the intention to use. This probably indicates
that the attitude and the knowledge of the instructor
play an important role in the student's intention of
use the LMS. On the other hand, the student's
characteristics are weakest directly related to the
intention of use. His/her own characteristics i.e., no
shape his/her intention as strongly as other external
factors.
Interests are the results of the overall
relationships, namely computing and indirect from
direct. The strongest relationship longer observed
between technology and the intention to use. While
the direct relationship between them was particularly
weak, the indirect was particularly strong with the
result as a whole to have the strongest correlation
model. The so strong indirect relationship, probably
due to the fact that technology is related to all the
factors which affect. We have not to forget that
education through Internet is a methodology that
uses advanced technology. It is worth noting that the
difference of total relationship among factors and
intention of use is small. In particular, the
relationships of intention to use with technology,
students' characteristics, instructors' characteristics
and support are in the same range. It is striking that
the student's characteristics have a significantly
weaker relationship with the intention to use. The
same occurred with the direct relationship. The most
likely explanation in this case is that the student is
more influenced by external factors than by its own
characteristics.
E) In general, we see that the education through
LMS is still at an early investigation stage in Greece.
Nevertheless, students seem willing to walk the new
paths that appear in front of them and adopt the e-
class and other relevant LMSs. The factors affecting
the intent of students are many. Some of them are
definitely the student's and instructor's
characteristics, information technology and technical
CSEDU 2016 - 8th International Conference on Computer Supported Education
336
support from the university. This has also been
noticed by previous studies (Selim, 2007; Volery
and Lord, 2000; Friesen, 2005; Soong et al., 2001)
and now it was confirmed. The relationships
between the factors are influenced by other factors
affecting the students’ intention to use.
F) All the above tables, figures and analysis show
us that the constructed model can be considered
reliable and can fulfil its mission successfully.
It should be noted that the above results related
to the test of hypotheses, largely agree with most
previous studies (Selim, 2006; Volery and Lord,
2000; Al-Fadhli, 2009; Abbad et al., 2009).
Concluding, we point out with some general
remarks. The presented causal model explains 54%
of education acceptance criteria through an LMS.
The strongest relationship in our final model is
between Information Technology and Technical
Support from the school. The weaker relationship is
observed between the Technical Support and
Instructors' Characteristics.The study revealed the
following order of significancy of the five factors
used, according to the average of the responses of
the students; the most significant factors in
descending order are: Students' characteristics,
Intention of use, Technology, Instructors'
characteristics and Technical Support.
However the limitations of the study are the
sample size, the questionnaire size, the objectivity of
the respondents, the level of education through LMS
in Greece, the associative nature of the research and
the adaptability indices of confirmatory factor
analysis.
Suggestions for further research are the repeat of
study with new larger sample, to be applied in other
Universities to confirm the findings of the study.
Since this causal model covers only the 54% of all
the possible factors, there are more factors that have
to be discovered. A twofold evaluation with research
to other entities apart of the students (i.e. proper
questionnaires for teachers, executives of school,
companies of advanced technology) would be
useful.
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