Evaluating Mobile Learning Adoption in Higher Education based on
New Hybrid MCDM Models
Ming-Tsang Lu
1
, Gwo-Hshiung Tzeng
1,2
Kua-Hsin Peng
3
and Shu-Kung Hu
4
1
Institute of Project Management, Kainan University, No. 1, Kainan Road, Luchu, Taoyuan 338, Taiwan
2
Institute of Management of Technology, National Chiao Tung University, 1001 Ta-Hsueh Road, Hsinchu 300, Taiwan
3
Institute of Leisure and Recreation Management, Kainan University, No. 1, Kainan Road, Luchu, Taoyuan 338, Taiwan
4
Department of Business and Entrepreneurial Management, Kainan University,
No. 1, Kainan Road, Luchu, Taoyuan 338, Taiwan
Keywords: Mobile Learning, MCDM (Multiple Criteria Decision-Making), DEMATEL, DANP (DEMATEL-based
ANP), VIKOR.
Abstract: This study investigated the mobile learning adoption of evaluation in higher education. Mobile learning is a
new form of learning utilizing the unique of mobile devices. However, students’ readiness for mobile
learning has yet to fully explore in Taiwan. The purpose of this study is to address this issue using a hybrid
MCDM (multiple criteria decision-making) approach that includes the DEMATEL (decision-making trial
and evaluation laboratory) for constructing influential network relationship, DANP (DEMATEL-based
ANP) for finding the influential weights, and VIKOR methods combining the influential weights of DANP
for evaluating the performance gaps in each criterion and then how based on influential network relationship
map (INRM) to reduce gaps for achieving aspiration level. An empirical case as example is illustrated to
show that these hybrid MCDM. By evaluating the influential interrelationships between criteria related to
mobile learning, this approach can be used to solve interdependence and feedback problems, allowing for
greater satisfaction of the actual needs of mobile learning behaviour.
1 INTRODUCTION
This study contributes in higher education in three
ways. First, the adoption of mo-bile learning is
explored from a multi-faceted perspective including
attitude-related behaviors to mobile learning,
perceived behavioral control, and trust-related
behaviors. This implies that university practitioners
should consider these three fac-tors before
employing m-learning. Second, the current study
shows the relative im-portance of perceived
behavior control (i.e., perceptions of internal and
external con-straints on behavior) (Taylor and Todd,
1995) in the decision to adopt mobile learning. That
is, students who are confident with mobile devices
are likely to adopt mobile learning. Hence,
universities need to provide students with training
opportunities about the basic functions and
applications of mobile learning technologies. Lastly,
the current findings reveal that usefulness and ease
of use affect students’ attitude for adopting mobile
learning. Thus, to facilitate the acceptance of mobile
learning, the learning environment should be
perceived as useful and easy to use. A better
understanding of the process of mobile learning
adoption will help researchers and decision makers
work together to implement proper strategies for
mobile learning.
Most of the conventional multi-criteria decision
analysis (MCDA) models cannot handle the analysis
of complex relationships among different
hierarchical levels of criteria. Yet the decision to
adopt mobile learning requires decision model that
does just that. The purpose of the present study is to
address these issues; we develop a hybrid MCDM
model that combines DEMATEL, DANP, and
VIKOR. The hybrid method overcome the
limitations of existing decision models and can be
used to help us analyze the criteria that influence
mobile learning issue. In particular, we use Tai-
wan’s college students as an example to study the
interdependence among the factors that influence the
267
Lu M., Tzeng G., Peng K. and Hu S..
Evaluating Mobile Learning Adoption in Higher Education based on New Hybrid MCDM Models.
DOI: 10.5220/0004389502670271
In Proceedings of the 5th International Conference on Computer Supported Education (CSEDU-2013), pages 267-271
ISBN: 978-989-8565-53-2
Copyright
c
2013 SCITEPRESS (Science and Technology Publications, Lda.)
user behavior of mobile learning in the higher
education as well as evaluate alternative user
behavior processes to achieve the aspired levels of
performance from mobile learning.
2 METHODLOGY
This Section comprises four parts: the first part
presents the DEMATEL technique for building an
influential network relationship; the second part
calculates the influential weights using DANP
(DEMATEL-based ANP); the third, the last part
uses VIKOR to evaluate total accreditation
performance; finally, describes the data collection.
2.1 DEMATEL for Establishing an
Influential Network Relationship
DEMATEL is mainly used to solve complex
problems to clarify their essential nature.
DEMATEL uses matrix and related mathematical
theories (Boolean operation) to calculate the cause
and effect relationships involved in each element.
This technique is widely used to solve various
complex studies, and particularly to understand
complex problem structures and provide viable
problem-solving methods (Tzeng et al., 2007).
DEMATEL is based on the concept of influential
relation map, which can distinguish the
direct/indirect influential relationship of the criteria,
allowing decision-makers to identify the key
criterion for developing strategies for improving
accreditation performance in higher education of this
study.
2.2 Find the Influential Weights using
the DANP
This study not only uses the DEMATEL technique
to confirm the interactive relationship among the
various dimensions/criteria, but also seeks the most
accurate influential weights. This study found that
ANP can serve this purpose. This study used the
basic concept of ANP (Saaty, 1996), which
eliminates the limitations of Analytic Hierarchy
Process (AHP) and is applied to solve nonlinear and
complex network relations (Saaty, 1996). ANP is
intended to solve interdependence and feedback
problems of criteria. This study thus applies the
characteristics of influential weights ANP and
combines them with DEMATEL (call DANP,
DEMATEL-based ANP) to solve these kind of
problems based on the basic concept of ANP. This
approach yields more practical results.
2.3 Evaluating Competitiveness Gaps
using VIKOR
Opricovic and Tzeng (2004) proposed the
compromise ranking method (VIKOR) as a suitable
technique for implementation within MCDM (Tzeng
et al., 2005; Opricovic and Tzeng, 2004; Opricovic
and Tzeng, 2007; Liu and Tzeng, 2012). VIKOR
uses the class distance function (Yu, 1973) based on
the concept of the Positive-ideal (or we adopt the
Aspiration level) solution and Negative-ideal (or we
adopt the Worst level) solution and puts the results
in order. For normalized class distance function it is
better to be near the positive-ideal point (the
aspiration level) and far from the negative-ideal
point (the worst value) for normalized class distance
function.
2.4 Data Collection
Table 1 descripts the framework of dimensions and
criteria. And the data was collected from 32
education experts who understand mobile learning
trend and usage (in consensus, significant
confidence is 96.375%, more than 95%; i.e., gap
error =3.265%, smaller less 5%). Most of the
education experts have teaches more than ten years
in higher education. Expert perspectives on all
criteria within the criteria were collected via
personal interviews and a questionnaire. Expert
elicitation was conducted in Nov., 2012, and it took
60 to70 minutes for each subject to complete a
survey.
Table 1: Framework of dimensions and criteria.
Dimensions Criteria
Attitude-related behaviours
D
1
Relative advantage
C
1
Compatibility
C
2
Complexity
C
3
Perceived behavioural
control D
2
Self-efficacy
C
4
Resource facilitating
conditions C
5
Technology facilitating
conditions C
6
Trust-related behaviours D
3
Disposition to trus
t
C
7
Structural assurance
C
8
Trust belief
C
9
CSEDU2013-5thInternationalConferenceonComputerSupportedEducation
268
3 EMPIRICAL STUDY ANALYSIS
FOR MOBILE LEARNING
ISSUE
In this section, an empirical study is displayed to
illustrate the application of the proposed model for
evaluating and selecting the best method that can
help decision makers to understand how to improve
their evaluations of mobile learning user-behaviour.
3.1 Analysis of Result
In this paper, we confirmed DEMATEL decision-
making structure, and analysed from three
dimensions with 9 criteria of the user-behaviour
perspective on mobile learning. According to the
expert questionnaires, we obtain the total influence
matrix
T of dimensions and criteria shown in Table
2 to Table 3. We find the cognition and opinion from
experts in three dimensions, and the relationship
between the extents of the impact can also be found
which is compared to other dimensions as show in
Table 2.
Table 2: The total effect matrix of
D
T and sum of effects
on dimensions.
D D
1
D
2
D
3
d
i
s
i
d
i+
s
i
d
i-
s
i
D
1
0.827 0.813 0.817 2.457 2.532 4.989 -0.075
D
2
0.888 0.784 0.822 2.494 2.338 4.832 0.156
D
3
0.817 0.741 0.767 2.325 2.406 4.730 -0.081
According to the total influence prominence
()
ii
d+s , “attitude-related behaviours
1
()D ” has the
highest influence of the strength of relationship that
means the most important influencing dimensions;
in addition, “trust-related behaviours
3
()D ” is all the
factors that affect the least degree of other
dimensions. According to the influence relationship
()
ii
ds− , we can also find “perceived behavioural
control
2
()D
” is the highest degree of influence
relationship that affects other dimensions directly.
Otherwise, “trust-related behaviours
3
()D ” is the
most vulnerable to influence that compare with other
dimensions. According to Table 3, we can obtain all
the criteria of the impact of relations with each
criterion. And then, from Table 4 shows the
relationship between the extents of the direct or
indirect influences and compares them with other
criteria. “Technology facilitating conditions
6
()C ” is
the most important considerations criteria; in
addition, “structural assurance
8
()C
” is the influence
of all criteria in the least degree of other criteria.
Furthermore, we can also find in Table 4 that shows
“self-efficacy
4
()C ” is the highest degree of
influence relationship in all the criteria. And,
“technology facilitating conditions
6
()C ”, is the most
vulnerable to impact of criteria that compare with
other criteria.
We use DEMATEL to confirm the influence
relationship with the criteria, and expect to obtain
the most accurate influence weights. The purpose of
DANP is to solve the interdependence and feedback
problems of each criterion (Saaty, 1996). Therefore,
we structure the quality assessment model by
DEMATEL which combination with DANP model
to obtain the influential weight of each criterion as
show in Table 4.
Table 3: The total effect matrix of
c
T
for criteria.
C
1
C
2
C
3
C
4
C
5
C
6
C
7
C
8
C
9
C
1
0.773 0.848 0.901 0.738 0.768 0.978 0.836 0.790 0.919
C
2
0.868 0.827 0.920 0.805 0.816 1.011 0.865 0.804 0.921
C
3
0.802 0.812 0.695 0.656 0.687 0.858 0.734 0.680 0.801
C
4
0.886 0.940 0.911 0.662 0.784 0.979 0.833 0.774 0.902
C
5
0.787 0.857 0.833 0.690 0.617 0.872 0.743 0.704 0.815
C
6
0.920 0.954 0.902 0.778 0.795 0.879 0.859 0.815 0.956
C
7
0.882 0.882 0.863 0.702 0.737 0.941 0.729 0.800 0.925
C
8
0.690 0.698 0.673 0.550 0.580 0.731 0.680 0.541 0.740
C
9
0.885 0.894 0.882 0.728 0.748 0.954 0.871 0.809 0.805
Table 4: The gap evaluation of mobile learning by
VIKOR.
D/C
Local
Weight
Global weight
(DANP)
Mobile learning gap
()
kj
r
D
1
0.348 0.197
C
1
0.329 0.115 0.113
C
2
0.339 0.118 0.213
C
3
0.332 0.116 0.266
D
2
0.322 0.296
C
4
0.300 0.097 0.228
C
5
0.310 0.100 0.366
C
6
0.389 0.125 0.294
D
3
0.331 0.295
C
7
0.331 0.109 0.266
C
8
0.310 0.102 0.338
C
9
0.359 0.119 0.284
Total gaps 0.261
In addition, we can find the critical criteria in
higher education of mobile learning user behaviour
are identified as technology facilitating conditions
6
()C , trust belief
9
()C and compatibility
2
()C .
Furthermore, the influence weights combine with the
DEMATEL technique to assess the priority of
EvaluatingMobileLearningAdoptioninHigherEducationbasedonNewHybridMCDMModels
269
problem-solving based on the gaps identified by
VIKOR method and the influence network
relationship map.
An empirical study involving mobile learning
user behaviour in the multiple stages (intention stage
and adoption stage) are used to evaluate and
improve the total accreditation gaps using the
VIKOR method, as listed in Table 4. Decision
makers can identify problem-solving issues
according to this integrated index, either from the
perspective of the criteria as a whole or from that of
an individual dimension.
Using the overall/dimension criteria, the gap
values can be determined by the priority sequence
improvement for reaching the desired level. In the
intention stage, resource facilitating conditions
5
()C
,
with a higher gap value of 0.366, are the first
criterion to be improved.
Improvement priority can also be applied to the
individual dimension. In the attitude-related
behaviours
1
()D
of the intention stage, for instance,
the priority gap values are ordered as follows:
complexity
3
()C , compatibility
2
()C , relative
advantage
1
()C
. In the perceived behavioural control
2
()D of the intention stage, the priority gap values
are ordered as follows: resource facilitating
conditions
5
()C , technology facilitating conditions
6
()C , self-efficacy
4
()C . In the trust-related
behaviours
3
()D of the intention stage, the
improvement priorities can be sequenced as follows:
structural assurance
8
()C , trust belief
9
()C ,
disposition to trust
7
()C . Using the gap values
provided by the panel experts above, improvement
priority schemes are unique and comprehensive,
both from the separate dimensions and from the
overall points of view, as shown in Table 4.
For decision makers, understanding
improvement priorities of mobile learning user
behavior for client must be easier to understand than
the gaps in higher education.
3.2 Discussions and Implications
The empirical results are discussed as follows. First,
according to the DEMATEL model, we could
recognize the interrelationship of each dimension
and criterion the influential relationship network
map for each dimension and criterion (as Fig. 1
shows). In Fig. 1, the perceived behavioral control
2
()D is affecting other dimensions- attitude-related
behaviors
1
()D , and, trust-related behaviors
3
()D ;
visibly perceived behavioral control
2
()D
plays an
important role and it has the highest and intensity
influence in its relationship to other dimensions.
Thus, higher education leader should first improve
it, then, followed by attitude-related behaviors
1
()D ,
trust-related behaviors
3
()D for evaluating and
improving the mobile learning user behaviors in the
higher education.
Second, after analyzing the dimensions, we
would illustrate the considered-criteria in each
dimension. According to the results, we illustrate the
influence relationship-digraph-map of criteria in Fig.
1. Hence, for the influence relationship of these
criteria, in the attitude-related behaviors dimension
1
()D
: compatibility
2
()C
was the most influence
criterion and should be improved first, followed by
relative advantage
1
()C and complexity (see Fig. 1
for more details on the causal relationship in
1
D
,
2
D ,and
3
D ). Each of the evaluation dimensions and
criteria creates the necessary behaviors for inducing
mobile learning user behaviors in the higher
education. Therefore, high education leader should
evaluate all of the dimensions and criteria for the
mobile learning user behavior in accordance with
Fig. 1. This evaluation method can be used in most
of the higher education. However, school leader
should keep in mind that, when applying this model,
some differences exist. The level of importance for
the 9 criteria may vary according to the particulars
of each high education, and the school leader should
compare the evaluation methods for each mobile
learning user behavior model before making
deciding upon the optimal using adoption method.
Fig. 1: The influential network relationship map of each
dimension and criterion
Finally, the overall gap values (i.e., the distance
to 0) shown in Table 4 that indicate room for
CSEDU2013-5thInternationalConferenceonComputerSupportedEducation
270
improvement are 0.261 in the intention stage, and
0.235 in the adoption stage. In the multiple-stage
perspective, the perceived behavioral control
2
()D ,
featuring the largest gap value of 0.296 in intention
stage, and the trust-related behaviors
3
()D featuring
the largest gap value of 0.295 in adoption stage,
which should be the first priority for improvement if
decision makers wish to achieve the desired level.
For long-term improvement, the decision makers
should manage internal motivation carefully, as
mentioned above. Given these empirical findings,
our results, as holistically formulated in Table 5,
fulfil the purpose of this research. Evaluating the
mobile learning user behaviour model provided by
this study can extend to most higher education using
mobile learning user behaviour. However, school
administrators should be cautious when applying
this model. The importance of the 9 criteria may
vary according to the situation, and administrators
should compare the mobile learning user behavior
and define the gap in that stage before making
decision on optimal technology use.
Table 5: Sequence of improvement priority for mobile
learning user behaviour.
Formula Sequence of
improvement priority
F1:Influential network of
dimensions
2
()
D
,
1
()
D
,
3
()
D
1
()D
:
1
()C
,
2
()C
,
3
()C
2
()D
:
4
()C
,
5
()C
,
6
()C
F2:Influential network of
criteria within individual
dimensions
3
()
D
,
2
()
D
,
1
()
D
F3:Sequence of
dimension to rise to
aspired/desired level (by
gap value, from high to
low)
1
()D
:
3
()C
,
2
()C
,
1
()C
2
()D
:
5
()C
,
6
()C
,
4
()C
3
()D
:
7
()C
,
9
()C
,
8
()C
F1:Influential network of
dimensions
2
()D
,
1
()D
,
3
()D
1
()D
:
1
()C
,
2
()C
,
3
()C
2
()D
:
4
()C
,
5
()C
,
6
()C
4 CONCLUSIONS
Mobile learning service has an important role in the
training of higher education. Its decisions are
complicated by the fact that various criteria are
uncertainty and may vary across the different
product categories and use situations. Based on the
export and literature review, we developed the three
dimensions and 9 criteria that align with the mobile
learning service of environment. So we applied the
methodology of hybrid MCDM model combining
DANP with VIKOR in empirical case. The main
reason is among the numerous approaches that are
available for conflict management, hybrid MCDM is
one of the most prevalent. VIKOR is a method
within MCDM; it is based on an aggregating
function representing closeness to the ideal
(aspiration level), which can be viewed as a
derivative of compromise programming for avoiding
“choose the best among inferior alternatives (i.e.,
pick the best apple among a barrel of rotten apples)”.
In a decision-making process, we used the global
and local weights into alternatives performance,
such as that in Table 5, to allow school leader to
select the best mobile learning adoption factor. We
haven't only selected the best factor, but also found
how to improve the gaps to achieve the aspiration
level in mobile learning service performances.
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