ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL
CURRICULUM MATERIALS BASED ON THE DANP
TECHNIQUE WITH GREY RELATIONAL ANALYSIS
Cheng-Hsiung Chen
Department of Information Management, Kainan University, 1, Kainan Rd., Luchu, Taoyuan 338, Taiwan
Gwo-Hshiung Tzeng
Kainan University, 1, Kainan Rd., Luchu, Taoyuan 338, Taiwan
Keywords: Teaching curriculum materials, MCDM (multiple criteria decision making), DANP (DEMATEL-based
ANP), GRA (grey relational analysis).
Abstract: The core objective of the integrated curriculum of compulsory education is to “enable students to
demonstrate their network-talents instead of just scoring high on independent exams.” The key to
determining education reform strategies in the e-era is to establish network-competence indicators for
educational behavior in primary schools. We propose a MCDM means for evaluating, comparing and
improving the effectiveness of network-competence indicators in various publications that are used for
teaching at the primary school level. The Mandarin Chinese teaching curriculum based on this system is
provided to verify the effectiveness of our method, which may extend to other subject areas.
1 INTRODUCTION
Most countries have made the cultivation of human
talent a priority in the twenty-first century. As other
advanced countries propose education reform,
Taiwan also views education as the bedrock of
national development. Taiwan has implemented
various education reforms, such as preschool
education reform, curriculum reforms for grades 1-9,
the restructuring of secondary education, the
enhancement of higher education, and projects to
promote lifelong learning. This study proposes a set
of techniques and evaluation methods to improve,
reconfigure and select the most appropriate Aspiring
Intelligent Grey Relational Assessment System
(AIGRAS) for improving the teaching materials in
our education system.
Four British educational reform projects have
been implemented since 1990 (DfE, 1991). The
report of the Mayer Committee advised the
Australian Education Council and the Ministers for
Vocational Education, Employment and Training on
employment-related key competencies for post-
compulsory education and training (Mayer, 1992).
The Education Commission of Hong Kong proposed
“Learning is the key to one’s future, and education is
the gateway to our society’s tomorrow” (EC, 2000).
Regardless of the style of educational reform,
key competencies are generally the major concern
for national reforms at the beginning of the twenty-
first century.
The core objective of the Nine-Year Integrated
Curriculum of compulsory education in Taiwan is to
“enable students to demonstrate their network-
talents instead of just scoring high on independent
exams.” The key to determining education reform is
to establish network-competence indicators of
targeted educational standards in primary school and
junior high school (MOE, 2002).
Therefore, in this study, we propose a new
MCDM (multiple criteria decision making) method
for evaluating, comparing and improving the
effectiveness of competence indicators in the various
publications used for curriculum materials in
primary schools. The DANP (DEMATEL-based
ANP) (decision making trial and evaluation
laboratory, DEMATEL; analytic network process,
ANP) influential weights are based on getting the
total relationship/influence-related matrix by
DEMATEL technique, using an MCDM approach to
solve and address the network-relational problems of
299
Chen C. and Tzeng G..
ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL CURRICULUM MATERIALS BASED ON THE DANP TECHNIQUE WITH GREY
RELATIONAL ANALYSIS.
DOI: 10.5220/0003320602990308
In Proceedings of the 3rd International Conference on Computer Supported Education (CSEDU-2011), pages 299-308
ISBN: 978-989-8425-50-8
Copyright
c
2011 SCITEPRESS (Science and Technology Publications, Lda.)
dependence and feedback involving various criteria.
Next, a grey relational analysis (GRA) technique
with DANP influential weights is proposed to
determine and implement the best performance
indicator related to each criterion for improving,
reconfiguring and selecting AIGRAS for the
development of curriculum materials. An empirical
study involving three publishers based on this
system design is provided to verify the effectiveness
of the proposed methods. This design may improve
the efficiency and quality of Mandarin Chinese
teaching curriculum materials; moreover, our work
may also apply to other subject areas.
The remainder of this paper is organized as
follows. In Section 2, AIGRAS for teaching
curriculum materials with MCDM are introduced. In
Section 3, a MCDM method based on the DANP
method is proposed. In Section 4, an empirical study
involving AIGRAS for Mandarin Chinese teaching
materials is presented to demonstrate our proposed
method, and we discuss the results. Finally, in
Section 5, we offer concluding remarks.
2 AIGRAS FOR TEACHING
CURRICULUM MATERIALS
WITH MCDM
In recent decades, competency-based education has
become a major trend, influencing the educational
reform strategies of most governments worldwide.
In the following subsection, we review the related
literatures describing core competencies (CCs) and
the intertwined effects of an assessment system for
teaching materials as a foundation for the
development of a theoretical framework.
2.1 Educational Reform in Taiwan
(MOE, 2002, 2008)
Taiwan must engage in educational reform to meet
the needs of the twenty-first century, respond to
global education reform trends, foster national
competitiveness and boost the overall quality of our
citizens’ lives.
The Ministry of Education (MOE) of Taiwan has
initiated curricular and instructional reforms in
primary school and junior high school education.
These reforms are based on the Action Plan for
Educational Reform approved by the Executive
Yuan of Taiwan. Because the curriculum represents
not only the core of schooling but also the
foundation on which teachers plan learning
activities, the MOE places the greatest emphasis on
the development and implementation of curriculum
reforms for grades 1-9. These timely reforms are
necessary to meet: (1) national development needs
and (2) public expectations with respect to the next
generation.
A major goal of education is to nourish each
student’s mind and character. Every legitimate
government hopes that its school system will
produce outstanding citizens with both a sense of
patriotism and the ability to adopt a global
perspective. In essence, education is a learning
process that helps students explore their potential
and develop their capacity to adapt and improve
their living environments. In this new century, the
following five basic aspects are emphasized and
included in the curricula for grades 1-9:
(1) developing humanitarian attitudes, (2) enhancing
the ability to integrate, (3) cultivating democratic
literacy, (4) fostering both indigenous awareness and
a global perspective, and (5) building a capacity for
lifelong learning.
For both primary schools and junior high
schools, the aim of national education is to teach
students basic networking knowledge and to develop
the capacity for lifelong learning. To cultivate able
citizens, we hope to engender mental and physical
health, vigour and optimism, gregariousness and
helpfulness, intellectual curiosity, reflection,
tolerance, creativity, a positive attitude and a global
perspective. To accomplish this, the curriculum
design of primary school and junior high school
education should focus on the needs and experiences
of students and on developing CCs relevant to
modern citizens. Such CCs are referred to as key
competencies and, as defined by the Mayer
Committee, should: (1) collect, analyze and organize
information; (2) communicate ideas and
information; (3) plan and organize activities;
(4) cooperate with others and help sustain the
group's ability to work; (5) use mathematical
concepts and technologies; (6) solve problems; and
(7) use technology (Mayer, 1992).
In Taiwan, the CCs applicable to curriculum
reforms in grades 1-9 (MOE, 2002) can be
categorized as follows: (1) self-understanding and
exploration of potential; (2) appreciation,
representation, and creativity; (3) career planning
and lifelong learning; (4) expression,
communication, and sharing; (5) respect, care and
teamwork; (6) cultural learning and international
understanding; (7) planning, organizing, and putting
plans into practice; (8) use of technology and
information; (9) active exploration and study; and
(10) independent thinking and problem solving.
CSEDU 2011 - 3rd International Conference on Computer Supported Education
300
With reference to curricular principles, CCs can
be organized into four basic categories: (A) physical,
mental and spiritual mold (1-3); (B) interpersonal
and social relations (4-7); (C) the use of life science
and technology (8); and (D) logical thinking and
reasoning (9-10).
To foster CCs in citizens, the curricula for
primary school and junior high school education
should emphasize three dimensions, including
individual development, community and culture, and
the natural environment. Thus, curricula in grades
1-9 encompasses include seven major learning areas:
(1) Language Arts, (2) Health and Physical
Education, (3) Social Studies, (4) Arts and
Humanities, (5) Science and Technology,
(6) Mathematics, and (7) Integrative Activities.
2.2 AIGRAS with the MCDM Method
“Decision-making is as old as man.” The MCDM
method may be applied for computer-aided learning
(Quaddus, 1997). Most research has concentrated on
evaluating the quality of web-based learning by the
MCDM method (Hwang et al., 2004; Shee & Wang,
2008; Lin, 2010). A MCDM method based on the
DEMATEL technique for evaluating a private
university of science and technology in Taiwan has
been proposed by Tseng (2010).
A MCDM method based on the DEMATEL
technique for assessing Mandarin Chinese teaching
curriculum materials was first proposed by the
authors. MCDM frameworks exist for teaching
curricula so that we can judge the quality of the
teaching materials, but these frameworks are vague,
even if clear CCs are used as the basis for the
criteria. In this paper, we propose an AIGRAS
technique in which the grey relational grade is used
to rank the indices between the performance ratings
of various curriculum materials.
3 A MCDM METHOD BASED
ON THE DANP TECHNIQUE
The structure of the MCDM problem will be derived
using the DEMATEL technique. The priorities of
each determinant are based on the structure derived
by using ANP. The GRA technique will be
leveraged to calculate the degree of alternatives to
be close the aspiring levels. Finally, the assessment
system for obtaining the best teaching curriculum
materials will be derived. In summary, this
evaluation framework consists of four main phases
(see Figure 1).
Figure 1: An analytical framework for the aspiring
assessment systems of teaching materials.
3.1 DANP Technique
The DEMATEL technique was developed by the
Battelle Geneva Institute to analyze complex “world
problems” dealing mainly with interactive man-
model techniques. A second goal was to evaluate
qualitative and factor-linked aspects of societal
problems (Gabus & Fontela, 1972). The
applicability of the method is broad, with
applications ranging from industrial planning and
decision-making to urban planning and design,
regional environmental assessment, the analysis of
global problems, and so forth. This technique has
also been successfully applied in many situations
and contexts, such as creating marketing strategies,
control systems and safety solutions and developing
the competencies of global managers and group
decision-making (Chen et al., 2010; Chiu
et al., 2006; Lee et al., 2009; Li & Tzeng, 2009;
Lin & Wu, 2008; Ou Yang et al., 2008; Wu &
Lee, 2007). Furthermore, a hybrid model combining
the two methods has been widely used in such fields
as e-learning evaluation (Tzeng et al., 2007), airline
safety measurement (Liou et al., 2007), and
innovation policy portfolios for Taiwan's SIP Mall
(Huang et al., 2007).
In this paper, we use DEMATEL not only to
detect complex relationships and build a network
relation map (NRM) of the criteria but also to
calculate the inter-relational influence levels of each
element. We developed/adopted these influence
level values as the basis of the normalization
supermatrix for determining ANP influential weights
of each criterion. To apply DEMATEL, we refined
the definitions based on the above references and
produced new essential definitions, as indicated
below. We based the DEMATEL technique on
graph theory so that we could divide multiple
criteria into cause and effect groups. Directed
influence graphs (also called digraphs) are more
useful than directionless graphs. A digraph typically
represents a communication network-relation or a
domination relationship between individuals.
Suppose that a system contains a set of elements
{
}
12 n
Sss s=
,
,, and that particular pair-wise
relationships are used for modeling with respect to a
mathematical relationship (MR). Next, consider the
ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL CURRICULUM MATERIALS BASED ON THE DANP
TECHNIQUE WITH GREY RELATIONAL ANALYSIS
301
relationship MR as a direct-relation matrix that is
indexed equally in both dimensions using elements
from set S. Then, extract the case for which the
number appears in the cell
(
)
i,j
. If the entry is a
positive integral, it means the ordered pair
(
)
,
ij
s
s
is
in the relationship MR; and its relationship is such
that
i
s
has an effect on
j
s
. The digraph portrays a
contextual relationship between the elements of the
system in which a numeral represents the strength of
influence (Figure 2). The number between factors is
the degree of influence. For example, an arrow from
1
s
to
2
s
represents the fact that
1
s
influences
2
s
and
that its degree of influence is 2. The DEMATEL
method can convert the relationship between the
causes and effects of criteria into an intelligible
network-structural model of the system (Chiu et al.,
2006).
Figure 2: An example of a directed graph.
The pair-wise comparison scale features five
levels, where the scores 0, 1, 2, 3 and 4 represent the
range from “no influence (0)” to “very high
influence (4)” By experts.
11 12 1
21 22 2
12
n
n
nn nn
aa a
aa a
aa a
⎡⎤
⎢⎥
⎢⎥
=
⎢⎥
⎢⎥
⎢⎥
⎣⎦
A
The initial direct-relation matrix
A is the
nn
×
matrix obtained by pair-wise comparisons in terms
of influences and directions between the
determinants in which
ij
a is denoted as the degree to
which the
th
i
determinant affects the
th
j determinant.
The normalized direct-relation matrix
N
can be
calculated from Equation (1) in which all principal
diagonal elements are equal to zero.
z=
N
A
(1)
where
11
11
1maxmax ,max
nn
ij ij
in jn
ji
zaa
≤≤ ≤ ≤
==
⎛⎞
=
⎜⎟
⎜⎟
⎝⎠
∑∑
.
In this case,
N
is called the normalized matrix.
Then, the total relationship / influence-related matrix
T can be obtained
1
()
2
∞
−
=+ ++ = −TNN N NIN
(2)
where
I stands for the identity matrix,
N
is a
direct influence matrix and
ij
nn
x
×
⎡⎤
=
⎣⎦
N
.
2
∞
++
N
N
stands for an indirect influence matrix.
01
ij
x≤<,
01
ij
i
x
<
≤
∑
,
01
ij
j
x
<
≤
∑
and at least one column sum
ij
j
x
∑
or one row sum
ij
i
x
∑
equals 1, but not all;
hence,
lim 0
h
nn
h
×
→∞
=
⎡
⎤
⎣
⎦
N
. The element
ij
t of matrix T
denotes the direct and indirect influences of factor
i
on factor
j .
The row sum
1
n
iij
j
rt
=
=
∑
and column sum
1
n
jij
i
ct
=
=
∑
of the total-relation matrix
T are denoted through
{
}
,, 1,2,,
ij
tij n
⎡⎤
=∈
⎣⎦
T
, then
1
1
1
n
iij
n
j
n
rt
×
=
×
⎡⎤
==⎡⎤
⎢⎥
⎣⎦
⎢⎥
⎣⎦
∑
r
and
1
1
1
n
jij
n
i
n
ct
×
=
×
′
⎡
⎤
⎡⎤
==
⎢
⎥
⎣⎦
⎣
⎦
∑
c
where the vectors
r
and
c
denote
the sums of the rows and columns, respectively.
Suppose that
i
r denotes the row sum of the
th
i
row of matrix
T , and,
j
c denotes the column sum of
the
th
j column of matrix T , when ij= , ()
ii
rc+
represents the index indicating the strength of both
the dispatching and receiving influences.
Furthermore,
(- )
ii
rc is the degree of the central role
that factor
i
plays in the problem. If (- )
ii
rc is
positive, then factor
i
will primarily exert influence
upon the strength of other factors, and if
(- )
ii
rc is
negative, then factor
i
will primarily be influenced
by other factors (Huang et al., 2007; Liou et al.,
2007).
Consequently, the ANP method, a multi-criteria
theory of measurement developed by Saaty (1996),
provides a general framework to deal with decision-
making problems without making assumptions about
the independence of higher-level elements from
lower-level elements and about the independence of
the elements within a level, as in a hierarchy. ANP is
different from traditional MCDM methods (Saaty,
2005). For example, AHP (Analytic Hierarchy
Process), TOPSIS, ELECTRE, et al. usually assume
independence between criteria. ANP is a new theory
that extends AHP to address dependence in feedback
and utilizes the supermatrix approach (Saaty, 2003).
ANP is a more reasonable tool for dealing with
complex MCDM problems in the real world. ANP
features two parts. The first consists of a control
hierarchy or network of criteria and sub-criteria that
control all interactions. The second is a network of
influences among the elements and clusters. A
control hierarchy is a hierarchy of criteria and sub-
criteria for which priorities are derived in the usual
way with respect to the goal of the system being
CSEDU 2011 - 3rd International Conference on Computer Supported Education
302
considered. However, we build the hierarchical
structure of the network relation map (NRM) with
dependency and feedback problems in real situations,
as shown in Figure 3.
Source: Saaty 1996
Figure 3: The control hierarchy.
The analysis of priorities in a system can be
considered in terms of a control hierarchy, with
dependence among its bottom-level alternatives
arranged as a network relation, as shown in Figure 3.
Dependence can occur both within and between
components.
Therefore, a hierarchy structure of NRM for
decision-makers (such as Figure 3) can be derived
by the DEMATEL technique. Based on NRM, a
supermatrix W for ANP as clusters
h
C , 1, ,hm= can
be obtained, where cluster
h
C resides in the h
th
dimension; we assume that
h
C has
h
n elements
(determinants), which we denote as
12
, , ,
h
hh hn
ee e
.
The influences of a given set of elements
(determinants) in a component (dimension) on any
element in the decision system are represented by a
ratio scale priority vector derived from pair-wise
comparisons of the relative importance of one
criterion to another criterion, with respect to the
interests or preferences of the decision-makers. This
relative importance value can be determined using a
scale of 1–9 to represent equal importance to
extreme importance (Saaty, 1996). The supermatrix
is as follows:
1
2
12
12
11 1 2 1 2 1
11
1
1
21
2
2
1
m
m
m
nnmmn
n
n
m
m
mn
11 12 1m
21 22 2m
m1 m2 mm
eeee ee
e
e
e
e
e
e
⎡⎤
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎣⎦
=
CC C
C
C
C
WW W
WW W
W
WW W
A typical entry
ij
W in the supermatrix is called a
block of the supermatrix in the following form,
where each column of
ij
W is a principal eigenvector
of the influence of the elements (determinants) in the
th
i
component of the network on an element
(determinants) in the
th
j component. Some of the
entries may be zero, corresponding to those elements
(determinants) that have no influence.
11 12 1
22 22 2
12
n
j
n
j
nn nn
ii ij
ij ij ij
ij ij ij
ij
ij ij ij
ww w
ww w
ww w
⎡
⎤
⎢
⎥
⎢
⎥
⎢
⎥
=
⎢
⎥
⎢
⎥
⎢
⎥
⎣
⎦
W
After forming the supermatrix, the weighted
supermatrix is derived by precisely transforming the
sum of all columns to unity for normalization. This
step is similar to the concept of the Markov chain in
terms of ensuring that the sum of the probabilities of
all states equals 1. Next, the weighted supermatrix is
raised to limiting powers, such as
lim
θ
θ
→∞
W
, to obtain
the constant values of global priority vectors, or so-
called weights (Huang et al., 2005).
3.2 Grey Relation for Evaluation
Since Deng (1982) proposed the grey theory, related
models have been developed and applied to MCDM
problems. Similar to fuzzy set theory, the grey
theory is a practical mathematical approach that can
be used to deal with systems analysis characterized
by inadequate information. Fields covered by the
grey theory include systems analysis, data
processing, modeling, prediction, decision-making,
and control engineering (Deng, 1985, 1988, 1989;
Tzeng et al., 2002; Tzeng & Tasur, 1994). In this
section, we briefly review the calculation process for
the grey relation model. This research modifies the
definitions used by Chiou and Tzeng (2001). GRA is
used to determine the relationship between two
sequences of stochastic data in a grey system. The
procedure bears some similarity to pattern
recognition technology. One sequence of data is
called the “reference pattern” or “reference
sequence,” and the correlation between the other
sequence and the reference sequence remains to be
identified (Deng, 1986; Tzeng & Tasur, 1994; Wu et
al., 1996). In this study, we use these concepts to
determine how to improve the degree of grey
relations from the performance values to reach the
aspired values for various publishers (called
alternatives) who create textbooks for Taiwanese
school children.
Let the initial relationship matrix
A be a
mn
×
matrix, where there are
m
alternatives and
n
criteria, obtained by surveying the relationships
following normalization, such as
ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL CURRICULUM MATERIALS BASED ON THE DANP
TECHNIQUE WITH GREY RELATIONAL ANALYSIS
303
1
1
1111
** * *
Criteria
Alternatives
(1) ( ) ( )
(1) ( ) ( )
(1)()()
Aspiring value (1) ( ) ( )
jn
jn
kkkk
mmmm
ccc
www
xxxjxn
xxxjxn
xxxjxn
xx xj xn
⎡⎤
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎢⎥
⎣⎦
Therefore, coefficients of grey relation for the
aspiring values are
((), ())
k
x
jx j
γ
∗
min min | ( ) ( ) | max max | ( ) ( ) |
| ( ) ( )| maxmax| ( ) ( )|
kk
kj
kj
kk
kj
xj xj xj xj
xj xj xj xj
ς
ς
∗∗
∗∗
−+ −
=
−+ −
(3)
Then, the grade (degree) of the grey relation is
obtained so that larger is better:
1
(,) ((),())
n
kj k
j
xx w x jx j
γγ
∗∗
=
=
∑
(4)
where the weight
j
w can be obtained by DANP.
4 AN EMPIRICAL STUDY OF
AIGRAS FOR MANDARIN
CHINESE TEACHING
MATERIALS
In this section, an example modified from a real case
will be presented to demonstrate the effectiveness of
the proposed MCDM framework with the DANP
technique including the grey relational assessment.
One empirical example focuses on the experiences
of three leading textbook publishers.
In this case study, we look at Mandarin Chinese
curriculum materials (six textbooks) for primary
school children in grade 1.
4.1 Background (MOE, 2002, 2008)
In the twenty-first century, major changes have
taken place in social, political, economic and
cultural arenas. These changes are both national and
global. Given the drastic changes brought about by
the e-era, most countries have become aware of the
importance of education and culture. Educational
reform in these countries has been carried out to
foster personal potential, to modernize, and to
promote social progress.
After six decades of post-war development,
Taiwan (also called Formosa) has transitioned from
a traditional agricultural society into a modern
industrial society. Political, economic, and cultural
arenas are facing modernization, industrialization
and the technological influences of structural
adjustment and reconstruction in the e-era. Among
the major arenas of reform, the impact of education
reform is one of the most far-reaching and has
extensive implications. It affects national pride,
impacts social consciousness, establishes a new
culture and develops the nation’s competitiveness in
the new century.
With the spread of education and enhancements
in quality of life, Taiwan is becoming an educational
community. However, many problems have emerged
in the development of education over the years, and
delays in solving these problems have made them
even more complex.
In light of this, the Council on Education Reform
of Taiwan was established in September 1994. The
Commission’s report on educational reform and the
development of educational research was presented
in December 1996.
In Taiwan, certain issues were addressed to
enable reform. The influence of educational reform
at both social and personal levels is significant. It is
important to ponder the impact of social change and
carefully consider how the value of the benchmarks
of socio-cultural development may be determined.
This is especially true in the context of educational
reform.
The Council has proposed a comprehensive
proposal for education reform. Given the need to
provide proper education for every student, it is clear
that schools have not paid adequate attention to
disadvantaged students. This has been mainly due to
inappropriate compulsory education of Taiwan,
where an excessively rigid system and curriculum is
coupled with a lack of long-term investment in
resources. As a result of weak educational practices,
many disadvantaged students fail to build a solid
foundation for learning; they are then exposed to
large class sizes and a general lack of timely and
adequate care. Consequently, their performance falls
even further behind that of other students, causing
them to feel insecure about school.
At the convening of the Education Reform
Committee, the MOE of Taiwan proposed
curriculum reforms for grades 1-9 (compulsory
education) (MOE, 2002, 2008). A more detailed
description is in Subsection 2.1.
The Mandarin Chinese curriculum is one of the
curricula included in Language Arts. It is divided
into three stages: grades 1-3, grades 4-6, and grades
7-9.
Based on curricular goals and CCs for grades 1-
9, the goals of the Mandarin Chinese curriculum
included listening, speaking, reading and writing of
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304
languages, as well as developing basic
communication competencies.
Based on the requirements for children's
intellectual development, the numbers of
competence indicators of the Mandarin Chinese
curriculum for each stage are presented below (see
Table 1).
Table 1: Competence indicators for the Mandarin Chinese
curriculum at each stage.
CCs
Stage
Total
1 2 3
D
1
: Physical, mental and spiritual mold
C
1
: Self-understanding and exploration of potential 24 19 18 61
C
2
: Appreciation, representation, and creativity 20 17 17 54
C
3
: Career planning and lifelong learning 9 13 10 32
D
2
: Interpersonal and social relations
C
4
: Expression, communication, and sharing 8 9 12 29
C
5
: Respect, care and teamwork 9 9 13 31
C
6
: Cultural learning and international understanding 6 8 6 20
C
7
: Planning, organizing and putting plans into
practice
7 7 6 20
D
3
: The use of life science and technology
C
8
: Using technology and information 4 11 8 23
D
4
: Logical thinking and reasoning
C
9
: Active exploration and study 8 7 9 24
C
10
: Independent thinking and problem solving 9 8 7 24
Total 104 108 106 318
Data source: MOE, 2002
Based on our chosen analytical framework, CCs
were first selected as determinants. The structure of
the assessment systems for the Mandarin Chinese
teaching materials was then established using
DANP. Then, the influential weights of each
determinant for the decision structure was identified.
The determinants are equivalent to CCs in this
research. The criteria were confirmed as competence
indicators and as determinants for improving
Mandarin Chinese teaching materials. Meanwhile,
the relationships between the determinants, the
DANP derivations of the weight of each
determinant, and the GRA of each determinant were
similarly derived for our case study.
4.2 Structuring NRM and Calculating
the Influential Weights of
Determinants using DANP
The relationships between determinants involving
assessment systems for Mandarin Chinese teaching
materials were surveyed based on the opinions of
teachers in Taiwan who write Mandarin Chinese
textbooks (1/3), have taught Mandarin Chinese in
primary school (1/3), or have taught other subjects in
primary school (1/3). All of the surveyed teachers
were familiar with the assessment protocols for
Mandarin Chinese in schools.
Our proposed assessment system for Mandarin
Chinese will assist publishers in creating better
textbooks and will help to determine which
assessment strategies can best achieve the aspiring
levels of quality of textbooks. Detailed procedures
and results are given below.
Table 2: Rating the CCs’ relationships matrix A for grades
1-3: Mandarin Chinese curricula.
D
1
D
2
D
3
D
4
C
1
C
2
C
3
C
4
C
5
C
6
C
7
C
8
C
9
C
10
D
1
C
1
0.000 3.500 3.375 3.625 3.250 2.250 2.750 2.375 2.875 3.000
C
2
3.250 0.000 2.875 3.000 2.625 2.875 2.750 2.250 2.500 2.375
C
3
3.750 2.375 0.000 2.875 2.625 2.500 3.000 2.750 3.000 3.125
D
2
C
4
3.750 3.250 3.000 0.000 3.250 3.125 3.250 2.750 3.125 3.250
C
5
2.375 3.000 2.125 3.500 0.000 3.500 3.375 2.375 2.750 3.000
C
6
2.625 3.000 2.500 3.250 3.125 0.000 2.875 2.375 2.625 2.625
C
7
2.625 2.625 3.375 3.375 3.375 2.875 0.000 2.750 3.000 3.125
D
3
C
8
2.375 2.500 2.875 3.125 2.375 2.500 3.000 0.000 3.250 3.250
D
4
C
9
3.000 3.000 3.375 3.250 3.000 2.875 3.500 3.125 0.000 3.750
C
10
3.375 3.375 3.125 3.000 2.875 2.625 3.250 2.875 3.875 0.000
Table 3: Results of the CCs’ total relationships matrix T
for grades 1-3: Mandarin Chinese.
D
1
D
2
D
3
D
4
C
1
C
2
C
3
C
4
C
5
C
6
C
7
C
8
C
9
C
10
D
1
C
1
1.1989 1.2839 1.2798 1.3786 1.2721 1.1868 1.3055 1.1287 1.2787 1.3022
C
2
1.1962 1.0744 1.1645 1.2523 1.1539 1.1083 1.2002 1.0342 1.1654 1.1802
C
3
1.2752 1.2146 1.1384 1.3175 1.2173 1.1574 1.2736 1.1063 1.2450 1.2678
D
2
C
4
1.3819 1.3446 1.3369 1.3402 1.3398 1.2754 1.3896 1.1999 1.3542 1.3787
C
5
1.2329 1.2298 1.2038 1.3322 1.1317 1.1851 1.2818 1.0928 1.2346 1.2607
C
6
1.1988 1.1890 1.1737 1.2813 1.1885 1.0379 1.2253 1.0562 1.1897 1.2083
C
7
1.2867 1.2638 1.2847 1.3773 1.2810 1.2097 1.2242 1.1445 1.2880 1.3116
D
3
C
8
1.2067 1.1886 1.1998 1.2927 1.1809 1.1305 1.2441 0.9939 1.2232 1.2419
D
4
C
9
1.3678 1.3436 1.3544 1.4480 1.3390 1.2745 1.4038 1.2172 1.2641 1.4001
C
10
1.3587 1.3351 1.3284 1.4204 1.3162 1.2490 1.3767 1.1927 1.3628 1.2651
The interrelationships between the ten determinants
were deduced using the DANP method in
Subsection 3.1. First, the direct relation matrix
A
was introduced (see Table 2). After that, the direct
relation matrix
A was normalized based on
Equation (1). The total relationship matrix was then
deduced based on Equation (2) (see Table 3).
Finally, the strength of the influence for each
determinant was deduced (see Table 4 and Figure 4).
Table 4: r
i
+c
i
and r
i
-c
i
for the CCs’ total relationships for
grade 1-3: Mandarin Chinese.
r
i
+ c
i
r
i
- c
i
D
1
: Physical, mental and spiritual mold
24.6645(3) -0.4259(4)
C
1
: Self-understanding and exploration of potential 25.3189(5) -0.0886(5)
C
2
: Appreciation, representation, and creativity 23.9970(8) -0.9377(10)
C
3
: Career planning and lifelong learning 24.6777(6) -0.2515(8)
D
2
: Interpersonal and social relations
25.1368(2) -0.1634(3)
C
4
: Expression, communication, and sharing 26.7817(1) -0.0992(6)
C
5
: Respect, care and teamwork 24.6058(7) -0.2351(7)
C
6
: Cultural learning and international understanding 23.5633(9) -0.0659(4)
C
7
: Planning, organizing and putting plans into
practice
25.5963(4) -0.2534(9)
D
3
: The use of life science and technology
23.0685(4) 0.7357(1)
C
8
: Using technology and information 23.0685(10) 0.7357(2)
D
4
: Logical thinking and reasoning
26.0200(1) 0.5977(2)
C
9
: Active exploration and study 26.0180(3) 0.8069(1)
C
10
: Independent thinking and problem solving 26.0219(2) 0.3886(3)
ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL CURRICULUM MATERIALS BASED ON THE DANP
TECHNIQUE WITH GREY RELATIONAL ANALYSIS
305
Figure 4: Causal diagram of the total influential
relationship.
Table 5: Weights of the determinants derived by DANP.
Local Global
D
1
: Physical, mental and spiritual mold
0.3015
C
1
: Self-understanding and exploration of potential
0.3376 0.1018
C
2
: Appreciation, representation, and creativity
0.3312 0.0998
C
3
: Career planning and lifelong learning
0.3312 0.0998
D
2
: Interpersonal and social relations
0.4054
C
4
: Expression, communication, and sharing
0.2656 0.1077
C
5
: Respect, care and teamwork
0.2455 0.0995
C
6
: Cultural learning and international understanding
0.2335 0.0947
C
7
: Planning, organizing and putting plans into
practice
0.2554 0.1035
D
3
: The use of life science and technology
0.0895
C
8
: Using technology and information
1.0000 0.0895
D
4
: Logical thinking and reasoning
0.2037
C
9
: Active exploration and study
0.4959 0.1010
C
10
: Independent thinking and problem solving
0.5041 0.1027
With an appropriate assessment system as the goal,
pair-wise comparisons of the determinants were
calculated based on the total relationship matrix, as
deduced by DEMATEL. Note the interrelationships
between the goals and the directions of arrows,
relationship matrix serves as a set of inputs for ANP.
By implementing ANP, the limit supermatrix
W
can
be calculated.
Weights corresponding to each determinant
(Table 5) are derived accordingly and may be used
to calculate both weighted averages and GRA
scores.
4.3 Compromise Rankings Calculated
using GRA
After the determinants’ weights were calculated
using DANP, the GRA technique introduced for
compromise ranking was applied. Weighted
averages of the six Mandarin Chinese textbooks for
grade 1 of primary school, which were edited by
three leading publishers (Table 6), were also
calculated as comparisons. In general, the calcu-
lation results (Table 7) demonstrated that the same
conclusions are apparent at both the global and local
levels: publisher A
publisher C
publisher B.
Table 6: Satisfaction of grade 1 textbooks.
A
B C
Dimensions Criteria 11
a
12
b
11 12 11 12
D
1
C
1
6.0000 5.7500 5.5000 5.2500 6.2500 6.2500
C
2
6.5000 6.7500 5.5000 7.0000 5.7500 7.2500
C
3
5.7500 4.7500 4.2500 4.5000 6.2500 4.7500
D
2
C
4
6.7500 7.5000 6.0000 6.5000 6.2500 7.2500
C
5
6.7500 6.2500 6.2500 6.5000 6.5000 6.5000
C
6
5.2500 4.0000 4.2500 4.2500 4.0000 4.0000
C
7
5.0000 5.0000 4.5000 4.7500 4.5000 4.2500
D
3
C
8
3.7500 3.7500 4.0000 4.7500 4.5000 4.5000
D
4
C
9
5.0000 5.2500 4.2500 4.2500 4.7500 4.5000
C
10
5.2500 4.7500 4.7500 4.5000 5.0000 6.0000
Note: a::11: the 1
st
Semester of grade 1; b: 12: the 2
nd
Semester of grade 1
Table 7: Grey relations versus weighted average results.
Local Global
A
B C
11
c
12
d
11 12 11 12
D
1
0.3015
0.8003(5) 0.7722(3) 0.7033( 1) 0.7613(2) 0.7998(4)0. 8158(6)
C
1
0.3376 0.1019
0.7895(4) 0.7627(3) 0.7377( 2) 0.7143(1) 0.8182(5)0. 8182(5)
C
2
0.3312 0.0998
0.8491(3) 0.8824(4) 0.7377( 1) 0.9184(5) 0.7627(2)0. 9574(6)
C
3
0.3312 0.0998
0.7627(5) 0.6716(3) 0.6338( 1) 0.6522(2) 0.8182(6)0. 6716(3)
D
2
0.4054
0.7946(6) 0.7872(5) 0.7251( 1) 0.7535(3) 0.7363(2)0. 7686(4)
C
4
0.2656 0.1077
0.8824(4) 1.0000(6) 0.7895( 1) 0.8491(3) 0.8182(2)0. 9574(5)
C
5
0.2455 0.0995
0.8824(6) 0.8182(1) 0.8182( 1) 0.8491(3) 0.8491(3)0. 8491(3)
C
6
0.2335 0.0947
0.7143(6) 0.6164(1) 0.6338( 4) 0.6338(4) 0.6164(1)0. 6164(1)
C
7
0.2554 0.1035
0.6923(5) 0.6923(5) 0.6522( 2) 0.6716(4) 0.6522(2)0. 6338(1)
D
3
0.0895
0.6000(1) 0.6000(1) 0.6164( 3) 0.6716(6) 0.6522(4)0. 6522(4)
C
8
1.0000 0.0895
0.6000(1) 0.6000(1) 0.6164( 3) 0.6716(6) 0.6522(4)0. 6522(4)
D
4
0.2037
0.7034(5) 0.6928(4) 0.6529( 2) 0.6431(1) 0.6821(3)0. 7214(6)
C
9
0.4959 0.1010
0.6923(5) 0.7143(6) 0.6338( 1) 0.6338(1) 0.6716(4)0. 6522(3)
C
10
0.5041 0.1027
0.7143(5) 0.6716(2) 0.6716( 2) 0.6522(1) 0.6923(4)0. 7895(6)
ζ=0.5
0.7603(5) 0.7467(4) 0.6941( 1) 0.7260(2) 0.7368(3)0. 7628(6)
Note: c::11: the 1
st
Semester of grade 1; d: 12: the 2
nd
Semester of grade 1.
4.4 Discussions and Implications
Authoring teaching materials is not an easy task.
There are no straightforward answers to the question
of how teaching materials should be designed to
meet particular criteria and determinants,
considering that textbooks should generally take into
account the relevant curriculum. Very little research
addresses assessment systems for Mandarin Chinese
teaching materials.
In this study, a MCDM framework that
combined the DANP technique and GRA was
proposed to address the aforementioned problems.
We consider the results satisfactory. This MCDM
framework was created to: (a) overcome the issue of
defining the assessment system for teaching
materials, (b) use innovative but traditional MCDM
approaches to resolve the problem of how to define
an assessment system for textbooks, (c) explore the
vague correlations between the determinants of
teaching materials, (d) create target priorities for the
resulting teaching materials, and (e) shape vague
semantic processing issues, such as defining ‘good’
and ‘very good’ assessments.
CSEDU 2011 - 3rd International Conference on Computer Supported Education
306
CCs were selected as determinants for the
assessment system. CCs were then categorized into
four groups and used as criteria for the assessment.
These groups were as follows:
D
1
: Physical, mental and spiritual mold
C
1
: Self-understanding and exploration of
potential
C
2
: Appreciation, representation, and creativity
C
3
: Career planning and lifelong learning
D
2
: Interpersonal and social relations
C
4
: Expression, communication, and sharing
C
5
: Respect, care and teamwork
C
6
: Cultural learning and international
understanding
C
7
: Planning, organizing and putting plans into
practice
D
3
: The use of life science and technology
C
8
: Using technology and information
D
4
: Logical thinking and reasoning
C
9
: Active exploration and study
C
10
: Independent thinking and problem solving
Through application studies, we found the MCDM
model to be relevant and helpful. DANP establishes
a reasonable assessment structure for dealing with
the influence of various criteria. The influence
relationships pertaining to the results (see Figure 4)
were quite reasonable.
(1) The goal of education is to nurture each
student’s mind and character. First, enhancing
“the use of life science and technology” may
strengthen “logical thinking and reasoning” for
students, which then improves “interpersonal and
social relations” and becomes the ultimate goal;
finally, this gives students “the physical, mental
and spiritual dimensions.”
(2) For logical thinking and reasoning,
“active exploration and study” is better than
“independent thinking and problem solving,”
consistent with the well-known point of view of
knowledge management.
(3) For interpersonal and social relations,
starting from “cultural learning and international
understanding” may shorten the mental distance
for the individual; sharing “expression,
communication” should then naturally lead to
improvement in “respect, care and teamwork,”
and “planning, organizing and putting plans into
practice” should be thoroughly examined.
(4) For physical, mental and spiritual mold,
“self-understanding and exploration of potential”
is the benchmark of “career planning and lifelong
learning” and “appreciation, representation, and
creativity.”
DANP suggests a general framework for dealing
with decisions without making assumptions about
the independence of higher-level elements from
lower-level elements and about the independence of
the elements within a typical hierarchy. Therefore,
by defining the assessment system for teaching
materials as illustrated in the paper, DANP is
apparently a more reasonable tool for analyzing
network structures with feedback.
The GRA technique uses a grade of the grey
relation function
(,)
k
x
x
γ
∗
that represents “closeness
to the aspiring level.” The GRA approach in this
paper simply measures the grey relationship of the
alternatives with the aspiring level.
In Table 7, globally, the six volumes for
(,)
k
x
x
γ
∗
are 0.7603, 0.7467, 0.6941, 0.7260, 0.7368, and
0.7628, and the sequences are 5, 4, 1, 2, 3, and 6,
respectively. This means that Book 11 of Publisher
B
≺ Book 12 of Publisher B ≺ Book 11 of
Publisher C
≺ Book 12 of Publisher A ≺ Book 11
of Publisher A
≺ Book 12 of Publisher C.
However, if Publisher B were to improve Book
11, for example, the sequences would be (1) the use
of life science and technology (
3
D
γ
= 0.6164
), (2)
logical thinking and reasoning (
4
0.6529
D
γ
=
), (3)
physical, mental and spiritual mold (
1
0.7033
D
γ
=
),
then (4) interpersonal and social relationships
(
2
0.7251
D
γ
=
).
5 CONCLUDING REMARKS
This paper advances work in the field of teaching
material assessment. In response to current concerns,
we began with Mandarin Chinese. First, a MCDM
framework was proposed to define the determinants
of any set of teaching materials (not exclusively for
Mandarin Chinese). Second, the traditional problem
of the difficulty of defining an assessment system
for teaching materials was resolved using the
MCDM approach. An important conclusion was that
the most important determinants may be the least
influential determinants. We concluded that the
sequence of influence among determinants is as
follows: the use of life science and technology (D
3
)
logical thinking and reasoning (D
4
)
interpersonal and social relations (D
2
) physical,
mental and spiritual mold (D
1
) (see Figure 4).
However, the weighting sequence of determinants is
as follows: interpersonal and social relations (D
2
,
0.405
4
)
physical, mental and spiritual mold (D
1
,
0.301
5
)
logical thinking and reasoning (D
4
,
0.2037)
the use of life science and technology
(D
3
, 0.0895) (see Table 5). Finally, the challenge of
ASSESSMENT MODEL FOR IMPROVING EDUCATIONAL CURRICULUM MATERIALS BASED ON THE DANP
TECHNIQUE WITH GREY RELATIONAL ANALYSIS
307
selecting “rotten apple(s)” when using the traditional
MCDM approach was also addressed based on our
conceptual advances in achieving the aspiring level
for each of the criteria.
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