- Email: [email protected]
Relative Efficiency Evaluation on Water Resource Utilization
Journal of Northeast Agricultural University (English Edition)
Sep. 2011
Vol. 18 No. 3 60-64
Relative Efficiency Evaluation on Water Resource Utilization MA Ying School of Agriculture and Forestry Economics and Management, Lanzhou University of Finance and Economics, Lanzhou 730020, China
Abstract: Water resource allocation was defined as an input-output question in this paper, and a preliminary input-output index system was set up. Then GEM (group eigenvalue method)-MAUE (multi-attribute utility theory) model was applied to evaluate relative efficiency of water resource allocation plans. This model determined weights of indicators by GEM, and assessed the allocation schemes by MAUE. Compared with DEA (Data Envelopment Analysis) or ANN (Artificial Neural Networks), the model was more applicable in some cases where decision-makers had preference for certain indicators. Key words: water resource allocation, group eigenvalue method, multi-attribute utility theory, evaluation CLC number: X322
Document code: A
Article ID: 1006-8104(2011)-03-0060-05
and output indicators. Indexes should be chosen in con-
Introduction
formity to two rules: reasonableness and practicability.
As the development of economy, water resources
the model would be too complicated to lose the value
become more and more scarce. Therefore, the ques-
of practicability.
The number of indexes should be concise; otherwise,
tion that how to optimize the allocation of finite water resources attracts extensive attention, but the
Input indicators
past related studies often just highlighted the benefits
There are few researches on input indicators of
and production effects on allocation plans without
water resources distribution. At present, area water
paying enough attention to allocation costs. In this
resource allocation behaviors can be divided into
paper, water resource allocation was defined as
four categories according to its inner mechanism:
an input-output question, and a preliminary input-
configuration by verge costs price, distribution by
output index system was set up. Then GEM (group
administrative management, configuration by water
eigenvalue method)-MAUE (multi-attribute utility
market and allocation by users' demand, so there
theory) model was applied to assess water resource
are main four kinds of water resource configuration
allocation plans. This model determined weights of
resolutions: market configuration, administrative
indicators by GEM, and assessed the allocation
configuration, users participating configuration and
schemes by MAUE.
synthesis configuration[1]. No matter which allocation model it is, each configuration resolution has its own
Evaluation Indexes
configuration cost. How to reckon the allocation costs
Assessment indexes are composed of input indicators
assessment, so further studies on it should be done.
reasonably is very important to the allocation plans'
Received 6 April 2010 MA Ying (1981-), male, lecturer, Master, engaged in the research of population and environmental economics. E-mail: [email protected]
E-mail: [email protected]
·61·
MA Ying. Relative Efficiency Evaluation on Water Resource Utilization
Here, distribution costs are divided into three sub-
assessment model sententious.
indicators: EC, EEC, and UC.
Environmental and ecological costs (EEC)
Economic costs (EC)
EEC is the environmental and ecological sacrifice
Water resource allocation economic costs are the costs
that corresponds to configuration resolutions. There
which can be measured and expressed by currency
are many causes which can induce EEC, and it can
directly during water resource configuration process.
appear in many different forms, which also include the
The constitution of EC varies according to distribution
environmental and ecological losses of areas losing
methods. Except for the costs of water resource
water discussed above. In the early 1990, Colby BG
transfer, transport, store, etc., there are two kinds of
who studied the western water market of America
costs which are easy to be ignored:
yet talked about the environmental and ecological
(1) The costs which are produced during the process
external diseconomy produced by water right transfer
of introducing water rights market, such as information
from agriculture to non-agricultural usages [3], and
collecting fee, institution design fee, corresponding
this external diseconomy was a form of EEC. There
laws, regulations' design and approval fee, water rights
had been researches on the quantification of EEC[4-5];
initial allocation fee, litigation fee caused by con-
here EEC was monetized, and was presented by the
tradictions during the allocation process, the main-
currency equivalent.
tenance and supervision fee of water rights market.
Uncertain costs (UC)
Past assessment studies of the efficiency of water
Because water resource allocation processe is so
rights market configuration often just emphasized that
complicated and uncertain, there will be many random
water market can make the verge benefit of water users
costs which can't be expected beforehand in processes
come to the same level so as to maximize the social
of real configuration assessments; therefore, UC
total welfare, but ignored the relative institutional
indicator is used to describe them.
transfer costs. Laura McCann had pointed out that transaction costs of introducing water right market on
Output indicators
the base of administrative allocation was decided by
According to the principles of reasonability and
the local water resources' own characteristics, related
practicability talked above, roundly considering the
institutions, more comprehensive social institutional
large scale system of the human-ecology and environ-
[2]
environment and interactions among them .
ment-economy involved in water distribution pro-
(2) In the past, evaluations of water resources
cesses, an output indicator system like this (Fig. 1)
transfer from one area to another area, researchers
was set up. The indicator c5 (the degree of satisfaction
often underlined the social, economic, environmental
for water resource allocation) was used to express
and ecological benefits obtained by the area accepting
the fairness and social agreement of water resource
water, but didn't pay enough attention to the side
configurations.
effects for the area losing water. So when the measure of water transfer is taken, direct and indirect economic losses of the area losing water resources should be
GEM-MAUE
credited to EC; its environmental and ecological
These two models, DEA (data envelopment analysis)
sacrifice should be credited to the next indicator EEC.
and ANN (artificial neural networks), needn't fix
Meanwhile, there are some chance costs, time costs
indicators' weights, and just constitute the production
and so on caused by judicial litigations and democratic
frontier by processing indicator values then to evaluate
participations during the configuration process which
the relative efficiency of solutions. Compared with
also should be credited to EC in order to make the
them, GEM-MAUE model in this paper was more http: //publish.neau.edu.cn
·62·
Vol. 18 No. 3 2011
Journal of Northeast Agricultural University (English Edition)
applicable in some cases where decision-makers
possible to develop area economy; but for developed
have special preference for indicators. For example,
areas or some areas where the tourism of natural
in the inchoate period of economy development,
landscapes is regarded as economic polar, they will
on the premise of assuring that the ecological and
pay more attention to the environmental and ecological
environmental status wouldn't degenerate seriously,
qualities. This kind of preference can be expressed by
the decision-makers often use as much water as
weights of indicators.
Output indicator system Economic benefit indicators
Domestic production gross per ton of water (c1)
Area GDP increase rate (c2)
Environmental and ecological indicators Ratio of the water amount used by environment and ecology to the total water amount (c3)
Rate of rivers' water quality reaching standards (c4)
Social benefit indicators
Degree of satisfaction for water resource allocation (c5)
Contribution ratio of scientific progress (c6)
Fig. 1 Output indexes system
Group eigenvalue method (GEM)
ideal expert's scoring vector can make ∑αi become minimum. After fixing the indexes weights vector,
Group eigenvalue method abbreviated as GEM is
MAUT model can be used to assess the relative
[6]
proposed by Professor Qiu . This method fixes the
efficiency of plans in the following.
indicators' weights by constituting experts' judgment matrix, which makes the decision process more simple
Multi-attribute utility theory (MAUT)
and convenient. It includes two steps:
Multi-indicator decision making, also known as multi-
(1) Constructing experts' scoring matrix.
attribute decision making, is an important part of
Let each one of the expert groups score all the in-
multi-objective decision to build the theory, and is
dicators directly so as to form an m×n scoring matrix
mainly used to rank decision making schemes with
(integer m is the number of experts; and integer n is
multiple attribute-indicators. According to MAUT,
the number of indicators):
the result value of every attribute has some utilities
X=(xij)m×n
for decision makers. So the result value of every
Here, xij is the ith expert's scoring value for the jth
attribute can be converted into dimensionless utility
indicator.
value through some utility function relationships. As
(2) Calculating the indicators' weights. T
Make the matrix F=X X, and then figure out the *
utility values are dimensionless, different attributes' utilities can be synthesized into an integrated utility
eigenvector X according to the largest eigenvalue of
value, which makes the result value of multi-attribute
matrix F. At last, normalize the eigenvector to form
quantified completely; then the best plan can be
the indicators' weights vector which is also called
chosen in accordance with the quantification value.
"the ideal expert's scoring vector". Marking the
The idea of multi-attribute analysis is to set up a
intersection angle between a n-dimensional vector and
"super target", whose total utility target U (p1, p2, …,
the ith expert's scoring vector as αi ( i=1, …, m), the
p n) is the largest, (here, p 1, p 2, …, p n are different
E-mail: [email protected]
MA Ying. Relative Efficiency Evaluation on Water Resource Utilization
·63·
attributes). The principle of the method is just as
Mark the standardized decision-making matrix as
[7-8]
follows
B=(bij)m×n, and the weighted standardized decision-
:
Mark the set of multi-attribute decision-making
making matrix as C=(cij)m×n, here cij=wj×bij.
plans as X={x1, x2, …, xm}, the set of indicators as
+ Set c j= max{cij|i=l, 2, …, m}=max{wjbij|i=l, 2, …, m}
P={p1, p2, …, pn}, and the index right weight vector
is figured out by GEM as W={w1, w2, …, wn}, which
+ Here, b j is the ideal value in the jth column of
has been normalized. aij represents the attribute value
matrix B, and then the ideal solution C={c+1, c+2, …,
of plan xi for indicator pj, and A=(aij)m×n is the deci-
c+n} is acquired. The evaluation target value of a plan
sionmaking matrix. Normally, there are different
is defined as the distance between the plan and the
types of indicators, such as cost-based pattern, bene-
ideal point, which is expressed by the sum of error's
fitbased pattern, fixed pattern, interval pattern and
square:
so on. Because there are contradictions among diffe-
= max{bij|i=l, 2, …, m}wj=b+jwj j=1, 2, …, n
n
n
j=1
j=1
di=∑ (cij–c+j)2=∑(wjbij–wjb+j)2
rent types of indicators and they can't be measured together, the decision-making matrix needs standar-
n
=∑ wj2(bij–b+j)2(i=l, 2, …, m)
dizing.
j=1
The indicators proposed in this paper just involved
Obviously, the less the value of di is, the closer
in cost-based patterns and benefit-based patterns.
the plan is to the ideal point, which means the plan
Benefit-based indicators are processed as below:
further close to the ideal plan. Plans should be ranked
bij=
according to the value of di; thus, the relative effi-
min
aij–aj ajmax–ajmin
ciency of plans is obtained.
i=l, 2, …, m; j=1, 2, …, n max
Here, aj
and ajmin are the maximum and minimum
Example
in the jth column, respectively. As for cost-based indicators, they are processed as
A calculation example is established to demonstrate
below:
the using of GEM-MAUE model. Supposing there are five schemes for an area's decision makers to choose,
max
bij=
aj –aij ajmax–ajmin
those plans have different index values which are
i=l, 2, …, m; j=1, 2, …, n
shown in Table 1.
Table 1 Index values of decision-making units Plan
ec (Ten thousand Yuan)
eec (Ten thousand Yuan)
uc (Ten thousand Yuan)
c1 (%)
c2 (%)
c3 (%)
c4 (%)
c5 (%)
c6 (%)
1
100
80
20
30
7
8
80
80
40
2
80
120
5
40
8
10
50
70
60
3
120
60
5
50
6
15
70
75
30
4
60
100
10
30
10
12
85
65
35
5
90
50
25
50
5
7
75
70
50
The above model is applied to assess the plans.
0.155, 0.114, 0.115)T by using GEM model and then
There are five experts (S1, S2, …, S5) who score the
standardize Table 1 to get Table 3.
above nine indicators, and the results are shown in
At last, figure out "d 1=0.0419, d 2=0.0318, d 3=
Table 2.
0.0544, d4=0.0416, and d5=0.0505", so the sequence of *
Get x =(0.093, 0.121, 0.104, 0.100, 0.103, 0.095,
plans is as below: Plan3>Plan5>Plan1>Plan4>Plan2. http: //publish.neau.edu.cn
·64·
Vol. 18 No. 3 2011
Journal of Northeast Agricultural University (English Edition)
Table 2 Experts scoring matrix Item
S1
S2
S3
S4
S5
ec
5
4
2
6
1
eec
7
2
3
8
3
uc
1
7
2
7
3
c1
5
2
3
4
6
c2
2
3
6
7
1
c3
2
5
8
1
3
c4
4
7
7
5
8
c5
2
2
5
8
4
c6
7
2
6
3
5
Table 3 Standardized index values Plan
ec
eec
uc
c1
c2
c3
c4
c5
c6
1
0.333
0.571
0.250
0
0.400
0.125
0.667
1.000
0.333
2
0.667
0.000
1.000
0.500
0.600
0.375
0.667
0.333
1.000
3
0.000
0.857
1.000
1.000
0.200
1.000
0.000
0.667
0.000
4
1.000
0.286
0.750
0.000
1.000
0.625
1.000
0.000
0.167
5
0.500
1.000
0.000
1.000
0.000
0.000
0.333
0.333
0.667
3 Colby B G. Transactions costs and efficiency in western water
Conclusions GEM-MAUE model which is concise and practical suited some situations where people have special
allocation [J]. American Journal of Agricultural Economics, 1990, 72(5): 1184-1192. 4 Loomis J. The economic value of instream flow: methodology and benefit estimates [J]. Environ Manage, 1987, 24: 169-179.
preferences for assessment indexes. Evaluation factors
5 Schluter M, Savitsky A G, McKinney D C, et al. Optimizing
could be chosen, according to the concrete background
long-term water allocation in the Amudarya River delta: a water
of real cases. And the configuration plans should be
management model for ecological impact assessment [J]. Environ-
measured in more comprehensive input-output views.
mental Modelling and Software, 2005, 20(5): 529-545. 6 Qiu W H. An eigenvalue method on group decision [J]. Applied
References 1 Wang H, Wang J H, Qin D Y. Research advances and direction on the theory and practice of reasonable water resources allocation [J]. Advances in Water Science, 2004, 15(1): 123-128.
Mathematics and Mechanics, 1997, 18(11): 1027-1031. 7 Wu W Q, Dong Y M. The ideal solution of multiple decisions [J]. Journal of Kunming Metallurgy College, 1999, 15(4): 62-63. 8 Wu Z N, Cui M, Cao Q. Application of BP artificial neural network
2 McCann L, Easter K W. A framework for estimating the transac-
model in evaluation of water resources utilization [J]. South-to-
tion costs of alternative mechanisms for water exchange and alloca-
north Water Transfers and Water Science & Technology, 2004,
tion [J]. Water Resources Research, 2004, 40(9): 1-6.
2(3): 25-28.
E-mail: [email protected]
Sep. 2011
Vol. 18 No. 3 60-64
Relative Efficiency Evaluation on Water Resource Utilization MA Ying School of Agriculture and Forestry Economics and Management, Lanzhou University of Finance and Economics, Lanzhou 730020, China
Abstract: Water resource allocation was defined as an input-output question in this paper, and a preliminary input-output index system was set up. Then GEM (group eigenvalue method)-MAUE (multi-attribute utility theory) model was applied to evaluate relative efficiency of water resource allocation plans. This model determined weights of indicators by GEM, and assessed the allocation schemes by MAUE. Compared with DEA (Data Envelopment Analysis) or ANN (Artificial Neural Networks), the model was more applicable in some cases where decision-makers had preference for certain indicators. Key words: water resource allocation, group eigenvalue method, multi-attribute utility theory, evaluation CLC number: X322
Document code: A
Article ID: 1006-8104(2011)-03-0060-05
and output indicators. Indexes should be chosen in con-
Introduction
formity to two rules: reasonableness and practicability.
As the development of economy, water resources
the model would be too complicated to lose the value
become more and more scarce. Therefore, the ques-
of practicability.
The number of indexes should be concise; otherwise,
tion that how to optimize the allocation of finite water resources attracts extensive attention, but the
Input indicators
past related studies often just highlighted the benefits
There are few researches on input indicators of
and production effects on allocation plans without
water resources distribution. At present, area water
paying enough attention to allocation costs. In this
resource allocation behaviors can be divided into
paper, water resource allocation was defined as
four categories according to its inner mechanism:
an input-output question, and a preliminary input-
configuration by verge costs price, distribution by
output index system was set up. Then GEM (group
administrative management, configuration by water
eigenvalue method)-MAUE (multi-attribute utility
market and allocation by users' demand, so there
theory) model was applied to assess water resource
are main four kinds of water resource configuration
allocation plans. This model determined weights of
resolutions: market configuration, administrative
indicators by GEM, and assessed the allocation
configuration, users participating configuration and
schemes by MAUE.
synthesis configuration[1]. No matter which allocation model it is, each configuration resolution has its own
Evaluation Indexes
configuration cost. How to reckon the allocation costs
Assessment indexes are composed of input indicators
assessment, so further studies on it should be done.
reasonably is very important to the allocation plans'
Received 6 April 2010 MA Ying (1981-), male, lecturer, Master, engaged in the research of population and environmental economics. E-mail: [email protected]
E-mail: [email protected]
·61·
MA Ying. Relative Efficiency Evaluation on Water Resource Utilization
Here, distribution costs are divided into three sub-
assessment model sententious.
indicators: EC, EEC, and UC.
Environmental and ecological costs (EEC)
Economic costs (EC)
EEC is the environmental and ecological sacrifice
Water resource allocation economic costs are the costs
that corresponds to configuration resolutions. There
which can be measured and expressed by currency
are many causes which can induce EEC, and it can
directly during water resource configuration process.
appear in many different forms, which also include the
The constitution of EC varies according to distribution
environmental and ecological losses of areas losing
methods. Except for the costs of water resource
water discussed above. In the early 1990, Colby BG
transfer, transport, store, etc., there are two kinds of
who studied the western water market of America
costs which are easy to be ignored:
yet talked about the environmental and ecological
(1) The costs which are produced during the process
external diseconomy produced by water right transfer
of introducing water rights market, such as information
from agriculture to non-agricultural usages [3], and
collecting fee, institution design fee, corresponding
this external diseconomy was a form of EEC. There
laws, regulations' design and approval fee, water rights
had been researches on the quantification of EEC[4-5];
initial allocation fee, litigation fee caused by con-
here EEC was monetized, and was presented by the
tradictions during the allocation process, the main-
currency equivalent.
tenance and supervision fee of water rights market.
Uncertain costs (UC)
Past assessment studies of the efficiency of water
Because water resource allocation processe is so
rights market configuration often just emphasized that
complicated and uncertain, there will be many random
water market can make the verge benefit of water users
costs which can't be expected beforehand in processes
come to the same level so as to maximize the social
of real configuration assessments; therefore, UC
total welfare, but ignored the relative institutional
indicator is used to describe them.
transfer costs. Laura McCann had pointed out that transaction costs of introducing water right market on
Output indicators
the base of administrative allocation was decided by
According to the principles of reasonability and
the local water resources' own characteristics, related
practicability talked above, roundly considering the
institutions, more comprehensive social institutional
large scale system of the human-ecology and environ-
[2]
environment and interactions among them .
ment-economy involved in water distribution pro-
(2) In the past, evaluations of water resources
cesses, an output indicator system like this (Fig. 1)
transfer from one area to another area, researchers
was set up. The indicator c5 (the degree of satisfaction
often underlined the social, economic, environmental
for water resource allocation) was used to express
and ecological benefits obtained by the area accepting
the fairness and social agreement of water resource
water, but didn't pay enough attention to the side
configurations.
effects for the area losing water. So when the measure of water transfer is taken, direct and indirect economic losses of the area losing water resources should be
GEM-MAUE
credited to EC; its environmental and ecological
These two models, DEA (data envelopment analysis)
sacrifice should be credited to the next indicator EEC.
and ANN (artificial neural networks), needn't fix
Meanwhile, there are some chance costs, time costs
indicators' weights, and just constitute the production
and so on caused by judicial litigations and democratic
frontier by processing indicator values then to evaluate
participations during the configuration process which
the relative efficiency of solutions. Compared with
also should be credited to EC in order to make the
them, GEM-MAUE model in this paper was more http: //publish.neau.edu.cn
·62·
Vol. 18 No. 3 2011
Journal of Northeast Agricultural University (English Edition)
applicable in some cases where decision-makers
possible to develop area economy; but for developed
have special preference for indicators. For example,
areas or some areas where the tourism of natural
in the inchoate period of economy development,
landscapes is regarded as economic polar, they will
on the premise of assuring that the ecological and
pay more attention to the environmental and ecological
environmental status wouldn't degenerate seriously,
qualities. This kind of preference can be expressed by
the decision-makers often use as much water as
weights of indicators.
Output indicator system Economic benefit indicators
Domestic production gross per ton of water (c1)
Area GDP increase rate (c2)
Environmental and ecological indicators Ratio of the water amount used by environment and ecology to the total water amount (c3)
Rate of rivers' water quality reaching standards (c4)
Social benefit indicators
Degree of satisfaction for water resource allocation (c5)
Contribution ratio of scientific progress (c6)
Fig. 1 Output indexes system
Group eigenvalue method (GEM)
ideal expert's scoring vector can make ∑αi become minimum. After fixing the indexes weights vector,
Group eigenvalue method abbreviated as GEM is
MAUT model can be used to assess the relative
[6]
proposed by Professor Qiu . This method fixes the
efficiency of plans in the following.
indicators' weights by constituting experts' judgment matrix, which makes the decision process more simple
Multi-attribute utility theory (MAUT)
and convenient. It includes two steps:
Multi-indicator decision making, also known as multi-
(1) Constructing experts' scoring matrix.
attribute decision making, is an important part of
Let each one of the expert groups score all the in-
multi-objective decision to build the theory, and is
dicators directly so as to form an m×n scoring matrix
mainly used to rank decision making schemes with
(integer m is the number of experts; and integer n is
multiple attribute-indicators. According to MAUT,
the number of indicators):
the result value of every attribute has some utilities
X=(xij)m×n
for decision makers. So the result value of every
Here, xij is the ith expert's scoring value for the jth
attribute can be converted into dimensionless utility
indicator.
value through some utility function relationships. As
(2) Calculating the indicators' weights. T
Make the matrix F=X X, and then figure out the *
utility values are dimensionless, different attributes' utilities can be synthesized into an integrated utility
eigenvector X according to the largest eigenvalue of
value, which makes the result value of multi-attribute
matrix F. At last, normalize the eigenvector to form
quantified completely; then the best plan can be
the indicators' weights vector which is also called
chosen in accordance with the quantification value.
"the ideal expert's scoring vector". Marking the
The idea of multi-attribute analysis is to set up a
intersection angle between a n-dimensional vector and
"super target", whose total utility target U (p1, p2, …,
the ith expert's scoring vector as αi ( i=1, …, m), the
p n) is the largest, (here, p 1, p 2, …, p n are different
E-mail: [email protected]
MA Ying. Relative Efficiency Evaluation on Water Resource Utilization
·63·
attributes). The principle of the method is just as
Mark the standardized decision-making matrix as
[7-8]
follows
B=(bij)m×n, and the weighted standardized decision-
:
Mark the set of multi-attribute decision-making
making matrix as C=(cij)m×n, here cij=wj×bij.
plans as X={x1, x2, …, xm}, the set of indicators as
+ Set c j= max{cij|i=l, 2, …, m}=max{wjbij|i=l, 2, …, m}
P={p1, p2, …, pn}, and the index right weight vector
is figured out by GEM as W={w1, w2, …, wn}, which
+ Here, b j is the ideal value in the jth column of
has been normalized. aij represents the attribute value
matrix B, and then the ideal solution C={c+1, c+2, …,
of plan xi for indicator pj, and A=(aij)m×n is the deci-
c+n} is acquired. The evaluation target value of a plan
sionmaking matrix. Normally, there are different
is defined as the distance between the plan and the
types of indicators, such as cost-based pattern, bene-
ideal point, which is expressed by the sum of error's
fitbased pattern, fixed pattern, interval pattern and
square:
so on. Because there are contradictions among diffe-
= max{bij|i=l, 2, …, m}wj=b+jwj j=1, 2, …, n
n
n
j=1
j=1
di=∑ (cij–c+j)2=∑(wjbij–wjb+j)2
rent types of indicators and they can't be measured together, the decision-making matrix needs standar-
n
=∑ wj2(bij–b+j)2(i=l, 2, …, m)
dizing.
j=1
The indicators proposed in this paper just involved
Obviously, the less the value of di is, the closer
in cost-based patterns and benefit-based patterns.
the plan is to the ideal point, which means the plan
Benefit-based indicators are processed as below:
further close to the ideal plan. Plans should be ranked
bij=
according to the value of di; thus, the relative effi-
min
aij–aj ajmax–ajmin
ciency of plans is obtained.
i=l, 2, …, m; j=1, 2, …, n max
Here, aj
and ajmin are the maximum and minimum
Example
in the jth column, respectively. As for cost-based indicators, they are processed as
A calculation example is established to demonstrate
below:
the using of GEM-MAUE model. Supposing there are five schemes for an area's decision makers to choose,
max
bij=
aj –aij ajmax–ajmin
those plans have different index values which are
i=l, 2, …, m; j=1, 2, …, n
shown in Table 1.
Table 1 Index values of decision-making units Plan
ec (Ten thousand Yuan)
eec (Ten thousand Yuan)
uc (Ten thousand Yuan)
c1 (%)
c2 (%)
c3 (%)
c4 (%)
c5 (%)
c6 (%)
1
100
80
20
30
7
8
80
80
40
2
80
120
5
40
8
10
50
70
60
3
120
60
5
50
6
15
70
75
30
4
60
100
10
30
10
12
85
65
35
5
90
50
25
50
5
7
75
70
50
The above model is applied to assess the plans.
0.155, 0.114, 0.115)T by using GEM model and then
There are five experts (S1, S2, …, S5) who score the
standardize Table 1 to get Table 3.
above nine indicators, and the results are shown in
At last, figure out "d 1=0.0419, d 2=0.0318, d 3=
Table 2.
0.0544, d4=0.0416, and d5=0.0505", so the sequence of *
Get x =(0.093, 0.121, 0.104, 0.100, 0.103, 0.095,
plans is as below: Plan3>Plan5>Plan1>Plan4>Plan2. http: //publish.neau.edu.cn
·64·
Vol. 18 No. 3 2011
Journal of Northeast Agricultural University (English Edition)
Table 2 Experts scoring matrix Item
S1
S2
S3
S4
S5
ec
5
4
2
6
1
eec
7
2
3
8
3
uc
1
7
2
7
3
c1
5
2
3
4
6
c2
2
3
6
7
1
c3
2
5
8
1
3
c4
4
7
7
5
8
c5
2
2
5
8
4
c6
7
2
6
3
5
Table 3 Standardized index values Plan
ec
eec
uc
c1
c2
c3
c4
c5
c6
1
0.333
0.571
0.250
0
0.400
0.125
0.667
1.000
0.333
2
0.667
0.000
1.000
0.500
0.600
0.375
0.667
0.333
1.000
3
0.000
0.857
1.000
1.000
0.200
1.000
0.000
0.667
0.000
4
1.000
0.286
0.750
0.000
1.000
0.625
1.000
0.000
0.167
5
0.500
1.000
0.000
1.000
0.000
0.000
0.333
0.333
0.667
3 Colby B G. Transactions costs and efficiency in western water
Conclusions GEM-MAUE model which is concise and practical suited some situations where people have special
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preferences for assessment indexes. Evaluation factors
5 Schluter M, Savitsky A G, McKinney D C, et al. Optimizing
could be chosen, according to the concrete background
long-term water allocation in the Amudarya River delta: a water
of real cases. And the configuration plans should be
management model for ecological impact assessment [J]. Environ-
measured in more comprehensive input-output views.
mental Modelling and Software, 2005, 20(5): 529-545. 6 Qiu W H. An eigenvalue method on group decision [J]. Applied
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