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Article

Sustainability Assessment of Municipal Infrastructure Projects Based on Continuous Interval Argumentation Ordered Weighted Average (C-OWA) and Cloud Models

School of Civil Engineering, Suzhou University of Science and Technology, Suzhou 215009, China
*
Author to whom correspondence should be addressed.
Sustainability 2023, 15(6), 4706; https://doi.org/10.3390/su15064706
Submission received: 16 January 2023 / Revised: 27 February 2023 / Accepted: 6 March 2023 / Published: 7 March 2023
(This article belongs to the Special Issue Sustainable Management of Transportation Infrastructure Projects)

Abstract

:
The goals of sustainable development are constantly negatively impacted by infrastructure initiatives. The importance of these projects in advancing the economic, social, and civilizational growth of the country will, however, prevent their construction from being stopped. The overall construction of the project is related to the scientific and unbiased assessment of an infrastructure project’s sustainability throughout the decision-making stage. Based on the references documents, this paper establishes an index system for evaluating an infrastructure project’s sustainability from three aspects: environment, economy, and society. In the assessment process, the cloud model was used to describe the various attribute values of infrastructure project sustainability, which achieved the uncertainty measures for infrastructure project sustainability, and a cloud model-based assessment method for infrastructure project sustainability was proposed by modifying the attribute value by the penalty factor. Finally, an assessment method for infrastructure project sustainability based on the cloud model was proposed after the attribute values were modified by using a continuous interval argument ordered weighted average (C-OWA) operator. The model carries out an overall sustainability assessment by generating a synthesized cloud with the weight to calculate the similarity of assessment factors, which takes the randomness, fuzziness, and uncertainty of expert qualitative assessment into account, and uses the analytic hierarchy process (AHP) method and the C-OWA operator to determine the weight of the sustainable index and the aggregation of the expert scoring interval. A case study was conducted to clarify how this strategy was applied. The study provides a valuable and useful tool for the operational stage to assess the achievability of municipal infrastructure projects.

1. Introduction

It is a well-known truth that municipal infrastructure projects are an essential reflection of the nation’s regional modernization since they play a crucial role in generating and sustaining a suitable standard of life [1]. The benefits of these municipal infrastructure projects in terms of flood management, alleviating water shortages, producing renewable energy, ensuring food security, and general economic development have been immense [2,3,4]. However, the advantages come at a steep price. With large-scale infrastructure construction, many problems have arisen: lack of foresight in infrastructure planning [5], investors’ focus on short-term interests and neglect of long-term interests [6], over-emphasis on construction and contempt for maintenance [7], low level of operation [8], degradation of freshwater and soil ecosystems [9,10], soil and river erosion [4,11], and large population resettlements [12]. In addition, infrastructure projects often require significant land use and long-term investment; therefore, it often leads to problems related to noise pollution, ground and water pollution, disturbance to human life and ecosystems, habitat fragmentation, and resources consumption [11].
These problems have not only led to a severe waste of resources but have also impeded the development of municipal infrastructure projects and lost the original intention to improve the living standards of local residents and promote economic development [4,13]. These are concrete manifestations of the sustainability of the project, which are rooted in neglecting to evaluate the sustainability dimension in the feasibility study of a project and the lack of sustainability awareness in these infrastructure-construction and management procedures [14].
The above-mentioned problem is a manifestation of unsustainable municipal infrastructure projects. It can be attributed to the lack of a comprehensive and systematic understanding of the factors involved in the sustainability evaluation of municipal infrastructure projects. In addition, sustainability evaluation of municipal infrastructure projects does not adequately consider the relationship between various factors and lacks a systematic approach to sustainability evaluation [10]. Therefore, it is essential to evaluate the sustainability of infrastructure efforts after they are implemented.
It has also brought the issue of the sustainability of municipal infrastructure projects to the attention of numerous experts and academics. Shen et al. [15] revealed the relative dispersion of project sustainability assessment indicators and helped decision makers to identify the most appropriate solutions based on key assessment indicators (KAIs). This study proposes an alternative method for assessing the sustainability performance of municipal infrastructure projects. Fernandez-Sanchez et al. [16] developed a methodology for identifying, classifying, and defining sustainability indicators and a selected set of indicators based on risk management criteria. In addition, this study highlights the high time and cost problems of the proposed methodology when applied to municipal infrastructure projects in Spain.
Banihashemi et al. [17] identified the critical success factors (CSFs) of the triple bottom line of sustainability (environmental, social, and economic) and proposed project management practices for incorporating sustainability into developing country construction projects after the model had been verified using questionnaire surveys utilizing the analytical technique of partial least squares structural equation modeling (PLS-SEM). According to Aimbavboa et al. [18], the main challenge for sustainable practices in the South African construction industry is the additional cost consumption during construction.
These evaluation methods solve the problem of infrastructure project sustainability evaluation to some extent; however, they mainly focus on one dimension of infrastructure project sustainability or a particular industry, and there is a less systematic evaluation of infrastructure sustainability. At the same time, these evaluation methods are still deficient in measuring and presenting infrastructure project sustainability. Most of them ignore the uncertainty of infrastructure project sustainability, such as fuzziness and randomness. Additionally, most evaluation processes use precise mathematical theory to describe and measure sustainability or classify the evaluation results in a threshold way. The sustainability evaluation often varies from person to person, and the evaluation results have certain randomness and fuzziness.
The cloud model has significant advantages in evaluating things because it handles qualitative concepts and quantitative descriptions in an uncertain way. To reflect the degree of cloud droplet dispersion and the assessment’s actual circumstances, the cloud model was used in the evaluation, this paper uses the amount of entropy ( E n ) to reflect the randomness and fuzziness and combines the expectation ( E x ) and the excess entropy ( H e ) to avoid the fuzziness and uncertainty in the evaluation. Then, the Analytic Hierarchy Process (AHP) and C-OWA operator are used to calculate the weight of the sustainable index and the aggregation of the expert scoring interval. Finally, the overall sustainability has been evaluated using a synthesized cloud which the weights rebirth into to calculate the similarity of the evaluation factor.
The following is an overview of the paper’s main parts: In Section 2, 42 critical factors that affect infrastructure project sustainability are examined through a literature review, and index systems are developed; Section 3 deals with the preliminary questions; Section 4 presents a model for evaluating the sustainability of infrastructure based on cloud model and C-OWA aggregation; Section 5 gives a real-world case study that demonstrates how this approach might be used for municipal infrastructure projects; Section 6 provides discussion and the conclusion.

2. Establishment of Sustainable Indicators

For the duration of an infrastructure project’s life cycle, sustainability indicates urban economic, social, and environmental growth. Science and operations should be considered in the design of the positive, sustainable evaluation index system of municipal infrastructure projects, as well as layered and systematic, qualitative and quantitative, and objective and comprehensive. Evaluation index systems are developed based on the nature of a project and are established as a process from individual to general. Examining the literature and specific case studies and inviting educators are all good ways to obtain the sustainability impact of municipal infrastructure projects. After further consultation with experts, the evaluation index system took availability and maneuverability into consideration. This paper summarized 42 factors affecting infrastructure project sustainability by frequency analysis and theoretical analysis after consultation with experts and combing and summarizing the literature of the infrastructure project sustainability study, as shown in Table 1.
According to Table 1, the classification of indicators can be seen, but the weight of each index in each category and the importance of each index in each specific case is different, so it is necessary to analyze specific issues, use numbers to reflect the importance, and then reflect the sustainability of the project. Entropy is a state parameter that can well reflect the randomness and fuzziness of the concept, so this paper analyzes the parameter values of each index in the specific case by cloud model.

3. Methodology

3.1. Cloud Model

Cloud is the uncertainty transformation model described in language values between a qualitative concept and its numerical representation; or simply, the cloud model is the uncertainty model for qualitative and quantitative interconversion.
Let U be a domain, expressed in exact numbers, and let A be an equivalent qualitative concept in U. For an element X in the domain that is a random instantiation of a concept A, there exists a random number y [ 0 , 1 ] with a stable trend called the degree of determination of X relative to A, i.e., the degree of affiliation. The membership cloud refers to the distribution of membership within the domain, often referred to as the cloud. The cloud is made up of many hazy droplets. As opposed to the cloud droplet, which is a quantitative depiction of the qualitative notion, the cloud’s overall form represents critical features of the qualitative concept. In the generation process of cloud droplets, the qualitative concept is mapped onto a quantitative value to demonstrate uncertainty mapping.
The cloud model represents the primitives in natural language–language values. The mathematical properties of the linguistic values are represented by the numerical features of the cloud—expected E x , entropy E n , and excess entropy H e .
Expectation E x : The most representative point of the qualitative concept as well as the most representative sample of the quantitative concept is thought to be an expectation of the spatial distribution of cloud droplets in the domain.
Entropy E n : The “entropy” concept was first used in thermodynamics as a state parameter and has since been introduced to measure the degree of uncertainty in statistical physics, information theory, complex systems, etc. The cloud model represents qualitative concepts by entropy, which represents their granularity. As entropy increases, the concept becomes more macroscopic. Furthermore, it serves as a measure of the uncertainty of qualitative conceptions, which is dictated by the concepts’ unpredictability and fuzziness. En can be seen as a measure of the qualitative concept’s unpredictability. It reflects the dispersion of cloud droplets that can be interpreted as a qualitative concept. On the other hand, a concept inside a domain space can accept a vast number of cloud droplets. As well as qualitative concepts, it measures the range of cloud droplets that can be accepted by a particular concept. The same numeric feature reflecting randomness and fuzziness will inevitably reflect the relevance of both.
Excess entropy H e : The unpredictability and fuzziness of entropy, which is the level of cohesiveness between cloud droplets, influence the uncertainty measurement of entropy, known as entropy-of-entropy. Excess entropy indicates greater dispersion, randomness, and thickness of the cloud.
Cloud generator (CG) or cloud production algorithm can be implemented through software with modular components or hardware treated with a cure. This research applied the mathematical software MATLAB to implement the cloud generator. By function, cloud generators can be divided into forward cloud generators and backward cloud generators.
Forward Cloud Generator: Forward cloud generators combine the digital features of 3 clouds ( E x , E n , H e ) in a forward, direct process and the number of cloud drops needed, along with the coordinates of each droplet in the domain and the probability of each cloud drop representing the concept. The principle and occurrence are shown in Figure 1.
Backward Cloud Generator: The backward cloud generator puts a model for changing quantitative quantities into qualitative notions into practice. It may transform a certain volume of precise data into a qualitative concept conveyed in a digital feature ( E x , E n , H e ) . The principle and occurrence are shown in Figure 2.
The most prevalent and significant cloud model is the forward cloud. Taking the one-dimensional forward cloud as an example, its algorithm for generating cloud droplets is as follows:
Input: the numerical eigenvalues of the qualitative concept ( E x , E n , H e ) are the digital representation of the cloud model, as well as the number of cloud droplets;
Output: the quantitative value of cloud droplets; that is, the certainty of cloud droplets for qualitative concepts.
Generate the normal random number E n i = N O R M ( E n , H e ) with E n as expectation and H e as variance. E n i is the generating function of the normal random number, with E n as the expectation and H e as the variance;
Generate the normal random number x i = N O R M ( E x , E n i ) with E n as the expectation and E n i as the standard deviation;
Calculate the certainty of x i
μ ( x i ) = e ( x i E x ) 2 2 ( E n i ) 2 ;
Set μ ( x i ) expressed as the conceptual, quantitative certainty of cloud droplets x i ;
Repeat (1)~(4) until a cloud droplet is generated to form a cloud model.

3.2. Continuous Interval Argument Ordered Weighted Average (C-OWA)

Ordered Weighted Average (OWA) operator is mainly used to describe and deal with multi-criteria aggregation problems and form an overall decision function [73]. This conceptualization highlights the importance of OWA weighting vectors for influencing decision-makers’ attitudes [74]. Research on operators has gained significant attention in recent years due to its multi-field and multi-angle nature [75]. The OWA operator was employed in this study to resolve the decision scheme’s ranking difficulty and to condense the judgment-related data.
An OWA operator of n dimension is a mapping f : R n R with the i t h position of a set of order weights w = w 1 , w 2 , , w n such that w j [ 0 , 1 ] , j = 1 , 2 , , n , i = 0 n w i = 1 , and the definition of aggregation function is as follows [73,76]:
f ( a 1 , a 2 , , a n ) = i = 1 n w i b i
where b i is the i-th largest element of the collection of aggregated objects a 1 , a 2 , , a n . OWA is a unified framework for decision-making under uncertainty. The following qualities are required for it to be chosen w [77]: (1) there is an order to the weights; that means w n w 2 w 1 or 0 w 1 w 2 w n ; (2) in summary data, the weights do not depend on the size of the sets but on the order in which they are sorted b 1 , b 2 , , b n and the degree of optimism of the decision maker.
On the basis of this definition, process weight assembling and rank data a i ( i = 1 , 2 , , n ) down sequencing, since a i and w i are non-correlated, w i can be defined in advance as it only relates to the i t h position. Different OWA operators correspond to various weight vectors as a result.
Due to OWA operators only being suitable for the aggregation of discrete data, a new continuous interval data information aggregation operator was proposed [78]:
Let [ a , b ] be the interval number, and f ρ ( [ a , b ] ) = 0 1 d ρ ( y ) d y ( b y ( b a ) ) d y , which ρ : [ 0 , 1 ] [ 0 , 1 ] is a function with the following properties: (1) ρ ( 0 ) = 0 ; (2) ρ ( 1 ) = 1 ; (3) if x > y , then ρ ( x ) ρ ( y ) . Then f is called Continuous Interval Argument Ordered Weighted Average (C-OWA) and ρ is called Basic Unit-interval Monotonic (BUM) function.
This definition defines the interval [ a , b ] of definite uncertainty after the function of the C-OWA operator f ; it is transformed into a deterministic value, which integrates each interval data.
Set the level of optimism among policymakers to λ = 0 1 ρ ( y ) d y ( 0 λ 1 ) , then it can be obtained: f ρ ( [ a , b ] ) = λ b + ( 1 λ ) a . For any BUM function ρ , there is a f ρ ( [ a , b ] ) b . In the special case, if ρ ( y ) = y r ( r 0 ) , then f ρ ( [ a , b ] ) = b + r a r + 1 . Among them, the value of parameter r can express the risk attitude of decision makers. When r = 1 , the decision maker is risk neutral. When r [ 0 , 1 ) , the decision maker is risk preference (optimistic). In addition, when r ( 1 , + ) , the decision maker is risk aversion (pessimism). When different values of r are taken, then (1) r 0 , f ρ ( [ a , b ] ) = b ; (2) r = 1 , f ρ ( [ a , b ] ) = ( a + b ) / 2 ; (3) r + , f ρ ( [ a , b ] ) = a . The computational flow of the C-OWA operator is shown in Figure 3.

4. Establishment of a Sustainability Evaluation Model of Infrastructure Based on the Cloud Model

4.1. Sustainable Evaluation of Municipal Infrastructure Projects Based on the Cloud Model

The digital attributes of the cloud model are introduced in accordance with the characteristics of randomness, fuzziness, and other uncertainties of infrastructure project sustainability, as well as the attribute state preferences of decision-makers in the evaluation process, using the expectation, entropy, and excess entropy to describe the attribute values of infrastructure project sustainability, reflecting the uncertainty measure of infrastructure project sustainability. Combining fuzziness, randomness, and discreteness organically enables the transformation between uncertainty language and quantitative value. The evaluation process is as follows:
(1)
Based on the sustainable development level of each indicator, the importance of each indicator is judged on the basis of dividing the sustainable development level, and the weight of each indicator is determined by applying AHP for a two-by-two comparison;
(2)
The evaluation interval of each secondary evaluation factor is determined by combining expert judgment and expert inquiry, and the C-OWA operator is applied to obtain each index cloud’s digital eigenvalues;
(3)
The cloud model for each primary evaluation factor is generated from the cloud digital features of the secondary evaluation factors;
(4)
In similarity calculation, the digital eigenvalues of the first-order evaluation factor are compared, with each standard sustainability sub-cloud corresponding to the evaluation factor to calculate the similarity;
(5)
We use the similarity of the obtained first-order evaluation factor for overall sustainability assessment.
Figure 4 illustrates the sustainability assessment process in this study.

4.2. Generation of Sustainability Standard Cloud

In order to evaluate, a series of standard clouds need to be pre-set in the system. As a reference for entity evaluation, each standard cloud corresponds to an evaluation factor indicating the corresponding sustainable level. Assuming that the range of sustainable evaluation scores for municipal infrastructure projects is [0, 10], the interval is divided into n sub-intervals [ R min , R max ] , corresponding to their respective levels of sustainability. The calculation of the standard cloud is as follows [79]:
(1)
Calculate the expectation according to the upper R max i and lower R min i of the i interval:
E x i = { R min ( i ) , i = 1 R min ( i ) + R max ( i ) 2 , 1 < i < n ; R max ( i ) , i = n
(2)
Calculate entropy based on the results in (1):
E n i = E x i + 1 E x i 3 ;
(3)
Computational excess entropy H e i = k i .
H e = k reflects the randomness of sustainability, the value should not be too large because the larger the H e , the greater error of E x , the greater the randomness of sustainability, and the more difficult to determine the results. There is currently no extremely developed approach for figuring out the value of H e that can be chosen based on the real circumstance and practical experience.
The forward cloud generator and the semi-cloud generator produce the standard clouds of each evaluation factor in accordance with the cloud model’s identified digital eigenvalues ( E x , E n , H e ) (rising and falling clouds).

4.3. Cloud Processing of Attribute Values

In evaluating the sustainability of municipal infrastructure projects, experts can often only give qualitative knowledge of each attribute because it is difficult to provide the digital eigenvalues of the cloud directly. Therefore, this paper adopts the group decision-making method. The expert individual gives the score interval number of the attribute value and then transforms the clustered interval number into the cloud model. The specific steps of the algorithm are as follows:
Step 1: According to the actual situation of the project, the experts give the evaluation interval of the attribute on the domain [0, 10] in the light of a certain scale;
Step 2: The C-OWA operator is used to assemble the evaluation interval number of each expert;
Step 3: Using the OWA operator for integration based on Step 2, the assembly interval number is obtained;
Step 4: The resulting assembly interval number is transformed into the cloud model.
In Step 3, the OWA operator is slightly modified as follows: sort according to the numerical size obtained in Step 2, but when the OWA operator is integrated, the interval number is used as the basic data of operation. The addition and multiplication operations involved are defined as follows:
If the interval number is [ a , b ] and [ n , m ] , τ R + , the addition and multiplication of the interval number are determined as follows:
[ a , b ] [ n , m ] = [ a + n , b + m ] ;
τ [ a , b ] = [ τ a , τ b ] .
The calculation method of transforming the interval number into the cloud model in step (4) are as follows: Use the Formula (1) to calculate the expectation E x i ; calculate the entropy and the excess entropy according to the formulas E n = R max R min 6 and H e i = k .

4.4. Formation of First-Order Assessment Factor Cloud

After the cluster interval number obtained from the C-OWA operator is transformed into a cloud model, the digital eigenvalue of the secondary evaluation factor can be calculated first with the help of the synthesized cloud theory in the virtual cloud, and then the calculated digital eigenvalue can be used to generate the Cloud Model of each primary evaluation factor. The formula is as follows:
{ E x = E x 1 × E n 1 × ω 1 + E x 2 × E n 2 × ω 2 + + E x n × E n n × ω n E n 1 × ω 1 + E n 2 × ω 2 + + E n n × ω n E n = E n 1 × ω 1 + E n 2 × ω 2 + + E n n × ω n H e = H e 1 × E n 1 × ω 1 + H e 2 × E n 2 × ω 2 + + H e n × E n n × ω n E n 1 × ω 1 + E n 2 × ω 2 + + E n n × ω n .
Among them, the expectation of each secondary evaluation factor is E x 1 , E x 2 , ……, E x n , the entropy of each secondary evaluation factor is E n 1 , E n 2 , ……, E n n , the super entropy of each secondary evaluation factor is H e 1 , H e 2 , ……, H e n , and n is the number of secondary factors under this primary evaluation factor.

4.5. Comprehensive Evaluation of the Sustainability of Municipal Infrastructure Projects

In order to better evaluate the sustainability of municipal infrastructure projects, economic, social, and environmental aspects of municipal infrastructure projects can be evaluated separately by the following process.
Using the Formula (7), the numerical eigenvalues of the first-order evaluation factor ( E x , E n , H e ) are obtained, compared with the standard sustainability sub-cloud of the evaluation factors, and the similarity is calculated to find the standard sub-cloud that is closest to it. The sustainability level corresponding to the standard sub-cloud is the entity’s sustainability level.
Respectively, set the synthesized cloud and standard cloud as M Y C 1 ( E x 1 , E n 1 , H e 1 ) and M Y C 2 ( E x 2 , E n 2 , H e 2 ) . The satisfaction cloud M Y C 1 was passed through the forward cloud generator of the Cloud Model to generate a cloud droplet x i . If the determination of x in the satisfaction cloud M Y C 2 is μ , the mean is the similarity of the satisfaction cloud M Y C 1 and the satisfaction cloud M Y C 2 , recorded as δ .
Input: M Y C 1 ( E x 1 , E n 1 , H e 1 ) , M Y C 2 ( E x 2 , E n 2 , H e 2 ) ;
Output: output δ (the resemblance between the synthesized cloud and the standard cloud).
The specific steps of the algorithm are as follows:
(1)
A random normal number with E n 1 as expectation and H e 1 as standard deviation is generated in the synthesized cloud M Y C 1 ;
E n 1 = n o r m r n d ( E n 1 , H e 1 2 )
(2)
A random normal number with E x 1 as expectation and E n 1 as standard deviation is generated in the synthesized cloud M Y C 1 ;
X 1 = n o r m r n d ( E x 1 , E n 1 2 )
(3)
The determination degree is calculated by substituting X 1 into the standard cloud M Y C 2 ;
μ i = e ( x i E x ) 2 2 ( E n i ) 2
(4)
Repeat steps 2 and 3 until n determinations ( μ i ) are generated;
(5)
Calculation of similarity:
δ = 1 n μ i .
The calculated synthesized cloud and standard cloud are calculated for cloud model similarity to find the highest grade of similarity. The overall sustainability is then evaluated using the similarity of the obtained first-level evaluation factor, and the certainty ( π j ) of the j th evaluation grade for infrastructure project sustainability is calculated, with the largest evaluation grade being the final overall sustainability evaluation grade for the infrastructure project.
π j = δ i j × ω i

5. Case Analysis

Take the Second Ring Road Expressway renovation project in City A as an example. The total length of the Second Ring Road Expressway project is 65.31 km, with a total investment of approximately RMB 22.39 billion, of which the construction cost is approximately RMB 17.89 billion (approximately RMB 15.83 billion for main works and RMB 2.06 billion for ancillary works). The project is divided into 14 tender sections. The main works include 13 interchanges, 6 river bridges, 12 cross-line bridges, 45 flyovers, and 2 graben passages. According to the actual situation of the project, the relevant government departments used the AHP method to determine the weight of each sustainable index of the project according to the real situation of the project and then evaluated each index based on the C-OWA operator. Five decision-making experts were first engaged in rating the sustainability indicators of the project based on actual project information, as shown in Table 2.
The decision-making steps are as follows:
Step 1: Evaluation factor standard cloud generation
This stage categorizes infrastructure sustainability into four categories: excellent, good, medium, and bad. The corresponding scoring interval and cloud model digital eigenvalues are shown in the table. Let the rating interval with the optimal sustainability grade be [9, 10], the desired value ex is 10 according to Formula (3), the entropy is 0.5 according to Formula (4), and the excess entropy value is 0.05. In the same way, the numerical eigenvalues of the sustainable evaluation grade are good, medium, and poor. As shown in Table 3.
Step 2: Use the C-OWA operator to find the aggregation interval
This step combines the indicators of the five invited experts rated based on years of engineering experience. The experts are conservative in the sustainable assessment of the project, so the BUM function is taken as ρ ( y ) = y 2 . The interval after aggregation is indicated by [A, B], as shown in Table 4.
Step 3: Cloud processing of attribute value
Cloud processing is carried out for the evaluation interval after aggregation; that is, the eigenvalue of the cloud model ( E x , E n , H e ) is obtained according to the above formula, as shown in Table 5.
Step 4: Use the weight in Table 2 to generate a synthesized cloud of first-level evaluation factors, as shown in Table 6. The MATLAB 2016a software processing is undertaken according to the data in Table 6, and the specific code is shown in Table 7. The sustainability synthesized cloud is shown in Figure 5.
Step 5: Calculation of evaluation factor similarity
The similarities with the respective standard cloud are calculated based on the economic, social, and environmental sustainability cloud models in Table 6, and the results are shown in Table 8.
As can be seen from Table 8, the economic sustainability of the project is medium, the social sustainability is medium, and the environmental sustainability is medium, but the degree of its affiliation to the good is also high, which can be regarded as the upper middle.
Step 6: Overall sustainability assessment of the project
Using the Formula (12), the overall sustainability assessment of the project is as follows, as shown in Table 9:
The infrastructure project has the highest overall sustainability level of medium membership. However, the degree of its subordinate to good is also high, so its sustainability grade should be upper middle.

6. Discussion and Conclusions

Various initiatives in municipal infrastructure projects are having a negative impact on the goal of sustainable development. Nevertheless, these projects will continue to grow because they are essential for the economic, social, and environmental development of the country. Therefore, this study develops a comprehensive sustainability evaluation indicator system for the operational phase of municipal infrastructure projects that considers three aspects: environmental, economic, and social. This research proposes a novel hybrid evaluation method that combines cloud modeling theory with AHP and C-OWA operators to analyze and evaluate the sustainability of municipal infrastructure projects. As a result of this approach, the AHP method and the C-OWA operator are used to determine the weights of sustainability indicators and the aggregation of expert scoring intervals to eliminate the problems associated with randomness, ambiguity, and uncertainty in expert qualitative evaluations. The cloud model theory describes various attributes related to the sustainability of municipal infrastructure projects to measure the degree of uncertainty associated with such projects. By modifying the attribute values with penalty factors, this study proposes a cloud model-based evaluation method for the sustainability of municipal infrastructure projects, and then evaluates the overall sustainability of such projects. To demonstrate its feasibility, this paper illustrates the application of this evaluation system and strategy using the Second Ring Expressway Improvement Project in City A as an example. The indicator system proposed in this paper can facilitate a comprehensive analysis of the sustainability of municipal infrastructure in facility projects. In addition, it can help solve the problem of ambiguous expert scores due to different levels of knowledge and working experience, and effectively balance the different needs of quantitative and qualitative indicators. The final evaluation of the improved municipal infrastructure projects can also visualize environmental, economic, and social sustainability levels.
This research can be used as a reference for future municipal infrastructure projects in establishing sustainability evaluation and indicator systems. However, there are still some limitations. First, this paper attempts to assess the sustainability of municipal infrastructure projects from a macro perspective, so there is still room for further improvement in terms of specific indicators. In addition, the specific focus of sustainability assessment varies from country to country and region to region. Since this paper is conducted in the context of China, it is difficult to verify the extent of its evaluation methodology. Therefore, it is recommended that in future research, more attention should be paid to refining sustainability indicators for municipal infrastructure projects so that they can be more widely applied.

Author Contributions

Conceptualization, X.L. and Z.X.; methodology, X.L. and Z.X.; formal analysis, S.C. and Z.D.; investigation, Z.D. and S.C.; data curation, X.L.; writing—original draft preparation, Z.X.; writing—review and editing, X.L.; supervision, X.L. All authors have read and agreed to the published version of the manuscript.

Funding

Philosophy and Social Science Research in Colleges and Universities in Jiangsu Province (No. 2020SJA1394); Fundamental Research Funds for the Central Universities (No. 331711105); Jiangsu Provincial Construction System Science and Technology Project of Housing and Urban and Rural Development Department (No. 2017ZD074); Postgraduate Research & Practice Innovation Program of Jiangsu Province (SJCX22_1568).

Institutional Review Board Statement

Ethical review and approval were waived for this study due to this study not involving biological human experiment and patient data, which was not within the scope of the review by the Institutional Review Board of Suzhou University of Science and Technology.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

The data presented in this study are available on request from the corresponding author.

Acknowledgments

The authors would like to thank the reviewers for all helpful comments.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Wu, Y.; Guo, L.; Xia, Z.; Jing, P.; Chunyu, X. Reviewing the Poyang Lake Hydraulic Project Based on Humans’ Changing Cognition of Water Conservancy Projects. Sustainability 2019, 11, 2605. [Google Scholar] [CrossRef] [Green Version]
  2. Liu, J.; Zang, C.; Tian, S.; Liu, J.; Yang, H.; Jia, S.; You, L.; Liu, B.; Zhang, M. Water conservancy projects in China: Achievements, challenges and way forward. Glob. Environ. Chang. 2013, 23, 633–643. [Google Scholar] [CrossRef] [Green Version]
  3. McManamay, R.A.; Parish, E.S.; DeRolph, C.R.; Witt, A.M.; Graf, W.L.; Burtner, A. Evidence-based indicator approach to guide preliminary environmental impact assessments of hydropower development. J. Environ. Manag. 2020, 265, 110489. [Google Scholar] [CrossRef]
  4. Mosaffaie, J.; Salehpour Jam, A. Economic assessment of the investment in soil and water conservation projects of watershed management. Arab. J. Geosci. 2018, 11, 368. [Google Scholar] [CrossRef]
  5. Valdes-Vasquez, R.; Klotz, L.E. Social sustainability considerations during planning and design: Framework of processes for construction projects. J. Constr. Eng. Manag. 2013, 139, 80–89. [Google Scholar] [CrossRef]
  6. Li, H.; Zhang, X.; Ng, S.T.; Skitmore, M.; Dong, Y.H. Social Sustainability Indicators of Public Construction Megaprojects in China. J. Urban Plan. Dev. 2018, 144, 04018034. [Google Scholar] [CrossRef] [Green Version]
  7. Jang, W.; Lee, S.K.; Han, S.H. Sustainable Performance Index for Assessing the Green Technologies in Urban Infrastructure Projects. J. Manag. Eng. 2018, 34, 04017056. [Google Scholar] [CrossRef]
  8. Zhu, Q.-Y.; Fang, G.-H. Evaluation index system for positive operation of water conservancy projects. Water Sci. Eng. 2009, 2, 110–117. [Google Scholar]
  9. Wang, H.; Yang, Z.; Saito, Y.; Liu, J.P.; Sun, X. Interannual and seasonal variation of the Huanghe (Yellow River) water discharge over the past 50 years: Connections to impacts from ENSO events and dams. Glob. Planet. Chang. 2006, 50, 212–225. [Google Scholar] [CrossRef]
  10. Chen, A.; Wu, M.; Chen, K.-Q.; Sun, Z.-Y.; Shen, C.; Wang, P.-Y. Main issues in research and practice of environmental protection for water conservancy and hydropower projects in China. Water Sci. Eng. 2016, 9, 312–323. [Google Scholar] [CrossRef]
  11. Yang, S.L.; Milliman, J.D.; Li, P.; Xu, K. 50,000 dams later: Erosion of the Yangtze River and its delta. Glob. Planet. Chang. 2011, 75, 14–20. [Google Scholar] [CrossRef]
  12. Chang, X.; Liu, X.; Zhou, W. Hydropower in China at present and its further development. Energy 2010, 35, 4400–4406. [Google Scholar] [CrossRef]
  13. Pohlner, H. Institutional change and the political economy of water megaprojects: China’s south-north water transfer. Glob. Environ. Chang. 2016, 38, 205–216. [Google Scholar] [CrossRef]
  14. Yu, M.; Wang, C.; Liu, Y.; Olsson, G.; Wang, C. Sustainability of mega water diversion projects: Experience and lessons from China. Sci. Total. Environ. 2018, 619, 721–731. [Google Scholar] [CrossRef]
  15. Shen, L.; Wu, Y.; Zhang, X. Key assessment indicators for the sustainability of infrastructure projects. J. Constr. Eng. Manag. 2011, 137, 441–451. [Google Scholar] [CrossRef] [Green Version]
  16. Fernández-Sánchez, G.; Rodríguez-López, F. A methodology to identify sustainability indicators in construction project management—Application to infrastructure projects in Spain. Ecol. Indic. 2010, 10, 1193–1201. [Google Scholar] [CrossRef]
  17. Banihashemi, S.; Hosseini, M.R.; Golizadeh, H.; Sankaran, S. Critical success factors (CSFs) for integration of sustainability into construction project management practices in developing countries. Int. J. Proj. Manag. 2017, 35, 1103–1119. [Google Scholar] [CrossRef]
  18. Aigbavboa, C.; Ohiomah, I.; Zwane, T. Sustainable Construction Practices: “A Lazy View” of Construction Professionals in the South Africa Construction Industry. Energy Procedia 2017, 105, 3003–3010. [Google Scholar] [CrossRef]
  19. Diaz-Sarachaga, J.M.; Jato-Espino, D.; Castro-Fresno, D. Application of the Sustainable Infrastructure Rating System for Developing Countries (SIRSDEC) to a case study. Environ. Sci. Policy 2017, 69, 73–80. [Google Scholar] [CrossRef] [Green Version]
  20. Shen, H.; Huang, Y.; Tang, Y.; Qiu, H.; Wang, P. Impact Analysis of Karst Reservoir Construction on the Surrounding Environment: A Case Study for the Southwest of China. Water 2019, 11, 2327. [Google Scholar] [CrossRef] [Green Version]
  21. Liang, Y.; Wang, Y.; Zhao, Y.; Lu, Y.; Liu, X. Analysis and Projection of Flood Hazards over China. Water 2019, 11, 1022. [Google Scholar] [CrossRef] [Green Version]
  22. Ding, J.; Zhai, W.; Hu, L. Measuring the Value of Farmland-Elevating Engineering in the Reservoir Area of a Key Water Conservancy Project in China. Water 2018, 10, 658. [Google Scholar] [CrossRef] [Green Version]
  23. Chen, Y.; Lin, P. The Total Risk Analysis of Large Dams under Flood Hazards. Water 2018, 10, 140. [Google Scholar] [CrossRef] [Green Version]
  24. Khan, K.; Depczyńska, K.S.; Dembińska, I.; Ioppolo, G. Most Relevant Sustainability Criteria for Urban Infrastructure Projects—AHP Analysis for the Gulf States. Sustainability 2022, 14, 14717. [Google Scholar] [CrossRef]
  25. El-Kholy, A.M.; Akal, A.Y. Proposed Sustainability Composite Index of Highway Infrastructure Projects and Its Practical Implications. Arab. J. Sci. Eng. 2020, 45, 3635–3655. [Google Scholar] [CrossRef]
  26. Laali, A.; Nourzad, S.H.H.; Faghihi, V. Optimizing sustainability of infrastructure projects through the integration of building information modeling and envision rating system at the design stage. Sustain. Cities Soc. 2022, 84, 104013. [Google Scholar] [CrossRef]
  27. Mathew, L.; Varghese, R. Factors influencing sustainability of infrastructure projects. Int. J. Sci. Eng. Res. 2014, 4, 14–17. [Google Scholar]
  28. Dobrovolskienė, N.; Tamošiūnienė, R. An index to measure sustainability of a business project in the construction industry: Lithuanian case. Sustainability 2016, 8, 14. [Google Scholar] [CrossRef] [Green Version]
  29. Chan, M.; Jin, H.; van Kan, D. Assessment of driving factors for sustainable infrastructure development. Resour. Conserv. Recycl. 2022, 185, 106490. [Google Scholar] [CrossRef]
  30. Dabirian, S.; Khanzadi, M.; Taheriattar, R. Qualitative Modeling of Sustainability Performance in Construction Projects Considering Productivity Approach. Int. J. Civ. Eng. 2017, 15, 1143–1158. [Google Scholar] [CrossRef]
  31. Xiong, W.; Chen, B.; Wang, H.; Zhu, D. Public–private partnerships as a governance response to sustainable urbanization: Lessons from China. Habitat Int. 2020, 95, 102095. [Google Scholar] [CrossRef]
  32. Enshassi, A.; Kochendoerfer, B.; Al Ghoul, H. Factors affecting sustainable performance of construction projects during project life cycle phases. Int. J. Sustain. Constr. Eng. Technol. 2016, 7, 50–68. [Google Scholar]
  33. Marinho, A.J.C.; Couto, J.; Camões, A. Current state, comprehensive analysis and proposals on the practice of construction and demolition waste reuse and recycling in Portugal. J. Civ. Eng. Manag. 2022, 28, 232–246. [Google Scholar] [CrossRef]
  34. Wu, G.; Duan, K.; Zuo, J.; Zhao, X.; Tang, D. Integrated sustainability assessment of public rental housing community based on a hybrid method of AHP-Entropy weight and cloud model. Sustainability 2017, 9, 603. [Google Scholar]
  35. Dezhi, L.; Yanchao, C.; Hongxia, C.; Kai, G.; Hui, E.C.-M.; Yang, J. Assessing the integrated sustainability of a public rental housing project from the perspective of complex eco-system. Habitat Int. 2016, 53, 546–555. [Google Scholar] [CrossRef]
  36. Pombo, O.; Allacker, K.; Rivela, B.; Neila, J. Sustainability assessment of energy saving measures: A multi-criteria approach for residential buildings retrofitting—A case study of the Spanish housing stock. Energy Build. 2016, 116, 384–394. [Google Scholar] [CrossRef] [Green Version]
  37. Das, J.T.; Banerjee, A.; Puppala, A.J.; Chakraborty, S. Sustainability and resilience in pavement infrastructure: A unified assessment framework. Environ. Geotech. 2019, 9, 360–372. [Google Scholar] [CrossRef]
  38. Xue, B.; Liu, B.; Sun, T. What Matters in Achieving Infrastructure Sustainability through Project Management Practices: A Preliminary Study of Critical Factors. Sustainability 2018, 10, 4421. [Google Scholar] [CrossRef] [Green Version]
  39. Martens, M.L.; Carvalho, M.M. The challenge of introducing sustainability into project management function: Multiple-case studies. J. Clean. Prod. 2016, 117, 29–40. [Google Scholar] [CrossRef]
  40. Zhao, L.; Zha, Y.; Zhuang, Y.; Liang, L. Data envelopment analysis for sustainability evaluation in China: Tackling the economic, environmental, and social dimensions. Eur. J. Oper. Res. 2019, 275, 1083–1095. [Google Scholar] [CrossRef]
  41. Rooshdi, R.; Rahman, N.A.; Baki, N.Z.U.; Majid, M.Z.A.; Ismail, F. An evaluation of sustainable design and construction criteria for green highway. Procedia Environ. Sci. 2014, 20, 180–186. [Google Scholar] [CrossRef] [Green Version]
  42. Kehagia, F. The implementation of sustainability in highway projects. Int. J. Sustain. Dev. Plan. 2009, 4, 61–69. [Google Scholar] [CrossRef]
  43. Tahon, A.; Elshakour, H.A.; Elyamany, A. Sustainability concept and knowledge analysis in construction industry. Int. J. Eng. Manag. Res. 2017, 7, 307–315. [Google Scholar]
  44. Berardi, U. Clarifying the new interpretations of the concept of sustainable building. Sustain. Cities Soc. 2013, 8, 72–78. [Google Scholar] [CrossRef]
  45. Jafari, A.; Valentin, V.; Bogus, S.M. Identification of Social Sustainability Criteria in Building Energy Retrofit Projects. J. Constr. Eng. Manag. 2019, 145, 04018136. [Google Scholar] [CrossRef]
  46. Dodoo, A.; Gustavsson, L.; Tettey, U.Y.A. Final energy savings and cost-effectiveness of deep energy renovation of a multi-storey residential building. Energy 2017, 135, 563–576. [Google Scholar] [CrossRef]
  47. Wang, Q.; Laurenti, R.; Holmberg, S. A novel hybrid methodology to evaluate sustainable retrofitting in existing Swedish residential buildings. Sustain. Cities Soc. 2015, 16, 24–38. [Google Scholar] [CrossRef]
  48. Martens, M.L.; Carvalho, M.M. Key factors of sustainability in project management context: A survey exploring the project managers’ perspective. Int. J. Proj. Manag. 2017, 35, 1084–1102. [Google Scholar] [CrossRef]
  49. Gan, X.; Zuo, J.; Ye, K.; Skitmore, M.; Xiong, B. Why sustainable construction? Why not? An owner’s perspective. Habitat Int. 2015, 47, 61–68. [Google Scholar] [CrossRef]
  50. Samiadel, A.; Golroo, A. Developing an index to measure sustainability of road related projects over the life cycle. Comput. Res. Prog. Appl. Sci. Eng. 2017, 3, 71–80. [Google Scholar]
  51. Arshad, H.; Thaheem, M.J.; Bakhtawar, B.; Shrestha, A. Evaluation of road infrastructure projects: A life cycle sustainability-based decision-making approach. Sustainability 2021, 13, 3743. [Google Scholar] [CrossRef]
  52. Meng, J.; Xue, B.; Liu, B.; Fang, N. Relationships between top managers’ leadership and infrastructure sustainability: A Chinese urbanization perspective. Eng. Constr. Archit. Manag. 2015, 22, 692–714. [Google Scholar] [CrossRef]
  53. Nelms, C.E.; Russell, A.D.; Lence, B.J. Assessing the performance of sustainable technologies: A framework and its application. Build. Res. Inf. 2007, 35, 237–251. [Google Scholar] [CrossRef]
  54. Rosa, L.V.; Haddad, A.N. Assessing the sustainability of existing buildings using the analytic hierarchy process. Am. J. Civ. Eng. 2013, 1, 24–30. [Google Scholar] [CrossRef]
  55. Turcu, C. Re-thinking sustainability indicators: Local perspectives of urban sustainability. J. Environ. Plan. Manag. 2013, 56, 695–719. [Google Scholar] [CrossRef] [Green Version]
  56. Carvalho, M.M.d.; Patah, L.A.; de Souza Bido, D. Project management and its effects on project success: Cross-country and cross-industry comparisons. Int. J. Proj. Manag. 2015, 33, 1509–1522. [Google Scholar] [CrossRef]
  57. Carvalho, M.M.d.; Rabechini Junior, R. Impact of risk management on project performance: The importance of soft skills. Int. J. Prod. Res. 2015, 53, 321–340. [Google Scholar] [CrossRef]
  58. Liu, R.; Hu, X.; Ye, K.; Cao, K.; Zhu, W.; Zuo, J. Perspective Discrepancy between Designers and Constructors on the Sustainability of Steel Structures: Are They Synthesizable? Appl. Sci. 2021, 11, 7430. [Google Scholar] [CrossRef]
  59. Hueskes, M.; Verhoest, K.; Block, T. Governing public–private partnerships for sustainability: An analysis of procurement and governance practices of PPP infrastructure projects. Int. J. Proj. Manag. 2017, 35, 1184–1195. [Google Scholar] [CrossRef]
  60. Wu, S.R.; Fan, P.; Chen, J. Incorporating Culture Into Sustainable Development: A Cultural Sustainability Index Framework for Green Buildings. Sustain. Dev. 2016, 24, 64–76. [Google Scholar] [CrossRef]
  61. Yuan, J.; Li, W.; Guo, J.; Zhao, X.; Skibniewski, M.J. Social risk factors of transportation PPP projects in China: A sustainable development perspective. Int. J. Environ. Res. Public Health 2018, 15, 1323. [Google Scholar] [CrossRef] [Green Version]
  62. Yang, D.; Li, J.; Peng, J.; Zhu, J.; Luo, L. Evaluation of Social Responsibility of Major Municipal Road Infrastructure—Case Study of Zhengzhou 107 Auxiliary Road Project. Buildings 2022, 12, 369. [Google Scholar] [CrossRef]
  63. Goel, A.; Ganesh, L.S.; Kaur, A. Sustainability integration in the management of construction projects: A morphological analysis of over two decades’ research literature. J. Clean. Prod. 2019, 236, 117676. [Google Scholar] [CrossRef]
  64. Tang, J.; Zhu, H.-l.; Liu, Z.; Jia, F.; Zheng, X.-x. Urban Sustainability Evaluation under the Modified TOPSIS Based on Grey Relational Analysis. Int. J. Environ. Res. Public Health 2019, 16, 256. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Sierra, L.A.; Pellicer, E.; Yepes, V. Social sustainability in the lifecycle of chilean public infrastructure. J. Constr. Eng. Manag. 2016, 142, 05015020. [Google Scholar] [CrossRef] [Green Version]
  66. Montalbán-Domingo, L.; García-Segura, T.; Sanz, M.A.; Pellicer, E. Social sustainability criteria in public-work procurement: An international perspective. J. Clean. Prod. 2018, 198, 1355–1371. [Google Scholar] [CrossRef]
  67. Braulio-Gonzalo, M.; Bovea, M.D. Relationship between green public procurement criteria and sustainability assessment tools applied to office buildings. Environ. Impact Assess. Rev. 2020, 81, 106310. [Google Scholar] [CrossRef]
  68. Yu, T.; Shen, G.Q.; Shi, Q.; Zheng, H.W.; Wang, G.; Xu, K. Evaluating social sustainability of urban housing demolition in Shanghai, China. J. Clean. Prod. 2017, 153, 26–40. [Google Scholar] [CrossRef] [Green Version]
  69. Pauleit, S.; Ambrose-Oji, B.; Andersson, E.; Anton, B.; Buijs, A.; Haase, D.; Elands, B.; Hansen, R.; Kowarik, I.; Kronenberg, J.; et al. Advancing urban green infrastructure in Europe: Outcomes and reflections from the GREEN SURGE project. Urban For. Urban Green. 2019, 40, 4–16. [Google Scholar] [CrossRef]
  70. Yin, J.; Cao, X.; Huang, X.; Cao, X. Applying the IPA–Kano model to examine environmental correlates of residential satisfaction: A case study of Xi’an. Habitat Int. 2016, 53, 461–472. [Google Scholar] [CrossRef] [Green Version]
  71. Kucukmehmetoglu, M.; Geymen, A. Optimization models for urban land readjustment practices in Turkey. Habitat Int. 2016, 53, 517–533. [Google Scholar] [CrossRef]
  72. Sierra, L.A.; Pellicer, E.; Yepes, V. Method for estimating the social sustainability of infrastructure projects. Environ. Impact Assess. Rev. 2017, 65, 41–53. [Google Scholar] [CrossRef] [Green Version]
  73. Yager, R.R. On ordered weighted averaging aggregation operations in multicriteria decision making. IEEE Trans. Syst. Man Cybernet 1988, 18, 183–190. [Google Scholar] [CrossRef]
  74. Amarante, M. Mm-OWA: A generalization of OWA operators. IEEE Trans. Fuzzy Syst. 2017, 26, 2099–2106. [Google Scholar] [CrossRef]
  75. Liu, X.; Liu, H. Application of fuzzy ordered weighted geometric averaging (FOWGA) operator for project delivery system decision-making. Soft Comput. 2019, 23, 13297–13307. [Google Scholar] [CrossRef]
  76. Medina, J.; Yager, R.R. OWA operators with functional weights. Fuzzy Sets Syst. 2021, 414, 38–56. [Google Scholar] [CrossRef]
  77. Wang, Y.-M.; Luo, Y.; Hua, Z. Aggregating preference rankings using OWA operator weights. Inf. Sci. 2007, 177, 3356–3363. [Google Scholar] [CrossRef]
  78. Xing, C.; Yao, L.; Wang, Y.; Hu, Z. Suitability Evaluation of the Lining Form Based on Combination Weighting–Set Pair Analysis. Appl. Sci. 2022, 12, 4896. [Google Scholar] [CrossRef]
  79. Gao, H.; Ju, Y.; Gonzalez, E.D.S.; Zeng, X.J.; Dong, P.; Wang, A. Identifying critical causal criteria of green supplier evaluation using heterogeneous judgements: An integrated approach based on cloud model and DEMATEL. Appl. Soft Comput. 2021, 113, 107882. [Google Scholar] [CrossRef]
Figure 1. One-dimensional forward cloud generator.
Figure 1. One-dimensional forward cloud generator.
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Figure 2. One-dimensional backward cloud generator.
Figure 2. One-dimensional backward cloud generator.
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Figure 3. C-OWA operator flow chart.
Figure 3. C-OWA operator flow chart.
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Figure 4. Sustainability evaluation process based on cloud model and C-OWA aggregation method.
Figure 4. Sustainability evaluation process based on cloud model and C-OWA aggregation method.
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Figure 5. Sustainability synthesized cloud.
Figure 5. Sustainability synthesized cloud.
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Table 1. Analysis of factors influencing sustainability of municipal infrastructure projects.
Table 1. Analysis of factors influencing sustainability of municipal infrastructure projects.
IndexInfluence FactorsExplanationReference
EnvironmentalFlooding riskSize and risk of potential floodplains area[19,20,21,22,23]
Energy consumptionConsumption of energy resources such as electricity, gas, and oil[15,24,25,26,27,28,29,30]
Raw materials consumptionConsumption of materials used in all project phases, such as cement, wood, steel, bitumen, aggregate, bricks…etc.[15,24,25,26,31]
Waste recycling and reuseThe utilization and recycling of waste.[15,24,25,32,33]
Energy conservationEnergy conservation of construction technology, equipment, material, etc.[26,34,35,36,37]
Using renewable resourcesThe utilization of renewable resources, less wastage, and contamination.[25,28,29,30,32,38,39,40]
Materials with low health riskUtilization of materials with low health risk.[25,28]
Water pollutionWater quality of the entire life cycle of municipal infrastructure projects.[15,24,25,27,29,32,41,42,43]
Air pollutionAir quality of the entire life cycle of municipal infrastructure projects.[15,24,25,27,29,32,41,42,43]
Noise/acoustic pollutionNoise decibels of the entire life cycle of municipal infrastructure projects.[15,24,25,27,29,32]
Land useProtection and rational development and utilization of local cultural relics, natural water systems and underground Spaces, etc.[34,35,44]
Greening and environmentPlant diversity and green space ratio., etc.[6,25,34,35,45]
Energy performanceEnergy performance of the technology in construction and community equipment, use of energy-saving materials, and material selection that takes recycling performance into account, etc.[34,35,36,46,47]
Environmental fusionThe satisfaction of the public sphere and environment.[15,24,25,29,32,42,48]
Environmental impactThe impacts of pollutants, emissions, household garbage, etc. on the environment.[25,32,34]
Eco-efficiencyLess environmental footprints.[38,39,49]
BiodiversityThe increase in biodiversity and the attraction of other species.[38,49]
EconomyLife cycle profitsProfits of the entire life cycle of municipal infrastructure projects.[32,50,51]
Payback periodThe number of years needed to recover the initial cash outlay.[15]
Life cycle costsCosts of the entire life cycle of municipal infrastructure projects.[37]
Opportunity costsInvestments in other municipal infrastructure projects will be limited due to the fixed and liquid capital bound to the project.[25]
Operation costsCosts of operation of the infrastructure during the operation period.[25,26,34,50,52,53]
Economic fusionThe impacts of pollutants, emissions, household garbage, etc. on the environment.[25,34]
Project budgetTotal project budget of the infrastructure.[15,24,25,27,34,54]
Business activityBusiness activities within and around the municipal infrastructure projects.[34,55]
Financial returnsEfficiencies in operation management contributed to the increase in profits.[38,56,57]
Energy costsCosts associated with oil, gas, and electricity consumption.[25]
Economic performanceThe project increases the local economy’s productivity and introduces economic benefits to society as a whole.[25]
DurabilityService life of municipal infrastructure projects.[26,37,58]
SocialGovernment strategyHigh-level sustainable policies are being pursued by the government.[31,35,38,59]
Cultural continuityPractices, materials, and styles associated with tradition, such as vernacular architecture.[24,34,42,45,60,61,62]
Stakeholder involvementRelationship management among stakeholders and participation of stakeholders.[38,39,63]
Social adjustmentSettlement intentions, discrimination levels, social references, etc.[34]
Public interestsPublic consultations, social security, health care, enrollment of children, etc.[6,34,60,61,64,65,66,67]
Workers’ Safety and HealthA safety and health care plan is implemented during the implementation of the project to ensure the safety of the working staff.[25,37]
Safety standardsProvision of safety features and amenities for users on built-in infrastructure to lower accident rates[25,61,68]
Social satisfactionParticipation in activities and satisfaction with the community among residents[34,62]
Productivity improvement of industries and communitiesConstruction of infrastructure enhances efficiency and productivity in all industries and communities.[38,69]
Employment provisionProject implementation adheres to safety and health care principles for protecting the working staff.[24,25,27,28,32,34,35,43,48,61]
AdaptabilityCapacity of infrastructure to withstand and adapt to external environmental disturbances and changing public requirements.[70,71,72]
Livability of communitiesApplication of infrastructure for improving the quality of life for people.[38,39,62]
Supply capacity of public infrastructureImproved drainage, parking, service level, capacity, electrical, warning systems, etc.[24,25,32]
Table 2. Sustainability evaluation of a highway project in a city.
Table 2. Sustainability evaluation of a highway project in a city.
First Evaluation FactorWeightSecond Evaluation FactorWeightFive Expert Scores
Environment0.49Flooding risk0.11[7, 8] [8, 9] [7, 8] [8, 8.5] [7, 8]
Energy consumption0.05[5, 5.5] [8, 9] [8, 9] [8.5, 9] [7, 8]
Raw materials consumption0.09[6, 7] [7.5, 8.5] [7, 8.5] [8.5, 9.5] [7, 8]
Waste recycling and reuse0.03[5, 5.5] [6, 8] [8, 8.5] [8, 8.5] [6, 7]
Energy conservation0.07[6, 7] [8, 9] [8, 9] [7, 8.5] [8, 9]
Using renewable resources0.12[7, 8] [7, 9] [7, 8] [8, 9] [8, 9]
Materials with low health risk0.06[6, 7] [6, 8] [7, 8] [7, 8.5] [8, 9]
Water pollution0.08[7, 7.5] [7, 8] [7, 8] [6.5, 8.5] [6, 7]
Air pollution0.03[5, 5.5] [6, 8] [7, 8.5] [8, 8.5] [5, 6]
Noise/acoustic pollution0.03[5, 5.5] [7, 8] [8, 8.5] [8, 9] [6, 7]
Land use0.12[8, 9] [8, 8.5] [8, 9.5] [8, 9] [5.5, 6.5]
Greening and environment0.10[7, 8] [7, 8] [8, 9.5] [7, 8.5] [8, 9]
Energy performance0.01[5, 6] [7, 9] [9, 9.5] [7, 8] [8, 9]
Environmental fusion0.03[6, 6.5] [7, 8.5] [7, 8] [6.5.7.5] [5, 6]
Environmental impact0.03[6, 8] [6, 8] [8, 8.5] [8, 8.5] [4, 5]
Eco-efficiency0.03[6, 6.5] [7, 9] [7, 8] [7.5, 8.5] [6, 7]
Biodiversity0.05[7, 8] [8, 9] [8, 8.5] [6, 5, 7.5] [4, 5]
Economy0.29Life cycle profits0.08[7, 7.5] [7, 8] [9, 9.5] [8, 8.5] [7, 8]
Payback period0.13[7, 9] [7, 8.5] [8, 9.5] [7, 8] [6, 7]
Life cycle cost0.03[5, 6] [6, 8] [8, 9.5] [7.5, 8.5] [8, 9]
Opportunity costs0.07[6, 7] [7, 9] [8, 9] [6.5, 8.5] [7, 8]
Operation costs0.13[8, 9] [7, 8.5] [8, 8.5] [7, 9] [6, 7]
Economic fusion0.07[6, 7] [7, 8] [8, 9] [8, 8.5] [5, 6]
Program budget0.13[8, 8.5] [6, 8] [8, 8.5] [8, 8.5] [6, 7]
Business activity0.04[6, 7] [7, 8.5] [7, 8.5] [7.5, 8.5] [5.5, 6.5]
Financial returns0.07[7, 8] [7, 8] [6, 7] [8, 9] [4, 5]
Energy costs0.07[7, 8] [6, 8] [7, 8.5] [7.5, 9] [4, 5]
Economic performance0.04[5, 6] [8, 9] [8, 9] [8, 9] [5, 6]
Durability0.13[8, 9] [8, 8.5] [8, 9] [7, 8] [6, 7]
Social0.22Government strategy0.04[5, 5.5] [8, 9] [7, 7.5] [8.5, 9] [5, 6]
Cultural continuity0.18[9, 9.5] [7, 8] [9, 9.5] [8, 8.5] [7, 8]
Stakeholder involvement0.05[5, 6] [7, 8.5] [7, 7.5] [6.5, 8.5] [6, 7]
Social adjustment0.13[7, 8] [7.5, 8.5] [7, 8] [7.5, 9] [7, 8]
Public interests0.03[5, 6] [8, 8.5] [8, 9] [8, 8.5] [6, 7]
Workers’ Safety and Health0.08[6, 7] [8, 9] [8, 9] [8, 9] [6, 7]
Safety standards0.13[7, 8] [7.5, 8.5] [9, 9.5] [8.5, 9] [6, 7]
Social satisfaction0.02[5, 6] [7, 8] [9, 9.5] [8.5, 9] [8, 9]
Productivity improvement of industries and communities0.04[6, 7] [8, 9] [8, 9] [7.5, 8] [6, 7]
Employment provision0.09[7, 7.5] [7, 8.5] [7, 8.5] [8, 9] [6, 7]
Adaptability0.08[5, 7] [7, 8.5] [7, 8] [8, 8.5] [6, 7]
Livability of communities0.08[5, 6.5] [7.5, 8.5] [7, 8] [8.5, 9] [7, 8]
Supply capacity of public infrastructure0.04[6, 8] [8, 9] [8, 9] [8.5, 9] [7, 8]
Table 3. Digital eigenvalues of the standard cloud.
Table 3. Digital eigenvalues of the standard cloud.
Sustainability LevelsScore Interval Digital   Eigenvalues   of   Cloud   Models   ( E x ,   E n ,   H e )
EconomySocialEnvironment
Excellent[9, 10](10.0, 0.5, 0.05)(10.0, 0.5, 0.05)(10.0, 0.5, 0.05)
Good[8, 9](8.5, 0.5, 0.05)(8.5, 0.5, 0.05)(8.5, 0.5, 0.05)
Medium[6, 8](7.0, 0.5, 0.05)(7.0, 0.5, 0.05)(7.0, 0.5, 0.05)
Bad[0, 6](0, 2.33, 0.23)(0, 2.33, 0.23)(0, 2.33, 0.23)
Table 4. Integration intervals by using C-OWA operators.
Table 4. Integration intervals by using C-OWA operators.
IndicatorabfAB
Flooding risk898.337.38.2
88.58.17
787.33
787.33
787.33
Energy consumption8.598.677.68.5
898.33
898.33
787.33
55.55.17
Raw materials consumption8.59.58.837.28.3
7.58.57.83
78.57.50
787.33
676.33
Waste recycling and reuse88.58.176.67.8
88.58.17
686.67
676.33
55.55.17
Energy conservation898.337.68.8
898.33
898.33
78.57.50
676.33
Using renewable resources898.337.38.7
898.33
797.67
787.33
787.33
Materials with low health risk898.336.88.1
78.57.50
787.33
686.67
676.33
Water pollution787.336.87.9
787.33
77.57.17
6.58.57.17
676.33
Air pollution88.58.176.17.5
78.57.50
686.67
565.33
55.55.17
Noise/acoustic pollution898.336.97.8
88.58.17
787.33
676.33
55.55.17
Land use89.58.507.88.8
898.33
898.33
88.58.17
5.56.55.83
Greening and environment89.58.507.38.5
898.33
78.57.50
787.33
787.33
Energy performance99.59.177.38.6
898.33
797.67
787.33
565.33
Environmental fusion78.57.506.47.3
787.33
6.57.56.83
66.56.17
565.33
Environmental impact88.58.176.58.0
88.58.17
686.67
686.67
454.33
Eco-efficiency7.58.57.836.77.9
797.67
787.33
676.33
66.56.17
Biodiversity898.337.07.9
88.58.17
787.33
6.57.56.83
454.33
Life cycle profits99.59.177.48.2
88.58.17
787.33
787.33
77.57.17
Payback period89.58.507.08.5
797.67
78.57.50
787.33
676.33
Life cycle cost89.58.507.18.4
898.33
7.58.57.83
686.67
565.33
Opportunity costs898.336.98.4
797.67
787.33
6.58.57.17
676.33
Operation costs898.337.38.6
88.58.17
797.67
78.57.50
676.33
Economic fusion898.336.97.8
88.58.17
787.33
676.33
565.33
Program budget88.58.177.48.3
88.58.17
88.58.17
686.67
676.33
Business activity7.58.57.836.78.0
78.57.50
78.57.50
676.33
5.56.55.83
Financial returns898.336.67.6
787.33
787.33
676.33
454.33
Energy costs7.598.006.68.0
78.57.50
787.33
686.67
454.33
Economic performance898.337.18.1
898.33
898.33
565.33
565.33
Durability898.337.68.4
898.33
88.58.17
787.33
676.33
Government strategy8.598.676.77.5
898.33
77.57.17
565.33
55.55.17
Cultural continuity99.59.178.08.7
99.59.17
88.58.17
787.33
787.33
Stakeholder involvement78.57.506.47.7
77.57.17
6.58.57.17
676.33
565.33
Social adjustment7.598.007.28.2
7.58.57.83
787.33
787.33
787.33
Public interests898.337.38.0
88.58.17
88.58.17
676.33
565.33
Workers’ Safety and Health898.337.48.4
898.33
898.33
676.33
676.33
Safety standards99.59.177.68.5
8.598.67
7.58.57.83
787.33
676.33
Social satisfaction99.59.177.88.6
8.598.67
898.33
787.33
565.33
Productivity improvement of industries and communities898.337.28.0
898.33
7.587.67
676.33
676.33
Employment provision898.337.08.2
78.57.50
78.57.50
77.57.17
676.33
Adaptability88.58.176.77.8
78.57.50
787.33
676.33
575.67
Livability of communities8.598.677.18.1
7.58.57.83
787.33
787.33
56.55.50
Supply capacity of public infrastructure8.598.677.78.7
898.33
898.33
787.33
686.67
Table 5. Cloudification results of sustainability indicators.
Table 5. Cloudification results of sustainability indicators.
IndicatorIntegration IntervalAttribute Value
[A, B] ( E x , E n , H e )
Flooding risk[7.3, 8.2](7.75, 0.15, 0.02)
Energy consumption[7.6, 8.5](8.06, 0.16, 0.02)
Raw materials consumption[7.2, 8.3](7.75, 0.20, 0.02)
Waste recycling and reuse[6.6, 7.8](7.16, 0.20, 0.02)
Energy conservation[7.6, 8.8](8.19, 0.19, 0.02)
Using renewable resources[7.3, 8.7](8.00, 0.23, 0.02)
Materials with low health risk[6.8, 8.1](7.44, 0.23, 0.02)
Water pollution[6.8, 7.9](7.34, 0.28, 0.03)
Air pollution[6.1, 7.5](6.78, 0.24, 0.02)
Noise/acoustic pollution[6.9, 7.8](7.36, 0.14, 0.01)
Land use[7.8, 8.8](8.30, 0.15, 0.02)
Greening and environment[7.3, 8.5](7.92, 0.20, 0.02)
Energy performance[7.3, 8.6](7.92, 0.22, 0.02)
Environmental fusion[6.4, 7.3](6.89, 0.15, 0.02)
Environmental impact[6.5, 8.0](7.23, 0.24, 0.02)
Eco-efficiency[6.7, 7.9](7.33, 0.20, 0.02)
Biodiversity[7.0, 7.9](7.44, 0.15, 0.02)
Life cycle profits[7.4, 8.2](7.78, 0.14, 0.01)
Payback period[7.0, 8.5](7.73, 0.24, 0.02)
Life cycle cost[7.1, 8.4](7.77, 0.21, 0.02)
Opportunity costs[6.9, 8.4](7.63, 0.25, 0.03)
Operation costs[7.3, 8.6](7.94, 0.23, 0.02)
Economic fusion[6.9, 7.8](7.38, 0.15, 0.02)
Program budget[7.4, 8.3](7.83, 0.15, 0.02)
Business activity[6.7, 8.0](7.34, 0.22, 0.02)
Financial returns[6.6, 7.6](7.13, 0.17, 0.02)
Energy costs[6.6, 8.0](7.30, 0.23, 0.02)
Economic performance[7.1, 8.0](7.56, 0.17, 0.02)
Durability[7.6, 8.4](8.03, 0.14, 0.01)
Government strategy[6.7, 7.5](7.09, 0.13, 0.01)
Cultural continuity[8.0, 8.7](8.33, 0.11, 0.01)
Stakeholder involvement[6.4, 7.7](7.08, 0.21, 0.02)
Social adjustment[7.2, 8.2](7.67, 0.17, 0.02)
Public interests[7.3, 8.0](7.66, 0.11, 0.01)
Workers’ Safety and Health[7.4, 8.4](7.88, 0.17, 0.02)
Safety standards[7.6, 8.5](8.05, 0.14, 0.01)
Social satisfaction[7.8, 8.6](8.17, 0.14, 0.01)
Productivity improvement of industries and communities[7.2, 8.0](7.59, 0.14, 0.01)
Employment provision[7.0, 8.2](7.59, 0.20, 0.02)
Adaptability[6.7, 7.8](7.27, 0.19, 0.02)
Livability of communities[7.1, 8.1](7.59, 0.17, 0.02)
Supply capacity of public infrastructure[7.7, 8.7](8.17, 0.17, 0.02)
Table 6. Synthesized cloud for economic, social, and environmental sustainability.
Table 6. Synthesized cloud for economic, social, and environmental sustainability.
First Evaluation FactorEconomic SustainabilitySocial SustainabilityEnvironmental Sustainability
( E x , E n , H e )(7.679, 0.188, 0.019)(7.328, 0.163, 0.016)(7.705, 0.202, 0.021)
Table 7. Synthesized cloud MATLAB code.
Table 7. Synthesized cloud MATLAB code.
Economic Sustainability
   E x = 7.679; E x , E n , H e
   E n = 0.188;
   H e = 0.019;
  n = 3000;
  X = zeros (1, n);
  Y = zeros (1, n);
  X (1: n)= normrnd ( E x , H e , 1, n);
  for i = 1: n
  En_1 = normrnd (En, He, 1, 1);
  X (1, i) = normrnd (Ex, En_1, 1);
  Y (1, i) = exp (−(X (1, i) − Ex)^2/(2*En_1^2));
  plot (X, Y, ‘>’, ‘MarkerEdgeColor’, ‘b’, ‘markersize’, 4);
  grid on;
  end
  hold on;
Social sustainability:
  Ex = 7.328;
  En = 0.163;
  He = 0.016;
  n = 3000;
  X = zeros (1, n);
  Y = zeros (1, n);
  X (1: n) = normrnd (Ex, He, 1, n);
  for i = 1: n
  En_1 = normrnd (En, He, 1, 1);
  X (1, i) = normrnd (Ex, En_1, 1);
  Y (1, i) = exp(−(X (1, i) − Ex)^2/(2*En_1^2));
  plot (X, Y, ‘.’, ‘MarkerEdgeColor’, ‘k’, ‘markersize’, 4);
  grid on;
  end
  hold on;
Environmental sustainability:
  Ex = 7.705;
  En = 0.202;
  He = 0.021;
  n = 3000;
  X = zeros (1, n);
  Y = zeros (1, n);
  X (1: n) = normrnd (Ex, He, 1, n);
  for i = 1: n
  En_1 = normrnd (En, He, 1, 1);
  X (1, i) = normrnd (Ex, En_1, 1);
  Y (1, i) = exp (−(X (1, i) − Ex)^2/(2*En_1^2));
  plot (X, Y, ‘*’, ‘MarkerEdgeColor’, ‘r’, ‘markersize’, 4);
  grid on;
  end
Table 8. Subordinate status of sustainability level of evaluation factors at each level.
Table 8. Subordinate status of sustainability level of evaluation factors at each level.
Economic SustainabilitySocial SustainabilityEnvironmental Sustainability
Excellent0.0000400.00003
Good0.27820.09220.3376
Medium0.45930.80820.4233
Bad0.00440.00720.0038
Table 9. Overall project sustainability assessment results.
Table 9. Overall project sustainability assessment results.
Sustainability LevelExcellentGoodMediumBad
Degree of membership0.000030.27560.599230.00544
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MDPI and ACS Style

Liu, X.; Xue, Z.; Ding, Z.; Chen, S. Sustainability Assessment of Municipal Infrastructure Projects Based on Continuous Interval Argumentation Ordered Weighted Average (C-OWA) and Cloud Models. Sustainability 2023, 15, 4706. https://doi.org/10.3390/su15064706

AMA Style

Liu X, Xue Z, Ding Z, Chen S. Sustainability Assessment of Municipal Infrastructure Projects Based on Continuous Interval Argumentation Ordered Weighted Average (C-OWA) and Cloud Models. Sustainability. 2023; 15(6):4706. https://doi.org/10.3390/su15064706

Chicago/Turabian Style

Liu, Xun, Zhiyuan Xue, Zhenhan Ding, and Siyu Chen. 2023. "Sustainability Assessment of Municipal Infrastructure Projects Based on Continuous Interval Argumentation Ordered Weighted Average (C-OWA) and Cloud Models" Sustainability 15, no. 6: 4706. https://doi.org/10.3390/su15064706

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