A New Self-Assessment “TQM Hybrid MCDM Fuzzy Model” For Enhancing the KPIs in Mega Universities

e key performance indicators (KPIs) are an eective part of benchmarking formeasuring the performance of universities aiming to raise the university quality services level. e problem is that there is no general standard analytical evaluation model for assessing KPIs criteria in higher education institutes for evaluating mega universities, and there are inadequacies in the treatment of specic current educational quality standards. In this paper, a hybrid fuzzy analytical model for TQM self-assessment to enhance KPIs in mega universities is proposed. e proposed model produces important weights for TQM-KPIs that are recommended for helping higher authorities at the university for enhancing the demanded total quality services and aid the university to achieve its strategic objectives and to be one of the highly ranked universities. In addition, the European Foundation for Quality Management (EFQM) excellence model enabler criteria were modied and used. Two additional enabler criteria for representing the mega university and the world ranking were proposed. e “TQM Hybrid Fuzzy Model” proposed integrates three fuzzy multiple criteria decisionmaking (MCDM) submodels including (1) the fuzzy analytic hierarchy process (FAHP), (2) the fuzzy decision-making trial and evaluation laboratory (FDEMATEL), and (3) the fuzzy multiple criteria decision analysis (FVIKOR). Each of these submodels is computed and evaluated analytically. A comparison between them is achieved. Finally, the whole “TQM Hybrid F-MCDMModel” proposed is proved and evaluated analytically and programmed using Excel. Hence, by comparison, it is found that the proposed hybrid fuzzy model is the most eective model for evaluating the TQM-KPIs for enhancing mega universities’ organizational assessment. Results show that the subcriteria that occupied the rst three positions are the managed and improved distance learning sources and materials, policy, and strategies that are based on the present and future needs and expectations of stakeholders.


Introduction
MEGA universities have achieved outstanding improvements in distance learning in the education area; however, there are several challenges to overcome to develop a universal quality model to cater to the needs of the mega universities (MU) to empower its role and innovation capabilities [1][2][3][4]. e key performance indicators (KPIs) are an e ective part of benchmarking for measuring the performance of universities [5] since they help university decision-makers to participate in community services e ectively. To achieve that, in this paper, the development of a hybrid MCDM fuzzy model for total quality management self-assessment is proposed for measuring KPIs to enhance the quality of MU. is is because there is no universal standard analytical model that can be used to assess the KPIs criteria for evaluating MU. Besides, there are shortcomings in the coverage of some current MU educational quality criteria [6]. e method produces important weights for criteria and subcriteria that are recommended for helping decision-makers at MU for enhancing its educational quality services. Moreover, it helps MU to achieve its strategic goals to produce people who are ready to contribute to a better and sustainable quality of life in the country [7]. Moreover, its own precise and suitable KPIs that bring transparency, accountability, and responsibility among its students, faculty, and staff pave the way to academic and scientific development [8].
is paper proposes an efficient fuzzy MCDM hybrid model for TQM self-assessment to enhance KPIs in mega universities to achieve continuous improvement and sustainable development of MU, with a case study on King Abdul-Aziz University (KAU) in the Kingdom of Saudi Arabia as an example of MU to be the pioneer in its region. However, the model can be applied to other mega universities.
In this paper, the used criteria are based on the combination of literature review and empirical research. It is based on research in MU for the sake of in-depth comprehension of university affairs and the environment. A review of the existing literature and an empirical study are handled through questionnaires. Survey questionnaires were developed to collect data about the current situation of MU quality criteria [9,10]. ree questionnaires were designed for academic leaders and experts including academic staff and students. e questionnaires were developed based on the results from surveys. e criteria and subcriteria of the proposed model are then identified.
en, the proposed model for evaluating KPIs of MU is constructed with several hierarchy levels including various criteria and subcriteria that are used to assess the KPIs recommended. e criteria and subcriteria priorities and weights are then estimated by constructing a pair-wise comparison matrix using the MCDM based on the integration of FAHP, FDEMATEL, and FVIKOR. Finally, the potential issues associated with the proposed hybrid fuzzy model are analyzed and discussed. e rest of the paper is as follows: Section 2 is the literature review. Section 3 describes the main components of the modified EFQM excellence model. Section 4 describes the "TQM Hybrid Fuzzy Model" proposed. Section 5 explains the new model analysis and results. Section 6 investigates the findings and discussions, and Section 7 is the conclusion.

Literature Review
In the knowledge-based society of the twenty-first century, no doubt that higher education (HE) is a key element of high value to the welfare of any society [11]. Universities exist to educate, carry out research, and engage in a community with better quality of life [12]. Manpower resource quality plays a vital in the growth and development of a society where the quality of people can be enriched with the high-quality education provided by higher education institutions (HEIs) [13]. On another hand, the increasing competition and the international mobility of students and staff raised the expectations about better education quality. is reflects the need to develop an internal mechanism for quality management as a strategic goal for many of the HEIs [14]. erefore, HEIs need to be subjected to some benchmarking or performance evaluation [15]. ere are a lot of efforts have been made for enhancing the quality of institutions in higher education [16][17][18][19][20][21][22][23].
In [22], the authors reported that the HEIs and governments need to change their strategic plans and institutional regulations for the development of the educational process and added that KPIs provide quality assurance to higher education. Insung Jung [23] mentioned that MU has been developed to meet the increasing demand for adults and lifelong learners, and recently, MU placed more emphasis on widening access than assuring quality, but now they recognize quality assurance (QA) as a key issue that needs to be considered. At the same time, QA models are at an early and therefore crucial stage of development. erefore, MU must produce people who are ready to contribute to a better and sustainable quality of life for the country. erefore, moreover, with its own precise and suitable KPIs, MU brings transparency, accountability, and responsibility to its students, faculty, and staff, paving the way to academic and scientific development. e KAU, as an example of MU, is one of the few universities in the Middle East that rose to acquire the number one in national rank and number 278 rank among the world-class universities in 2021 (R11). KAU tried to implement KPIs through its current and previous strategic plans to achieve international distinction in the education process. KAU witnessed tremendous quantitative and qualitative progress in academic programs while continuing to maintain its traditional commitment to deliver outstanding education and community service.
Classical MCDM methods [9,10,[36][37][38][39][40] are not efficient enough due to the identification of many effective criteria in a qualitative way based on the experts' judgments according to the linguistic variables and uncertainty of the problem. erefore, this paper aims to develop a hybrid fuzzy model for TQM self-assessment for enhancing KPIs in MU to achieve continuous improvement and sustainable development of MU by using fuzzy MCDM methods. KAU is used as an example of a MU case study to be the pioneer in its region. Several of the advanced MCDM hybrid methods are used to assess TQM. Selecting an appropriate method could be a great challenge since individual MCDM methods can produce different rankings (see Table 1). erefore, it is recommended to use a hybrid fuzzy model to avoid the disadvantages of these individual methods, to get the benefits of their advantages, and to integrate those results for final decision-making [41]. ese advantages can be summarized as follows [41]. e qualitative and quantitative data related to the criteria can be collected and used as inputs into the next proposed approach. Integration of subjective and objective criteria are important, because the objective criteria models do not consider the experiences of the decision makers while the subjective criteria model do not consider the performance ratings of the alternatives with respect to different criteria. Fuzzy logic can help to overcome uncertainties arising from human qualitative judgments to provide us with a more appropriate model for real-life assessment. So, to satisfy this goal, FAHP can be the best option for prioritization among the EFQM questions' importance weights, FDEMATEL is the best choice for finding the interconnections and relations among the subcriteria, and FVIKOR is the best method for ranking the final alternatives.

Modified EFQM Excellence Model
e EFQM model focuses on customer needs and quality attributes embraced by the customers. In this paper, the perception of quality in higher education is modified. It is then followed by the introduction of a modified EFQM excellence model as the basis for the adoption of a measure and self-assessment tool in the higher education areas. e classic EFQM excellence model contains 9 criteria [43]. e enablers criteria include leadership, policy and strategy, employee participations, and resource and process. And the results criteria include customer results, people results, social results, and key performance results. Organization quality assessment is accomplished by scoring and ranking those criteria. Enablers embrace the processes and structures so that they are concerned with how the organization performs its activities [44,45]. e results concentrate on achievements relating to organizational stakeholders; so, they deal with organizational accomplishments [44,48]. e modified EFQM (M-EFQM) excellence model of business was introduced based on the TQM concept. e M-EFQM was constructed with seven main criteria. Five of them are the enabler of EFQM, and the remaining two main criteria are proposed for the M-EFQM by considering the mega university and the world ranking, which are "mega online distance Learning" and "Scoring & Ranking." Furthermore, several experts are selected to find the most appropriate scores for criteria and subcriteria. After that, an adaptation of the M-EFQM excellence model of business with the implementation of multicriteria decisionmaking processes including FAHP, FDEMATEL, and FVI-KOR was investigated. Detailed differences of these methods and their influence on the quality assessment policies are studied analytically in Section 4. Finally, by comparing the advantages and disadvantages of each method, the developed hybrid fuzzy model was found as the most effective model of organizational assessment.
In this section, a TQM three-stage model is proposed for selecting and ranking institutions and universities in higher education to treat ambiguity and uncertainty in the evaluation of HE institutions and universities. e new model depends on a fuzzy framework that integrates three MCDM fuzzy techniques. ese techniques are FAHP, FDEMATEL, and FVIKOR. It is constructed of three phases. In Phase 1, the proposed model defines the decision-making problem (DM). en, it constructs the hierarchical structure of criteria (identify criteria, subcriteria (alternatives), and questions by a consultant with experts and reviewing the literature). In Phase 2, the proposed model defines and transforms criteria, subcriteria, and questions into linguistic variables and fuzzy values. In Phase 3, the proposed model evaluates the main TQM criteria and subcriteria by using multiple steps. Firstly, it calculates the importance of the weight of TQM evaluation criteria by using FAHP. Secondly, it determines the most effective criteria and subcriteria by using FDEMATEL, which uses the output importance weights of FAHP with the relationship weights of FDE-MATEL to get the combined weights of criteria and subcriteria. irdly, it prioritizes a set of available alternatives for criteria and subcriteria by using FVIKOR. Finally, it determines if the results by FVIKOR are satisfied or not. In case of its results are satisfied, then the results are accepted. While in the case of its results are not satisfied, then the proposed model will tune the criteria by fuzzy transformation phase and repeat the process. Figure 1 shows a flowchart of the model presented in the paper.
To carry out the integration of the submodels FAHP, FDEMATEL, and FVIKOR in the proposed hybrid MCDM fuzzy model, the following processes are followed. Selecting the best information system manager Chen, and Cheng [26] Fuzzy AHP-TOPSIS Evaluating the e-service quality of internet-based banking alternatives to obtain the best-qualified alternative Ozdagoglu and Guler [27] Fuzzy AHP-TOPSIS Selecting the best supplier Jain et al. [28] Delphi and fuzzy AHP-TOPSIS Weighting criteria and prioritizing heat stress indices in surface mining Asghari, et al. [29] Fuzzy DEMATEL-AHP-VIKOR Selecting the best strategy for investing Mobini and Yazdani [30] Fuzzy A set of main criteria and their subcriteria are identified and proposed as indicatedinTables 2-5. Moreover, a group of decision-makers (DMs) is asked to give a score for each subcriterion in the questionnaires.

3.1.2.
Step 2: Opinions and Score Collection. A group of responses and opinions are collected from DMs are mainly for the rating of the specified criteria and subcriteria. e DMs group consists of many experts to form linguistic data for rating the submodels FAHP, FDEMATEL, and FVIKOR.

3.1.3.
Step 3: Constructing a Hierarchical Structure. A hierarchical structure of the TQM-MCDM problem is constructed.
is hierarchical structure is divided into two levels. e first level describes the focus of the main criteria of the TQM-MCDM problem, while the second level explains the subcriteria of each main criteria.

Phase 2: Fuzzy Transformation.
In this phase, three sessions of data collection are conducted for determining the linguistic rating and fuzzy scaling of criteria and subcriteria. In the first session, DMs are asked to rate in five-point scales of pair-wise comparison of fuzzy AHP varying from "equally important (EI)" to "extremely strong important (ESI)". e proposed five-point scales and linguistic variables for criteria and subcriteria are shown in Tables 9,9) (1/11, 1/9, 1/7) session, we are asked to specify the rating of FDEMATEL by using five linguistic scales varying from "no influence (NO)" to "very high influence (VH)" over the criteria and subcriteria of the MCDM problem. e linguistic scales and variables of FDEMATEL are shown in Table 4. In the third session, DMs are asked to specify the rating FVIKOR by using seven linguistic scales varying from "very poor (VP)" to "very good (VG)" over the criteria concerning a set of available alternatives. e proposed linguistic scales and variables for FVIKOR are shown in Table 5).

Phase 3: TQM Evaluation.
In this phase, FAHP, FDE-MATEL, and FVIKOR are integrated to evaluate the criteria and subcriteria of the proposed TQM model with a set of available alternatives.
is phase is consisting of the following fourteen steps.

Step 1: Constructing a Pair-Wise Comparison for FAHP.
Here, the pair-wise comparison is constructed between all criteria and subcriteria of the hierarchical structure based on the preferences of DMs which are defined in the construction phase (phase 1). e pair-wise comparison constructs the following matrix C. C � 1 a 12 a 13 · · · · · · a 1n a 21 1 · ·· · · · · · · a 2n a 31 a 32 1 · · · · · · a 3n

3.3.2.
Step 2: Aggregating the Preferences of DMs. e resulted pair-wise comparison matrices are aggregated by using the geometric mean defined by Buckly in [47] where each element, a 12 , of a matrix is calculated as follows: where m is the total number of DMs.

Step 3: Calculating the Fuzzy Weights and Relative
Fuzzy Weights by FAHP. e aggregated comparison matrix of each criterion and subcriteria is constructed by using the following equation: where j � 1, 2, . . . , m and k � triangular fuzzy numbers. en, the fuzzy weight of criteria and subcriteria, w FA j , is calculated as follows: en, the relative fuzzy weights of subcriteria, rw FA j , are calculated by the following equation: where cw FA j and sw FA j are the weights of criteria and its related subcriteria, respectively.

Step 4: Defuzzifying and Normalizing the Fuzzy
Weights of FAHP. Triangular fuzzy weights are deffuzified, and it is calculated by the following formula [48][49][50]: where Z is the deffuzified value of the fuzzy number Z � (a 1 , a 2 , a 3 ). And, the normalized weights for criteria and subcriteria are calculated by the following formula: where Z j and Z r are the deffuzified values of criteria/subcriteria j and r, respectively.

3.3.5.
Step 5: Generating the Initial Direct-Relation Matrix, A, For FDEMATEL. Based on the fuzzy number score x k ij which is given k th decision-maker that indicates the influential level of criteria i on criteria j, the matrix n × n is calculated by aggregating the scores of all decision-makers in Phase 2, and each element of the aggregated matrix is defined as follows: where Matrix A describes the initial direct relation that a criterion or a subcriterion influences on and received from other criteria or subcriteria.

3.3.6.
Step 6: Calculating the Normalized Initial Direct-Relation Matrix D of FDEMATEL. Based on the initial directrelation matrix, A, the normalized initial direct-relation matrix, D, can be calculated as follows: where s is a scalar value which is calculated as follows: where s u is the sum of each row of the matrix A which represents the total direct effects the criterion i gave to the other criteria and s v is the sum of each column of the matrix A which represents the total direct effects received by other criteria by criterion i. s u and s v are defined as follows:

3.3.7.
Step 7: Constructing n × n Total Relation Matrix B of FDEMATEL. Based on the normalized initial direct-relation matrix, D, the total relation matrix B is calculated as follows: where I is the identity matrix.

3.3.8.
Step 8: Determining the Structural Correlation Analysis of FDEMATEL. Assume that r and c are n × 1 vectors for indicating the sum of rows and the sum of columns of matrix Z, respectively, as follows: , the sum of influences r j + c j gives the degree of importance that criterion j plays in the problem and is denoted as D j + R j . Also, the difference in influences r j − c j gives the net effects that criterion j contributes to the problem and is denoted as D j − R j . When D j − R j positive, criterion j is called a net causer, which means that it has a significant impact on the other criteria. On the contrary, when D j − R j negative, criterion j is called a net receiver, which means that it is influenced by the other criteria.

3.3.9.
Step 9: Calculating New Expected Value D j + R j and D j − R j by FAHP/FDEMATEL. Here, the fuzzy weights from step 3, w FA j are multiplied by values of D j + R j and D j − R j to calculate their new expected values as follows: 3.3.10.
Step 10: Calculating the Final Weights by Combining FAHP/FDEMATEL. Firstly, the defuzzification process of fuzzy numbers E(D j + R j ) and E(D j − R j ) is done by the following formula [51][52][53]: where X is the defuzzified crisp value of a fuzzy number X � (x 1 , x 2 , x 3 ). en, the final combining weights by FAHP/FDEMA-TEL, w c i , are calculated by using the following proposed formula: where ese combining weights will be the input weights of criteria and subcriteria for FVIKOR (Step 12).

3.3.11.
Step 11: Constructing the Causal Diagram. e casual diagram is constructed based on the new D j + R j and D j − R j value. In this diagram, D j + R j represents its horizontal axis vector and is called ''prominence'' which describes the important degree that criterion j plays in the system, while 6 Applied Computational Intelligence and Soft Computing D j − R j represents its vertical axis and is called ''relation'' which describes the net effect the criterion j contributes to the system. When D j − R j is positive, criterion j is a net causer, and when D j − R j is negative, criterion j is a net receiver [54,55].

3.3.12.
Step 12: Constructing a Comparison Matrix with Alternatives for FVIKOR. Firstly, a comparison matrix V between criteria/subcriteria and a group of alternatives is constructed as follows: A y p 11 p 12 p 13 · · · · · · p 1n p 21 p 22 p 23 · · · · · · p 2n p 31 p 32 p 33 · · · · · · p 3n An element p ij of the matrix indicates the performance rating of the ith alternative A i , concerning the jth criterion C j [56].
is rating is defined by using fuzzy numbers equivalent to linguistic variables which are shown in Table 5 and are described in Phase 2.

3.3.13.
Step 13: Ranking the Alternatives by FVIKOR. Firstly, the best x + j and the worst x − j values of all criteria are determined as follows: x + j � max f ij and x − j � min f ij if the jth criterion is a benefit.
x + j � min f ij and x − j � max f ij if the jth criterion is a loss.
Where j � 1, 2, . . . , n and f ij is the normalized value of p ij .
Secondly, the maximum group utility S i and the minimum individual regret i of the alternative A i are calculated as follows: irdly, the aggregate values Q i for each alternative A i are computed by using the following formula: where and v is a constant and equals 0.5, usually.
Finally, the alternatives are ranked by sorting by values of S i , R i , and Q i values in decreasing order. erefore, the results will be three ranking lists, and the alternative (A 1 ) which is ranked the best by the minimum of Q i is proposed as an optimal solution if the following two conditions are satisfied.
where A 2 the alternative with the second is the position in the ranked list by Q and y is the number of alternatives.

Condition 2.
Alternative A 1 must be the best ranked by S or/ and R.

3.3.14.
Step 14: Results Evaluation. In this step, the proposed model determines if the results by FVIKOR in Step 12 are satisfied or not. In case of its results are satisfied, then the results will be accepted. While, in the case, its results are not satisfied, then the proposed model will tune the criteria by fuzzy transformation phase and repeat the process.

TQM Hybrid MCDM Fuzzy Model Analysis and Results
In this section, a case study of TQM-KPIs self-assessment to enhance KPIs in mega universities, the case study KAU, was conducted to demonstrate the efficacy of the proposed model.

TQM-KPIs Evaluation Using the Proposed Model and
Recommendations. Table 6 shows the proposed set of criteria and subcriteria and their scores based on the opinion of decision-makers. As shown in Table 6, all scores have the value of 20 based on suggestions of decision-makers to show that all subcriteria have equally the same effect on its main criteria. In this evaluation, three DMs � {E1, E2, E3} were invited to evaluate the criteria and subcriteria of the TQM-KPIs selfassessment problem. Based on M-EFQM, 7 criteria and 35 subcriteria, where each criterion including 5 subcriteria, are proposed for the TQM-KPIs self-assessment problem. As described in Phase 1 of the proposed model, based on the opinion of DMs, each subcriterion is evaluated and scored. e first five criteria are the enablers of EFQM, which are leadership, policy & strategy, people, partnership & resources, product, and service & process. e remaining two main criteria are proposed for considering the mega university and the world ranking, including mega online distance learning and scoring & ranking. Moreover, the hierarchical structure of the TQM-KPIs self-assessment problem is identified as shown in Figure 2. Besides, questionnaires are developed to collect data about the current situation of MU quality criteria at KAU as an example of a MU case study. ree questionnaires are designed including "academic leaders and experts," "academic staff," and "students." e questionnaires are being developed based on the results from the surveys included, criteria, and the subcriteria of the proposed model.
By applying Phase 2, the three DMs were asked to provide ratings of the criteria and subcriteria using the linguistic scales as shown in Tables 2 and 3 for FAHP.  Tables 7 and 8 show the linguistic variables and their corresponding fuzzy decision matrix of the main criteria using E1 for FAHP. Moreover, they were asked to rate the criteria Applied Computational Intelligence and Soft Computing and subcriteria using the linguistic scales as shown in Table 4 for FDEMATEL. Tables 9 and 10 show the linguistic variables and their corresponding fuzzy decision matrix of the main criteria using E1 for FDEMATEL. Moreover, DMs were asked to rate the criteria and subcriteria using the linguistic scales as shown in Table 3 concerning the ten available alternatives for FVIKOR. Table 11 shows the linguistic variables and their corresponding fuzzy decision matrix of the main criteria, and Table 12 shows the fuzzy decision matrix of alternatives for the main criteria for FVIKOR.
By applying Step 1 to Step 4 in Phase 3, the proposed model calculates the final fuzzy weight of criteria and subcriteria of FAHP by using equations (1)-(7). Table 13 shows the final fuzzy, average, and normalized weights (w FA j ) of the main criteria by FAHP. Moreover, by applying Step 4 to Step 9, the proposed model calculates the final fuzzy weight of criteria and subcriteria of FDEMATEL by using equations (8) to (26). Tables 14-16 show the final fuzzy  values,    Applied Computational Intelligence and Soft Computing           Here, ten alternatives of TQM-KPIs self-assessment are proposed and denoted as A, A2, A3, A4, A5, A6, A7, A8, A9, and A10, respectively. ese alternatives can be considered as a set of strategies that mega university wants to select one of them for enhancing its plans, policies, activities, partnerships, and other resources and satisfying its goals and objectives. e alternatives are rated by DMs considering the evaluation of 7 criteria including A, B, C, D, E, F, and G in the case of the main criteria. While in the case of subcriteria, they are rated by considering 5 subcriteria of each main criterion.
By applying Steps 12 and 13 in Phase 3, the proposed model will determine the final alternatives ranking based on the benefit value (Si), the unfortunate value (Ri), and the FVIKOR index  Table 18.
Similarly, the final alternative rankings due to benefit value (Si), unfortunate value (Ri), and FVIKOR index (Qi) for subcriteria of each main criterion are shown in Table 19. According to conditions 1 and 2 in Step 13, for the main   10,9,4,7, and 2 are selected as the best alternatives. For the main criterion D, alternatives 9, 3, 2, 5, and 1 are selected as the best alternatives. For the main criterion E, alternatives 8, 7, 5, 6, and 9 are selected as the best alternatives. For the main criterion F, alternatives 6, 3, 7, 2, and 5 are selected as the best alternatives. For the main criterion G, alternatives 8, 3, 1, 9, and 4 are selected as the best alternatives. Based on the previous ranking results of the main criteria and subcriteria, the proposed model can give the best guideline to the mega university experts for selecting the best alternatives and strategies based on the most important criteria and their related subcriteria.

Findings and Discussions
Ranked results by FAHP are shown in Figure 5, which indicate that the subcriteria for the proposed model that occupied the first ten positions are as follows: (1) Policy and strategy are based on the present and future needs and expectations of stakeholders (B1) (2) Distance-learning sources and materials are managed and improved (F1) (3) Processes are systematically designed and managed (E1) (4) Internal and external partnerships are managed (D1) (5) Leaders are personally involved in ensuring the university's management system is developed, implemented, and continually improved (A2) (6) Leaders are involved with and interact with customers, partners, and representatives of Society (A3) (7) Leaders motivate, support, and recognize the university's people and nurture a culture of excellence (A4) (8) Teaching quality is managed and enhanced (G1) (9) Policy and strategy are based on information from performance measurement, research, learning, and externally related activities (B2)  Moreover, the ranked results by FAHP/FDEMATEL shown in Figure 6 indicate that the subcriteria for the proposed model that occupied the first ten positions are as follows.

Conclusions
In this paper, a new "TQM Hybrid MCDM Fuzzy Model" for self-assessment TQM-KPIs in mega universities was proposed. It consists of a hierarchical structure for solving the TQM-KPIs problem in mega universities. It uses seven main criteria, among which are five enabler criteria of EFQM and two additional proposed criteria. e "TQM Hybrid MCDM Fuzzy Model" integrates three fuzzy MCDM methods including FAHP, FDEMATEL, and FVIKOR, treating ambiguity and uncertainty in the evaluation of higher education institutions and universities.
e "TQM Hybrid MCDM Fuzzy Model" was evaluated and analyzed by developing questionnaires to collect data about the current situation of mega university quality criteria at KAU as a case study example. ree questionnaires were designed including academic leaders and experts, academic staff, and students, respectively. e questionnaires were developed based on the results from surveys. e criteria and subcriteria of the "TQM Hybrid MCDM Fuzzy Model" are then identified. Considering the importance level among criteria and subcriteria, the "TQM Hybrid Fuzzy Model" indicated that the criteria that have achieved the highest score include "leadership (A2, A3, A4)," "policy and strategy (B1, B2, B3)," "people (C1)," "partnership & resources (D1)," "product, service, & process (E1)," "mega online distance learning (F1, F2)," and "scoring & ranking (G1)," respectively. By considering the importance level and influence level among criteria and subcriteria, it indicated that "leadership (A2, A3, A4)," "policy and strategy (B1)," "people (C1)," "partnership & resources (D1, D2)," "product, service, & process (E1)," "mega online distance learning (F1, F2, F3)," and "scoring & ranking (G1)," respectively, have achieved the highest score. ese results prove that the "TQM Hybrid MCDM Fuzzy Model" can enhance TQM-KPIs and can help in identifying strategic opportunities aiming to raise the level of quality services efficiently in mega universities. In future work, the complete software of the model will be embedded inside the KAU database library.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.