Exploiting GWmZd Model by Exploring Knowledge-Based Grey-Holistic Technique for Sustainable Vendor Evaluation

School of Management, Guangdong Polytechnic Normal University, Guangzhou 510665, China Department of Business Administration, Lebanese French University, Erbil, Kurdistan, Iraq College of Business Administration and Economics, Lebanese French University, Erbil, Kurdistan, Iraq Department of Mechanical Engineering, School of Studies in Engineering and Technology, Guru Ghasidas Vishwavidyalaya (A Central University), Bilaspur, Chhattisgarh, India


Introduction of Sustainability
e application of technological and performance measurement tools towards attaining the green-lean-economic architectures in vendor units is called as vendor sustainability. e vendor firms can gain the sustainability if firms preserve the cost-effective and best practices/processes, i.e., green, waste minimizing, and zero defects planning across production measures practices, as these practices holistically enable the vendor organizations sustainable at the global platform. It is sensed that numerous vendor organizations attain the sustainability by minimizing miscellaneous wastes, preserving the best green performance, and maintaining economic tradeoffs in their production units in the present era. It is ascertained by the literature survey that advancement in metrics-practices of the green-waste minimizing and zero defect (GW M Z D ) model advise the production companies to materialize the sustainability of vendor organizations, where the green measure stimulate the vendor companies to preserve the green manufacturing via ramping up the renewable energies utilization, abasing hazard materials byproducts, and recycling of waste water [1][2][3]. Next, minimization of waste leads to lean manufacturing and eradicate the vendor companies for reducing multiple wastes, i.e., idle time, over processing, unwanted production, and unnecessary movement. Zero defects planning instructs the vendor companies to trim down the defective products, salvaging, and reworks and leads in reducing the cost of the quality. Figure 1 shows the GWmZd model whose base pillars were taken from the manuscript published by [4].

Green Practice, Waste Minimization, and Zero Defects
Concept. Green practice/measure aids the industrialists to eliminate the causes of carbon attacks, minimization of illbiological particles, fossil fuels, hazard particles, ill-particles, and toxic gasses. Green practice/measure is utilized in the present era as it is considered as a leading competitive strategy to overcome the trust of product consumers. Green practice/measure can be attained by vendor firms by pursuing, such as advanced practices-metrics, i.e., renewable energy process, recycling of waste and hazard materials, and recycling of waste water. A green practice is a procedure to eliminate the amount of many wastes, which are produced during the production. In vendor firms, green practice is used as an effective process for butchery the waste production. Waste can be minimized if vendor firms pursue, such as advanced green metrics-practices, i.e., over processing, most excellent production, and effective movement.
Waste minimization refers to the lean manufacturing strategy, whose objective is the use of economic sources and recycling methods prior to disposal of the wastes. As per the United Nations Green Programme (UNGP), waste minimization refers a strategy that has the aim to prevent waste via upstream interventions. In case of production in vendor firms, these strategies are focusing the on optimizing resource and energy use and lowering toxicity levels during the manufacturing time. Strategies are considered to minimize waste and thus improve resource efficiency before the manufacturing process, i.e., product design, cleaner production, reuse of scrap material, improved quality control, and waste exchanges. Recently, it is observed that minimization of waste does not only eliminate the waste such as idle time, over processing, unwanted production, and unnecessary movement (aids to economic production) but also preserve the healthy green environment, resulting in higher productivity. Minimization of waste helps the vendor firms to achieve sustainability.
Zero defects motivate the vendor firms for abolishing the wastes at first (that leads to cost reduction).
us, zero defects leads to waste reduction along with cost cutting. All these processes improve the services and therefore, make customer pleasure. Zero defects can be attained by stimulating the vendor firm for pursuing, such as advanced metrics-practices, i.e., elimination of manufacturing of defective products, meager rejection of goods, and minimization of reworking and salvaging.

Literature Survey
Literature survey is conducted into two parts: in the first part, the literature survey is conducted in the context of green manufacturing, waste minimization, and zero defects philosophies for structure and framing the model.
Later, the literature survey is conducted in extant of the multiobjective optimization MOORA methods and grey set theory and their application towards measuring the sustainability of production and vendor firms.

Literature Survey is Conducted in the Context of Green
Manufacturing. In [5], the author said that the green stressors may be responsible for protecting the quality and quantity of freshwater resources. Reference [6] articulated an innovative green regulation, which was integrated with licensed Ireland's pharmaceutical manufacturing sector as a part of the case study. In [7], the authors stated that green audit is a management tool, which provides a structure and comprehensive mechanism for ensuring that the goods of an enterprise do not cause unacceptable effects on the atmosphere. Reference [8] proposed a model for appraising the worth of sustainable material providers. e expert's method was applied to distinguish the criterion for assessing the performance of traditional material providers and sustainable material providers. Reference [9] stated that green is a major source of greenhouse gas emissions (55%).
Reference [10] defined that an idea of sustainability can be built by optimizing the link among global society and its natural atmosphere, taking into account society's social, economic, and green chains. In [11], the authors stated that sustainability is an important goal such as promoting economic development, decreasing poverty, and improving quality. e green agenda is a necessary part of holistic, cityled strategies for economic, social, and green sustainability. In [12], the authors stated that green sustainability added the green value in the growing proportion of the world's population, lives in cities. Reference [13] proposed the sustainability tool to aware about the status of sustainability development in organizations by dimensions such as green, social, and economic. In [14], the authors proposed a double layers green supply chain efficient appraisement model for benchmarking the green alternative suppliers. A triangular fuzzy sets theory is used to handle vagueness of the supplier's model and select the most significant supplier. In [15], the authors determined during the case study of coal enterprises of China that various driving mechanisms, i.e., government regulations, enterprise resource capability, and supply chain, aid the global industries to attain the green innovation. Reference [16] developed a multiobjective decision-making hierarchical model, which integrated the forward and reverse logistics in objective to reduce the recycling and manufacturing costs in industries. Reference [17] investigated the united green innovation policy and pricing strategies in a remanufacturing system to attract the huge customers. In [18], the authors investigated the GSC as retailer's strategy. It is ascertained that GSC aids the retailer to improve their retail profit with poor promotional efforts.

Literature Survey is Conducted in the Context of Waste
Minimization Manufacturing. Reference [19] explained the principles and conceptions of reuse aspects in case studies of Ecosan in developing countries. Reference [20] outlined the nature of the wastes, waste generating industries, waste characterization, health and green implications of wastes management practices, steps towards planning, design and development of models for effective hazardous waste management, treatment, approaches, and regulations for disposal of hazardous waste. Evaluation of the entire situation with reference to Indian scenario has attempted in order that a better cost-effective strategies for waste management be evolved in future. Reference [21] developed a green vendor selection model, which is solved by application of the artificial neural network (ANN) with two more multiattribute judgment analyses (MAJA) techniques such as data envelopment analysis (DEA) and the analytic network process (ANP) [22]. Industry is a chief consumer of natural resources and a major donor to the overall pollution load. As per organization for economic cooperation and development, it accounts for about one-third of global energy consumption of their member states and for about 10% of the total water withdrawal. e relative contribution to the total pollution load is obviously higher for industryrelated pollutants, i.e., organic substances, sulfur dioxide, particulates, and nutrients. In [23], the authors said that lean and agile indicators can be jointed within supply chain. e authors also said that combining agility and leanness in one supply chain via the strategic utility of a decoupling point is called as legality. e legality model can be constructed in future. Reference [24] applied a fuzzy-based quality function deployment (QFD) on lean SC. A case study was conducted out in an Indian electronics switches manufacturing organization. e applied techniques were found so effective in the recognition of lean indicators, lean decision domains, lean attributes, and lean enablers for the business. Reference [25] proposed an agility lean model to evaluate the agility and leanness of an individual firm. e model consisted of a set of agile and lean supply chain practices integrated in an assessment model. Reference [26] estimated the leanness of a manufacturing firm in a fuzzy context. Various leanness indicators have been considered in order to measure the performance of the manufacturing firm by using the concept of the trapezoidal fuzzy number set [27]. Waste minimization is one of the strategies, adopted for minimizing the industrial pollution. e objective of the scheme is to assist the small and medium scale industry in adoption of cleaner production practices.

Literature Survey is Conducted in the Context of Zero
Defect (Six Sigma) Philosophy. In [28], zero defects philosophy is a thought that gained its focus from 1960s. It is a programme to take away defects from the industrial production and was primarily intended for automobile production [29]. Zero defects (ZDs) philosophy is a management tool, which has the aim to reduce the defects through preventions. Vendor firm's employees are directed to prevent mistakes by developing a constant, conscious desire to do their job right the first time. In [30], the Six Sigma tools have aims to process the best product quality. Six Sigma tools is the need of organization to build customized products. Reference [31] conducted a systematic review on Lean Six Sigma and found that the environmental (green) is the best method for improving the quality in manufacturing operations. Reference [32] investigated the application of Lean Six Sigma (LSS) tools in food processing industries. It is evaluated that LSS impact on environmental sustainability. Reference [33] proposed an integrated DEA technique with the Six Sigma projects evaluation model for selecting Six Sigma projects. e findings demonstrated that selected projects confirmed expert opinions. Reference [34] evaluated the university leadership performance by using the Lean Six Sigma (LSS) framework. Reference [35] constructed a structural measurement model by creating a link between Lean Six Sigma (LSS) and sustainable manufacturing strategies. Next, structural equation modeling technique is applied to validate the existing links.  [38] proposed the MOORA method to solve many economic, managerial, and construction problems. Reference [39] employed the MOORA method to define the economic policy for balanced regional development in Lithuania. Reference [40] applied the MOORA method in the construction field to solve the problems related to energy loss in heating buildings. Reference [41] explored the MOORA method to solve different decision-making problems in the real-time manufacturing green. Six decisionmaking problems are solved. Reference [42] presented the extended MOORA method for solving decision-making problems with interval data to determine the most preferable alternative among possible alternatives. Reference [43] extended the MULTIMOORA method with type-2 grey sets for solving the personnel selection problem under uncertain assessments.

Grey System
Application towards Achieving the Sustainability. Reference [44] utilized the grey set and rough set theory towards integrating the sustainability with the vendor selection procedure. Reference [45] compared conventional statistical tools with the grey system theory and declared the three superiorities of the grey system theory, i.e., (a) provides easy calculation, (b) requires few sample size, and (c) has an exact accuracy for prediction. Reference [46] proposed an efficient grey TOPSIS and grey COPRAS methodology with the vendor appraisement platform for vendor evaluation under green concerns. Reference [47] utilized the grey sets theory with integrated MULTIMOORA to benchmark the CNC machine tool under CNC machine tool evaluation criteria. Reference [48] suggested the outline of the grey set so that an upcoming researcher might use the concept for decision-making. Reference [49] extended the application of the grey theory in many decision-making problems. In [50], the authors applied the grey system theory with the expert panel method to set up evaluation index for the material provider. e performance of mass production by Commercial Aircraft Corporation of China Ltd (COMAC) was measured. Reference [51] proposed a fractional reverse accumulative grey Verhulst model to enhance the model stability and improve the prediction accuracy in responding to the characteristics of information on the test. In [52], the authors proposed a fractional order reverse accumulation generation gm model and revealed its applications in solving industrial problems. Reference [53] presented a new ranking method to determine the ranking order of the professionals. e authors built a novel graph model with grey information to solve equilibrium states and decision paths problem. In [27], the authors proposed a QFD network for the early design of a complex product, which demonstrated the top-down decomposition design process. Moreover, an uncertain multilevel programming model and its algorithm are proposed to aid the designers to get an optimal solution. Reference [54] described the way to control and utilize the grey system theory under lack of information or incomplete information. Reference [55] utilized grey concepts and the corresponding theories to develop a multiobjective grey wolf optimizer for handling multiple objectives optimization problems. Reference [56] presented the grey DEMATEL approach to identify and evaluate criterions and alternatives under incomplete information.

Motivation to Conduct Research Work, Especially for Sustainability
Sustainability is a thought, which mainly focuses to minimize the industrial wastes by ramping up the quality across processes with green and zero defects planning schemes and concerns. Sustainability can be attained via increasing the renewable energy processes, recycling of waste and hazard materials, recycling of waste water, over processing, most excellent production, effective movement, elimination of manufacturing of defective products, meager rejection of goods, and minimization of reworking. e sustainability assessment of supplier organizations must be carried out by production companies if production companies desire to sustain at global market for a long period of time [6,9,12,22].
(i) Recently, it is virtually investigated that previous authors proposed a single and a few double layers sustainability assessment hierarchical structural model in addressing fuzzy ratings-based simulation techniques such as TOPSIS, PROMATHEE, SAW, VIKOR, and MLMCDM for assessing sustainability of vendor firm alternatives. A few authors attempted for grey ratings evaluation techniques, but they were capable to solve only the single layer sustainability assessment hierarchical structural model. Aforesaid gaps are probed as a first research gap. (ii) It is also observed and probed by authors, especially focusing over the model structure and framing embedded with measures/metrics that previous researchers introduced ordinary measures practices and its interrelated metrics such as economic and employee retention in framing sustainably-based models (except focusing over the green, minimization of waste, and zero defect measures practices with their interrelated metrics in inducing into the model), and it is noticed as a second research gap. (iii) Furthermore, the authors observed via the same literature survey that a few proposed sustainabilitybased hierarchical structural models are facilitated with crisp AHP technique, but AHP was capable to tackle only fused or combined ratings (except individual rating of each member). Next, the crisp AHP weight evaluation method application is observed accompanied with single TOPSIS, PRO-MATHEE, SAW, VIKOR, and MLMCDM ratings evaluation techniques under only the fuzzy set (except grey set), for assessing sustainability of vendor firm alternatives is found as the third research gap. (iv) ere are no weight evaluation mathematical formulas, which can be used to calculate the weight of measures from metrics data (calculated by the AHP), and it is respected as a forth research gap. (v) e authors had no research evidence pertaining to grey-based holistic-robust technique that can deliver accurate results as reliability of decision is a big concern, and it is respected as the fifth research gap.
e aforesaid grounds motivated authors to develop the multilevel knowledge-based GWmZd sustainability appraisement hierarchical structural evaluation model, with introducing AHP with new weights, and global weight mathematical formula, with grey set-based holistic technique embedded with the dominance approach to compensate all research gaps.

Analytic Hierarchy Process (AHP).
Analytic hierarchy process (AHP) is one of the multipractices decision-making techniques. In short, it is a technique to derive ratio scales from paired comparisons [57,58]. e input can be obtained from the actual measurement such as price and weight or from the subjective opinion such as satisfaction feelings and preference. AHP allows some small inconsistency in judgment because human is not always consistent. e ratio scales are derived from the principal eigenvectors, and the consistency index is derived from the principal eigen value.
It is a tool used for solving complex decision problems to evaluate many dilemma in different areas of human requirements, such as political, financial, and various others different interests. e AHP provides a comprehensive and rational framework to help managers set priorities and make the best decision when both qualitative and quantitative aspects of a decision need to be considered. In conventional AHP, the pairwise comparison is established using a scale which converts the human preferences between available alternatives. Even though the discrete scale of AHP has the advantages of simplicity and ease of use, it is not sufficient to take into account the uncertainty associated with mapping of one's perception to a number. However, due to vagueness and uncertainty in the decision maker's judgment, a crisp, pairwise comparison with a conventional AHP may be unable to accurately capture the decision maker's judgment.
In the classical AHP, we consider an n × n a pairwise comparison matrix A with positive elements, such that From the geometrical means, the relative normalized weights of each attributes/criterions can be calculated by normalizing the geometrical means of raw in the comparison matrix. is can be presented in equations (1) and (2); the geometric means method of the AHP is explored to find out the relative normalized weights of the criterion due to its simplicity and easiness to find out the maximum eigen value and to reduce the inconsistency in judgment.

Calculation of matrices A 3 and A 4 such that
Determine the maximum eigen value (λ max ) , i.e., the average of matrix A 4 .
Consistency index is evaluated by the following equation:

Mathematical Problems in Engineering
For the index of consistency for random judgments, Saaty [57] defined the consistency ratio (CR) as where RI is chosen by the matrix size using the Saaty [58] ( Table 1) 4.2. Global Weights Equation [46].

eory of Grey Numbers: Mathematical Basis.
Grey theory has become a very effective method of solving uncertainty problems under discrete data and incomplete information. Grey theory has now been applied to various areas such as forecasting, system control, and decisionmaking and computer graphics. Here, we give some basic definitions regarding the relevant mathematical background of the grey system, grey set, and grey number in the grey theory [27,44,46,47,59,60].

Definition 2.
A grey system is defined as a system containing uncertain information presented by grey numbers and grey variables Definition 3. Let X be the universal set. en, a grey set G of X is defined by its two mappings: , and μ G (x) are the upper and lower membership functions in G, respectively. When μ G (x) � μ G (x), the grey number G becomes a grey set. It shows that the grey theory considers the condition of fuzziness and can flexibly deal with the fuzziness situation Definition 3. Definition 4A grey number is one of which the exact value is unknown, while the upper and/or the lower limits can be estimated. Generally grey number is written as Definition 5. If only the lower limit of G can be possibly estimated and G is defined as the lower limit grey number, Definition 6. If only the upper limit of G can be possibly estimated and G is defined as the upper limit grey number, Definition 7. If the lower and upper limits of G can be estimated and G is defined as the interval grey number, Definition 8. e basic operations of grey numbers ⊗x 1 � [x 1 , x 1 ] and ⊗x 2 � [x 2 , x 2 ] can be expressed as follows: Whitened value: e whitened value of an interval grey number, ⊗x, is a deterministic number with its value lying between the upper and lower bounds of interval ⊗x. For a given interval grey number ⊗x � [x, x], the whitened value x (λ) can be determined as follows [44,46,47,50].
where λ is the whitening coefficient, and λ ∈ [0, 1]. Because of its similarity with a popular λ function, formula (15) is often shown in the following form: For λ � 0.5, formula (16) gets the following form: Signed distance: let ⊗x 1 � [x 1 , x 1 ] and ⊗x 2 � [x 2 , x 2 ] be two positive interval grey numbers. en, the distance between ⊗x 1 and ⊗x 2 can be calculated as a signed difference between its centers as shown in the following equation: [46].

Evaluation of Rating from 2 nd to 1 st Level
By using equation (18), denominator R � ( ⊗ r j ) m×n , the computed i th rating of 1 st level measures vs alternatives j th , can be computed on availing assigned ratings data of 2 nd level metrics( ⊗ r ik ). C ikn is the number of metrics that are aligned with its father measure.
wherex ij is the response of alternative j on objective or attributei; j � 1, 2, . . . , m is the alternative; and i � 1, 2, . . . , n is the attribute. e MOORA method consists of two parts: the ratio system and the reference point approach [38].

e Ratio System Approach of the MOORA Method.
Reference [42] proved that the most robust choice for the denominator is the square root of the sum of squares of each alternative per objective, and therefore, the use of the vector normalization method is recommended in order to normalize responses of alternatives. As a result, the following formula is obtained: where x ij is the response of alternative j on objective or attribute i; j � 1, 2, . . . , m is the number of alternatives; i � 1, 2, . . . , n, where n is the number of objectives; x * ij is the normalized response of alternative i on objective j; and Let W � (w 1 , w 2 , . . . , w n ) be the relative weight vector about the practices, evaluated by grey AHP satisfying n i�1 w i � 1.
Calculate the weighted normalized decision matrix.

22)
For optimization based on the ratio system approach of the MOORA method, normalized responses are added in case of maximization and subtracted in case of minimization, which can be expressed by the following formula: where x * ij is the normalized response of alternative j on objectives i; i � 1, 2, . . . , g is the objective to be maximized; i � g + 1, g + 2, . . . , n is the objective to be minimized; j � 1, 2, . . . , m is the alternatives; and y * j is the overall ranking index of alternativej. y * j ∈ [−1, 1] provided and proved by [42].

e Importance Given to Objectives.
When solving real-world problems using MCDM methods, objectives do Mathematical Problems in Engineering not always have the same importance, i.e., some objectives are more important than the others. In order to give more importance to an objective, it could be multiplied with a significance coefficient [42]. Importance given to objectives has influence on the ratio system and reference point approach of the MOORA method. In the ratio system approach, importance given to objectives is included by modifying formula (23), which gets the following form: where s i is the significance coefficient of objectivei; i � 1, 2, . . . , g is the objective to be maximized; i � g + 1, g + 2, . . . , n is the objective to be minimized; j � 1, 2, . . . , m is the alternative; and y .. * j is the overall ranking index of alternative j with respect to all objectives with significance coefficients, y After that, formula (24) still remains to determine the most appropriate alternative based on the ratio system approach of the MOORA method.

4.5.3.
e Grey-MOORA. e procedure of selecting the most appropriate alternative using the MOORA method involves several important stages that should be considered before an extension of the MOORA method with interval grey numbers, and these are [43] Stage 1: transforming responses of alternatives into dimensionless values Stage 2: determining overall ranking indexes for considered alternatives based on the ratio system part of the MOORA method and Stage 3: determining distances between considered alternatives and the reference point based on the reference point part of the MOORA method Stage 1: transformation into dimensionless values For the normalization of responses of alternatives expressed in the form of interval numbers, suggested the use of the following formula: Formula (25) provides the appropriate form for normalizing responses of alternatives expressed by interval grey numbers. However, in cases of multipractices optimizations, which require simultaneously the use of crisp and interval grey numbers, the previously mentioned formula gives unsatisfactory results. Stage 2: determining overall ranking index based on the ratio system approach of the MOORA method for optimization based on the ratio system part of the MOORA method, we start from the formula where y * j is the overall ranking index of alternative j; y ∨ j and y ∧ j are the total sums of maximizing and minimizing responses of alternative j to objectives i, respectively; s i is the significance coefficient of objective i; x * ij or ⊗x * ij as the normalized responses of alternative j on different objectives i, which are expressed in the form on crisp or interval grey numbers; Ω G + are the assets of objectives to be maximized and expressed in the form on crisp or interval grey numbers, and Ω G − are the sets of objectives to be minimized and expressed in the form on crisp or interval grey numbers: (i) When decision makers have the same significance (λ � 0), (ii) When the decision maker has no preferences (λ � 0.5), (iii) When the decision maker has no preference and objectives have the same significance (λ � 1), During problem solution, i.e., ranking of alternatives, the attitude of the professionals can lie between pessimistic and optimistic, and the whitening coefficientλ allows the expression of professionals' degree of optimism or pessimism.
In the cases of particularly expressed optimism, the whitening coefficient λ, in accordance with the aforesaid formula, takes 8 Mathematical Problems in Engineering higher values (λ ⟶ 1), and the ranking order of alternatives is mainly based on the upper bounds of intervals with which the overall response of each alternative is expressed, y j(λ�1) � y * j . On the other hand, in the cases of particularly expressed pessimistic, the whitening coefficient λ takes lower values (λ ⟶ 0), and the ranking order of alternatives is mainly based on lower bounds of the intervals, y j(λ�0) � y * j . On the other hand, in the cases of particularly expressed moderate, the whitening coefficient λ takes half of lower and upper values (λ ⟶ 0.5), and the ranking order of alternatives is mainly based on lower bounds of the intervals, y j(λ�0.5) � y * j .
In the cases of particularly expressed optimism, the whitening coefficient λ, in accordance with formula (29), takes higher values (λ ⟶ 1), and the ranking order of alternatives is mainly based on the upper bounds of intervals with which the overall response of each alternative is expressed, y j(λ�1) � y + j . On the other hand, in the cases of particularly expressed pessimistic, the whitening coefficient λ takes lower values (λ ⟶ 0), and the ranking order of alternatives is mainly based on lower bounds of the intervals, y j(λ�0) � y + j . On the other hand, in the cases of particularly expressed moderate, the whitening coefficient λ takes half of lower and upper values (λ ⟶ 0.5), and the ranking order of alternatives is mainly based on lower bounds of the intervals, y j(λ�0.5) � y + j . Table 11: Aggregated importance against (C 1 -C 9 ), assigned by P 1,2,3,4,5 . 5.400 6.600 3.000 3.000 5.000 5.000 7.000 9.000 1.000

Empirical Research: Sustainability Evaluation of Alternative Organizations
e grey knowledge-based GWmZd sustainability appraisement hierarchical structural evaluation model is constructed by scrutinizing 3 (three) momentous measures and 9 (nine) interrelated metrics via the literature review of [4-6, 8-16, 18-22, 27, 28, 30, 34, 35, 61, 62]. e model is found valid towards assessing the sustainability of supplier organizations. e model's attitude and measures' definitions are shown in Tables 2-4, respectively. In the presented research work, 3 significant practices/measures, i.e., green, (C 1 ), waste minimization, (C 2 ), and zero defect, (C 3 ), are considered at the 1 st level, whilst identified and shortlisted 9     1 ), recycling of hazard material, (C 1 , 2 ), recycling of waste water, (C 1,3 ), over time, (C 2,1 ), unwanted manufacturing, (C 2,2 ), unnecessary work, (C 2,3 ), defective goods, (C 3,1 ), rejection rate, (C 3,2 ), and salvaging of materials, (C 3,3 ), are set up over the 2 nd level. e model has an objective to evaluate the sustainability scores of supplier organizations in application of dominance comparative analysis. To evaluate results, a committee of five highly experience professionals are formed from units of the case study manufacturing industry and requested to overview and judge the supplier partners/organizations. e procedure steps are following: Step 1: Verbal information has been collected by a committee of five highly experienced professionals (P), and a team is formed from the cross functional units of the material purchaser (production) industry. Information is collected from each member of a group of professionals (P) via the crisp AHP linguistic scale as shown in Table 5 in relation to 9 metrics. e assigned pairwise weights against 9 metrics are shown in  Tables 6-10 and aggregated by average rule, and data are shown in Table 11. Equations (1)-(5) are applied to compute weights against 9 metrics of the 2 nd level as shown in Step 2: Later, using the concept of the grey set theory, the grey variables, shown in Table 14, are used by the team of same five professionals (P) to assign grey ratings against supplier organizations, i.e., A 1 , A 2 , and A 3 . e assigned grey ratings are aggregated by equation (13) as shown in Tables 15-17 and  Tables 18-20 against suppliers, i.e., A 1 , A 2 , and A 3 .
Step 3: en, to compute grey global rating of the 1 st level measures from the 2 nd level metrics, equation (18) is utilized to jump from the 2 nd level to the 1 st level as shown in Tables 18-20. Grey global rating matrix computed for organizations A 1 , A 2 , and A 3 is depicted in Table 21.
Step 4: en, normalization is carried out by using equation (25) for bringing grey set values in the interval of 0-1 excluding transforming the nonbeneficial criterion into beneficial measures as shown in Table 22.
en, global weights are multiplied by its measures and constructed the weighted normalized matrix by using equation (22), shown in Table 23.
Step 5: Grey-MOORA is applied on the data available in Table 23. Ranking results are obtained using MOORA technique by equation (26), and ranks computed for λ � 0, 0.5, 1 by using equations (27)- (29) shown in Table 24. Grey-Full multification    Applications e proposed grey knowledge-based GWmZd sustainability appraisement hierarchical structural evaluation model can be explored for measuring the sustainability of alternative vendor organizations under the proposed grey set-based approach with the dominance theory. Benchmarking and several election problems of industries, i.e., trucks, cranks, and hand trucks, can also be solved by using same research forum.
Limitations e model is found versatile in nature. It can solve the many decision-making problems, i.e., the evaluation problem of facility locations and routes for new manufacturing firm by replacing the chain of sustainability assessment measures and their interrelated metrics corresponding to defining alternatives. However, single and multivariables linear programming problem under the boundary constraint value cannot be solved. Economic values Proposed model neither requires a specific software nor high skill professional. It can be solved by excel sheet.

Commercial values
Proposed model is sharable with other manufacturing firm by e-mail, fax, and other electronic media. e proposed research work is suitable for solving many problems of the manufacturing firm on extension/exchange of the chain of sustainability appraisement measures and their interrelated metrics against defining or facing alternatives.
form is applied on the data available in Table 23.
Step 6: e preference's order vs sustainability of supplier organizations under GWmZd measures is obtained by exploring the comparative analysis at λ � 0, 0.5, 1 as shown in Table 26. It is found that A 1 is the more sustainable supplier than others. It must be the elected material purchasing company for placing orders (Table 27).

Applications, Practical Implications, Economic Values, Commercial Values, and Limitations
Applications, practical implications, economic values, commercial values, and limitations are provided in Table 27 7

. Conclusions
In the presented research work, the grey knowledge-based GWmZd sustainability appraisement hierarchical structural evaluation model is constructed by the literature survey, consisted of 3 measures, i.e., green, (C 1 ), waste minimization, (C 2 ), and zero defect, (C 3 ) and 9 measures' interrelated metrics. e authors applied the AHP in addressing individual rating of each expert and aggregated all the expert opinion vs 9 metrics as weights. Later, global weights are computed vs 3 measures. Eventually, the grey-holistic approach amalgamated with the dominance theory [37,39,41,42] is applied in order to get consistent results with respect to attitude of experts, i.e., λ � 0, 0.5, 1. Eventually, it is found that sustainability of 1 st vendor candidate alternative is the best. It must be elected by production firm for placing order. e others conclusions are given in below section: (i) e presented grey knowledge-based GWmZd model can be powered by Microsoft Windows XP, and manual computation is also possible (ii) Proposed GWmZd models can be extended with the advance chain of sustainability appraisement measures and their interrelated metrics against defining alternatives with the grey-holistic approach merged with dominance theory to compute robust results (iii) Proposed work does not require a special support of the software. It could be solved by excel sheet. (iv) e authors developed and proposed new mathematical equations, assisted authors to evaluate the global weight of first layer-three pillars from second level metrics e future scope of the presented research work is that the novel GWmZd model can be constructed with advanced sustainability measures and their interrelated metrics in future. e decision can be simulated by using the same grey-holistic approach fused with the dominance theory.

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 there are no conflicts of interest.