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Article

Sustainable Renewable Energy Source Selection Using a Machine Learning-Integrated Elliptic Intuitionistic Fuzzy Muirhead Mean Framework

by
Vasudevan Tharakeswari
1,
Meenakshi Sundaram Kameswari
1,* and
Shanmugavel Krishnaprakash
2
1
Department of Mathematics, Kalasalingam Academy of Research and Education, Krishnan Koil 626126, India
2
Department of Mathematics, Sri Krishna College of Engineering and Technology, Coimbatore 641008, India
*
Author to whom correspondence should be addressed.
Mathematics 2026, 14(10), 1633; https://doi.org/10.3390/math14101633
Submission received: 23 March 2026 / Revised: 26 April 2026 / Accepted: 28 April 2026 / Published: 11 May 2026
(This article belongs to the Topic Fuzzy Optimization and Decision Making)

Abstract

Over the past few decades, extensive attention has been given by researchers and practitioners to the development and application of multi-criteria decision-making (MCDM) methods within intuitionistic fuzzy environments across a wide range of fields and disciplines. This challenging research area has emerged as one of the most prominent topics, and its importance and popularity are expected to continue growing in the future. The elliptic intuitionistic fuzzy set (EIFS) addresses complex, multidimensional, non-symmetrical vagueness and uncertainty more effectively than other traditional intuitionistic fuzzy sets (IFSs). Sustainable renewable energy source selection is a critical decision-making (DM) process aiming to identify the most suitable energy alternative. The process of selecting sustainable renewable energy sources necessitates a comprehensive assessment of numerous criteria, which encompass environmental ramifications, economic feasibility, and societal acceptance. Contemporary research suggests novel methodologies to enhance this selection process, highlighting the need for an MCDM framework that integrates a variety of factors. This study presents an innovative DM framework for sustainable renewable energy source selection based on EIFS and a newly developed aggregation operator, the Elliptic Intuitionistic Fuzzy Weighted Muirhead Mean Aggregation (EIFWMMA) operator. These mechanisms expand upon conventional intuitionistic fuzzy frameworks by employing an elliptical portrayal of membership and non-membership degrees, facilitating a more accurate and lifelike representation of uncertainty and hesitation in evaluations by experts. To enhance computational efficiency, the framework weaves together machine learning-driven dimensionality reduction and weight optimization strategies of principal component analysis (PCA) for DM. The suggested operators are employed in an MCDM scenario centered around the selection of sustainable renewable energy sources, where the hierarchy of alternatives is established through score values derived from EIFWMMA. A comparative exploration of Circular Intuitionistic Fuzzy Sets (C-IFSs) and Interval-Valued Intuitionistic Fuzzy Sets (IVIFSs) uncovers that the elliptical formulation yields consistently reliable, precise, and geometrically comprehensible results. The findings affirm that EIFS-based operators offer a resilient, adaptable, and broadly applicable strategy for tackling MCDM challenges amidst uncertainty. The Min–Max normalization method is employed to validate our proposed methodology for identifying alternatives within the MCDM paradigm. It also improves accuracy, stability, and scalability in comparison to conventional approaches.

1. Introduction

The escalating global demand for energy, in conjunction with the detrimental environmental repercussions of fossil fuel utilization, has rendered the transition to sustainable renewable energy sources an imperative priority. Renewable energy modalities, including biomass, hydropower, geothermal, wind, solar, and tidal energy, present ecologically sound alternatives that have the potential to substantially diminish greenhouse gas emissions while fostering long-term energy security.
Nonetheless, the identification of the most appropriate renewable energy source constitutes a multifaceted DM challenge. This process necessitates the evaluation of numerous criteria, encompassing energy efficiency, environmental ramifications, reliability, resource availability, land, and water footprints, as well as social and policy acceptability. Such criteria frequently exhibit conflicting and uncertain characteristics, thereby complicating the selection procedure. To navigate this complexity, sophisticated decision-making methodologies, particularly MCDM techniques, are extensively employed. These methodologies facilitate the systematic analysis and ranking of alternatives by decision-makers, based on a variety of quantitative and qualitative dimensions. The incorporation of uncertainty through fuzzy and intuitionistic fuzzy frameworks further bolsters the resilience of the DM process. Consequently, the selection of sustainable renewable energy sources is pivotal in the pursuit of energy sustainability, environmental conservation, and economic advancement, thereby ensuring a balanced and efficient energy future.
Intuitionistic fuzzy sets (IFSs) extend conventional fuzzy sets by incorporating hesitancy alongside membership and non-membership, facilitating a more minute and accurate depiction of uncertainty and ambiguity. Introduced by Atanassov in the year 1986, IFSs are especially beneficial in DM and evaluative contexts where linguistic descriptions may be more confusing because of the effect of hesitancy in DM. In practice, MCDM often reflects a scenario marked by limited information, varying expert opinions, and the presence of hesitancy in experts’ opinions and in uncertainty. IFSs were formulated to encapsulate such hesitancy present in ambiguity/uncertainty by delineating distinct degrees to it, whereas IVIFSs further refined this methodology by permitting these degrees to exist within predetermined intervals. Geometrical extensions of the IFS, such as triangular, trapezoidal, etc., reconceptualize uncertainty, ambiguity, and imprecision as regions encompassed within the IFS interpretation. The C-IFS framework shifts from a sharp-edged geometrical structure to a structure with a smooth surface with the center at (Է, Ը), where the radius captures the uncertainty/ambiguity. This conceptual framework has been integrated with conventional MCDM methodologies to develop novel aggregation families aimed at enhancing resilience against informational dispersion. Advancing this smooth surface geometric paradigm, the EIFS framework extends anisotropic uncertainty, specifically, varying degrees of dispersion along the major and minor axes.
These advancements suggest that the EIFS holds promise for enabling more sophisticated and geometrically significant aggregation and ranking methodologies in comparison to C-IFSs and IVIFSs. Building upon this established trajectory, the current investigation introduces a novel operator, EIFWMMA, which integrates PCA, a machine learning-based dimensionality reduction, and weighted optimization techniques to enhance computational efficiency when addressing wide-ranging decision matrices. In this context, the selection of sustainable renewable energy sources is engaged for illustration. In this illustration, the rankings derived from EIFWMMA are compared with the benchmarks of C-IFS and IVIFS to highlight improvements in accuracy and consistency under uncertain conditions. The Min–Max normalization method confirms that the proposed framework authenticates the selection of optimal alternatives within other existing MCDM frameworks.

1.1. Literature Review

IFSs were introduced by Atanassov in 1986, advancing traditional fuzzy sets by integrating not only degrees of membership but also non-membership and hesitation parameters. This theoretical framework facilitates a more intricate depiction of uncertainty and imprecision, rendering IFSs particularly advantageous in a myriad of applications, encompassing DM processes and mathematical modeling [1]. IFSs provide a sophisticated methodology for modeling uncertainty, augmenting traditional fuzzy sets through the inclusion of both membership and non-membership degrees. This duality engenders a more elaborate representation of uncertainty, which may be geometrically interpreted through various perspectives. The geometric representation of IFSs not only contributes to the visualization of their intrinsic properties but also amplifies their applicability in DM frameworks. The following delineates key elements of geometric representation within intuitionistic fuzzy sets. To improve decision-making by matching preferences for optimal outcomes, the paper presented a novel aggregation operator for Generalized Intuitionistic Fuzzy. These operators are distinguished by characteristics like Idempotency and Monotonicity [2]. This paper presented new logarithmic operational laws for intuitionistic fuzzy sets. It presents a variety of aggregation operators [3]. In 2020, Atanassov presented C-IFSs, which are an expansion of intuitionistic fuzzy sets. A circular representation of each element, delineated by degrees of participation and non-membership, is a defining characteristic of C-IFSs [4]. C-IFSs represent a sophisticated enhancement of IFS, introduced to address uncertainty and indecision more effectively in processes of decision-making. C-IFSs are distinguished by a circular representation, wherein each component is articulated through degrees of membership and non-membership, with a radius denoting the degree of uncertainty. This paradigm shift facilitates a more intricate representation of data, which is particularly advantageous in multifaceted DM contexts. The utilization of C-IFSs across diverse methodologies, including TOPSIS and AHP, exemplifies their adaptability and efficacy in mitigating indecision and augmenting the precision of decision outcomes. The high levels of hesitation that might arise during DM processes, especially in situations with little uncertainty, are addressed by this approach. To address this hesitancy, one paper suggests a technique for determining decision-maker weights using the TOPSIS technique [5]. BWM determines the relative weights of criteria within the hierarchy, capturing decision-makers’ preferences effectively. In the second phase, FHRA assesses qualitative risks by computing risk magnitudes from the lowest level and aggregating them upward through the hierarchy. Additionally, the multimodal transport cost model estimates both transportation cost and time [6].
By successfully capturing vagueness and uncertainty in multi-attribute scenarios, one paper presented several aggregation operators for complex intuitionistic fuzzy information, such as CIF Hamacher weighted averaging, ordered weighted averaging, weighted geometric, and ordered weighted geometric operators. These operators improve decision-making abilities [7]. Various weighted averaging and geometric operators are among the Frank aggregation operators for interval-valued intuitionistic fuzzy numbers that are introduced in another study [8]. Using Einstein operations, one paper presented intuitionistic fuzzy aggregation operators that extend conventional aggregation techniques to Atanassov’s intuitionistic fuzzy values [9]. Improved versions of IFS and C-IFS were intended to handle ambiguities and uncertainties in decision-making. They used a circular structure that improved the way degrees of membership and non-membership were represented, enabling a more sophisticated interpretation of the data. This novel method helps managers make well-informed decisions in the face of complicated environmental factors, which is especially helpful in MCDM contexts like the manufacturing industry [10].
A paper by Atanassov and Gargov (1989) [11] introduces IVIFSs, which generalize fuzzy set theory by incorporating a membership range and a non-membership range, enhancing the modeling of real-life decision-making problems. IVIFSs presented necessary modifications and a new eighth geometrical interpretation alongside comparisons of existing representations [12]. Two geometrical representations of intuitionistic fuzzy sets visualized the connections between membership and non-membership degrees; these representations improve comprehension of intuitionistic fuzzy sets in a variety of settings [13]. To facilitate efficient ranking, one study presents a geometric representation of intuitionistic fuzzy values based on Euclidean distance [14]. Another study presented the Interval Valued C-IFS, which improves the capacity to account for uncertainty and encompasses a wider range of topics, especially in intricate assessments like the selection of digital transformation projects [15].
The Muirhead mean [16], introduced by Muirhead in 1902, serves as a generalized aggregation function. Muirhead means (MMs) are a well-known aggregation operator that can consider interrelationships among any number of arguments assigned by a variable vector, and some existing operators, such as arithmetic and geometric operators, the Bonferroni mean operator and the Maclaurin symmetric mean are special cases of MM operators [17]. Therefore, the MM can offer a flexible and robust mechanism to process information fusion problems and make them better suited to solve MCDM problems. The MM aggregation operator has been successfully expanded to IFSs to improve DM procedures. This modification, referred to as the Intuitionistic Fuzzy Muirhead Mean (IFMM), enables the amalgamation of intuitionistic fuzzy numbers, thereby encapsulating the interconnections among various criteria in group DM environments. The subsequent sections delineate the principal characteristics of this operator’s implementation within intuitionistic fuzzy frameworks. The MM operator has been extended to IFNs to create IFMM operators, enabling flexible aggregation of multi-attribute group decision-making problems while considering interrelationships among the arguments through a parameter vector [18]. Researchers addressed multi-attribute group DM problems by developing methods that aggregate individual decision matrices using IFMM operators [19].
EIFS constitute a progressive paradigm for managing uncertainty in DM processes. By assimilating elliptic membership and non-membership functions, these sets refine conventional intuitionistic fuzzy logic systems, facilitating more sophisticated representations of uncertainty. The ensuing sections expound upon the fundamental elements of elliptic intuitionistic fuzzy sets. The concept of elliptic intuitionistic fuzzy sets, as introduced by Atanassov, represents an advancement in the field of fuzzy logic by incorporating the geometric flexibility of ellipses into an intuitionistic fuzzy framework. This approach enhances the ability to model and analyze complex systems with inherent uncertainty and imprecision. EIFSs extend traditional intuitionistic fuzzy sets by allowing for more adaptable and versatile representations of data, which is particularly useful in DM processes [20]. EIFS are characterized by elliptical aggregation operators, which adapt to various point distributions. They enhance decision-making in MCDM by ranking alternatives based on their proximity to ideal options, accommodating diverse spatial patterns [21]. MCDM techniques like AHP, TOPSIS, and MOORA systematically select sustainable renewable energy sources. Researchers have established criteria across environmental, economic, and technical domains, facilitating informed DM and addressing conflicting objectives in High Renewable Energy System selection [22]. The TOPSIS and AHP methods for evaluating and selecting optimal renewable energy sources highlights solar energy as the most suitable option for sustainable energy planning in Egypt [23]. Grey analytic hierarchy processes and weighted aggregate sum product assessment were used to select sustainable renewable energy sources. Solar energy emerged as the optimal choice, followed by wind, biomass, and solid waste energy [24]. Another paper identifies the limitations of conventional synthesis methods for selecting renewable energy sources, highlighting their arbitrary nature and the difficulty of determining rescaling weights [25]. To enhance the fuzzy environment for the selection of suitable renewable energy sources by the TOPSIS method, researchers integrated the proposed entropy and distance measures into its framework [26]. An investigation of biodegradable oil-based minimum quantity lubrication (MQL) parameters for sustainable grinding of H13 die steel reveals significant advancements in eco-friendly machining practices. The use of biodegradable oils, such as Jatropha crude oil and olive oil, showed promising results in enhancing machinability while minimizing environmental impacts [27]. Other researchers have normalized closeness coefficients using the Min–Max normalization method [28].
In the context of sustainable renewable energy source selection, the enhanced aggregation operator EIFWMMA remains unexplored in MCDM applications. The integration of PCA effectively reduces redundancy and improves computational efficiency, while its adaptation for eliminating less significant criteria has not yet been applied within EIFS-based MCDM frameworks. Furthermore, the use of PCA based on machine learning to derive criteria weights in EIFS MCDM problems is still insufficiently addressed in the existing literature.
The existing literature on MCDM methods in intuitionistic fuzzy environments contains significant contributions; however, several limitations remain. Extensions such as Circular IFS (C-IFS) and Interval-Valued IFS (IVIFS) improve representation but often have redundancies or fail to capture directional uncertainty effectively. Traditional intuitionistic fuzzy sets (IFSs) assume symmetric and independent uncertainty, which restricts their applicability in complex real-world problems which possess nonlinearity along with asymmetricity.
Moreover, most existing aggregation operators rely on linear combinations and assume independence among criteria, thereby neglecting interrelationships and interaction effects. These limitations reduce the accuracy and reliability of decision outcomes in practical scenarios. Therefore, there is a need for advanced models like EIFS and EIFWMMA that can simultaneously address nonlinearity, asymmetric uncertainty and interdependent criteria in MCDM problems.

1.2. Research Gap

  • The enhanced aggregation operator EIFWMMA has not been previously explored in MCDM problems.
  • Implementation of PCA eliminates redundancy and enhances computational efficiency. Tailoring of PCA to reduce sluggish criteria has not been used yet in EIFS MCDM problems.
  • Also, PCA with machine learning has not been effectively used to determine criteria weights in EIFS MCDM problems in the literature.
  • Geometric representations have not been extensively or effectively utilized in EIFS MCDM processes; however, when compared with conventional averaging approaches, geometric methods demonstrate the potential to provide higher accuracy and more reliable outcomes.
  • This limitation significantly reduces their effectiveness in complex MCDM applications, particularly in the selection of sustainable renewable energy sources.
  • The identified shortcomings highlight a substantial research gap, justifying the necessity of elliptic fuzzy formulations and tailoring with machine learning techniques (PCA) to achieve more realistic and robust decision modeling in the selection of sustainable renewable energy sources.

1.3. Motivation

In 1987, Wold, Esbensen, and Geladi [29] presented a seminal tutorial on principal component analysis (PCA) in Chemometrics and Intelligent Laboratory Systems, firmly establishing PCA as a fundamental technique for multivariate data analysis. The inadequate exploitation of potential insights derived from insufficiently scrutinized integrations of MCDM and PCA undermines the efficacy of DM processes. Building on this rationale, the present study identifies and develops novel decision-support methodologies that integrate PCA and EIFS-MCDM. It examines the techniques used for deriving criteria weights, evaluating the performance of alternatives and validating the adequacy of PCA within the DM framework. The selection of sustainable renewable energy sources involves multiple conflicting criteria such as cost, environmental impact, efficiency, and reliability, making it a complex MCDM problem under uncertainty.

1.4. Objectives of the Study

  • To propose the EIFWMMA operator within the MCDM framework.
  • To develop a score function-based approach for evaluating alternatives across multiple criteria, aiming to improve the accuracy of decision analysis.
  • To demonstrate the applicability and effectiveness of EIFS and the proposed EIFWMMA operator through a comprehensive numerical case study.
  • To validate the superiority of EIFSs over traditional fuzzy frameworks in terms of intuitive data interpretation, visualization of complex decision structures, and overall decision accuracy.
  • To develop an advanced MCDM framework for sustainable renewable energy source selection under uncertain environments.
  • Its practical implications span several domains like medical diagnosis and healthcare, risk assessment and safety systems, supply chains and logistics, etc.

1.5. Preliminary Concept

1.5.1. Definition [1]

Let a set Y be fixed. An IFS K in E is defined as K = { y ,   Է K y ,   Ը K y   | y   E } which assigns to each element y a membership degree Է K y and a non-membership degree Ը K y . Where Է K y , Ը K y ≥ 0, with the condition 0 ≤ Է K y + Ը K y ≤ 1, for all y   E , In addition, π k y = 1 − Է K y Ը K y is called a hesitancy degree or an intuitionistic index of y to K, which represents the indeterminacy degree of y to K. Each pair of ( Է K y , Ը K y ) in K is called an IFN.

1.5.2. Definition [4]

Let us have a fixed universe E and its subset K. The set K = { y ,   Է A y ,   Ը A y   | y E }, where 0 ≤ Է K y + Ը K y ≤ 1 and r ˇ   [0, 1] is the radius of the circle around each element y E is called C-IFS and Է K : E → [0, 1] and Ը K : E → [0, 1] represent the degree of membership (validity, etc.) and non-membership (non-validity, etc.) of element y   E to a fixed set K E. Now, we can also define function π K y K : E→ [0, 1] by means π K y = 1 − Է K y Ը K y , and it corresponds to the degree of indeterminacy (uncertainty, etc.).

1.5.3. Definition [20]

An EIFS K Է ,   Ը is defined as K Է ,   Ը = { y ,   Է K y ,   Ը K y , Ժ , Ք | y   E } , where Է K : E → [0, 1] is the degree of membership of y   E , Ը K : E→ [0, 1] is the degree of non-membership of y   E , and 0 ≤ Է K y +   Ը K y ≤ 1 for all y   E ,   π K y   =   1 Է K y Ը K y .
The center Է ( y ) = t y + g ( y ) 2 ; Ը ( y ) = p y + s ( y ) 2 ; e(y) = s y p ( y ) g y t ( y ) , and Ժ , Ք   [0, 1] are the semi-major and semi-minor axes.
Ժ y = t ( y ) 2 + ( g y t ( y ) s y p ( y ) ) 2   p ( y ) 2 ,
Ք y = p ( y ) 2 + ( s y p ( y ) g y t ( y ) ) 2   t ( y ) 2 of the ellipse associated with y E ,
where t y = min 1 i q y Է ( y i ) , p y = min 1 i q y Ը ( y i ) ,
g y = max 1 i q y Է ( y i ) , s y = max 1 i q y Ը ( y i ) ,
where i = 1, 2, 3, …, q.
The geometrical interpretation of the E-IFS is represented in Figure 1.

1.5.4. Definition [20]

Let θ j = Է θ j , Ը θ j , Ժ θ j , Ք θ j , (j = 1, 2, 3, …, n) be EIFSs over the universal set E and α > 0, where * {min, max} if ( Ժ = ϣ , Ք = Ϩ ). θ 1 Ժ , Ք   θ 2 Ժ , Ք = { y ,   Է θ 1 y +   Է θ 2 y Է θ 1 y .   Է θ 2 y ,   Ը θ 1 y . Ը θ 2 y ; Ժ , ϣ , ( Ք , Ϩ ) | y   E }
θ 1 Ժ , Ք θ 2 Ժ , Ք = y ,   Է θ 1 y .   Է θ 2 y   ,   Ը θ 1 y + Ը θ 2 y Ը θ 1 y . Ը θ 2 y ; Ժ , ϣ , ( Ք , Ϩ ) | y   E } .

1.5.5. Definition [16]

Let φ j = (Էj, Ըj), (j = 1, 2, 3, …, n) be a collection of non-negative real numbers and
D = ( d 1 , d 2 d n ) Rn be a vector of parameters if
IFMM D ( φ 1 , φ 2 φ n ) = ( 1 n !     σ s n j = 1 n φ σ ( j ) D j ) 1 j = 1 n D j
where σ ( j ) is any permutation and s n is the collection of all permutations of (1, 2, …, n).
From Equation (1), we know that:
If   D   =   ( 1 ,   0 ,   0 ,   ,   0 ) ,   the   MM   reduces   to   MM ( 1 , 0 0 )   ( φ 1 , φ 2 φ n ) =   1 n j = 1 n φ j
where n is the arithmetic averaging operator.
If ( 1 n , 1 n , …, 1 n ) , the MM reduces to M M ( 1 n ,   1 n 1 n ) ( φ 1 , φ 2 φ n ) = j = 1 n φ j 1 / n
which is the geometric averaging operator.
If D = (1, 1, 0, 0, …, 0), the MM reduces to MM(1,1,0…0) ( φ 1 , φ 2 φ n ) = ( 1 n ( n 1 ) i , j = 1 n φ i φ j ) 1 / 2
where i ≠ j, which is the Bonferroni mean operator.
If D = {1, 1, …, 1, 0, 0, …, 0}, the MM reduces to
MM(1,1,…1,0,0…0) ( φ 1 , φ 2 φ n ) = ( 1 i 1   < . < i k   n j = 1 ) C n k 1 / k 1 / k , which is the Maclaurin symmetric mean.
MM   ( φ 1 , φ 2 φ n )   = ( 1 n !     ( . σ s n (   φ σ j ) D j ) ) 1 j = 1 n D j
Then Equation (2) is called the MM aggregation operator and Equation (1) is called the IFMM aggregation operator.
Numerical Example for Equation (1):
Consider three intuitionistic fuzzy values, φ 1 = 0.6, φ 2 = 0.8, and φ 3 = 0.7, and the corresponding weight vectors D = (1, 2, 1).
IFMM D = 1 6 ( ( 0.6 1 × 0.8 2 × 0.7 1 ) + ( 0.6 1 × 0.7 2 × 0.8 1 ) + ( 0.8 1 × 0.6 2 × 0.7 1 ) +                                           ( 0.8 1 × 0.7 2 × 0.6 1 ) + ( 0.7 1 × 0.6 2 × 0.8 1 ) + ( 0.7 1 × 0.8 2 × 0.6 1 ) ) 1 / 4 = 0.696                                                                                                                                                                                  

2. Development of EIFS Aggregation Operators and Properties

Aggregation Operator EIFWMMA:
Let φ j = (Էj, Ըj), j = 1, 2, ..., n) be a collection of IFNs; then, the elliptic intuitionistic fuzzy aggregation result can be obtained by Section 1.5.4 and Section 1.5.5.
φ σ j D j = { Է σ j D j , 1 ( 1 Ը σ j ) D j , min   Ժ σ j ,   min Ք σ j }
(   φ σ j ) D j = { j = 1 n Է σ j D j , 1 j = 1 n ( 1 Ը σ j ) D j , min   Ժ σ j ,   min Ք σ j }
( . σ s n (   φ σ j ) D j ) = { 1 σ s n .   ( 1 j = 1 n Է σ j D j ) ,   σ s n .   ( 1 j = 1 n ( 1 Ը σ j ) D j , min   Ժ σ j ,   min Ք σ j )
( 1 n !     ( . σ s n (   φ σ j ) D j ) ) = { 1 σ s n n   ( 1 j = 1 n Է σ j D j ) 1 / n ! , σ s n .   ( 1 j = 1 n ( 1 Ը σ j ) D j ) 1 / n ! , min   Ժ σ j ,   min Ք σ j } M   ( φ 1 , φ 2 φ n )   = ( 1 n !     ( . σ s n (   φ σ j ) D j ) ) 1 j = 1 n D j = { ( 1 ( σ s n n   ( 1 j = 1 n Է σ j D j ) ) 1 / n ! ) 1 j = 1 n D j , ( 1 ( 1 σ s n .   ( 1 j = 1 n ( 1 Ը σ j ) D j ) 1 / n ! ) ) 1 j = 1 n D j , min   Ժ σ j ,   min Ք σ j }
Equation (6) is the EIFWMMA operator.

2.1. Property 1—(Idempotency Property)

If all φ j (j = 1, 2, 3, …, n) are equal, φ j =   φ = ( Է , Ը , Ժ , Ք ) , then
EIFMM D   = ( φ 1 , φ 2 φ n ) = φ
Proof. 
EIFMMD  = {(1 − σ s n n   ( 1   j = 1 n Է σ j D j ) ) 1 / n ! ) 1 j = 1 n D j , (1 − (1 σ s n .   ( 1   j = 1 n ( 1 Ը σ j ) D j ) 1 / n ! ) ) 1 j = 1 n D j , min Ժ σ j ,   min Ք σ j } by (3)
= { ( 1 ( σ s n n   (   1 Է σ j j = 1 n D j   ) ) 1 / n ! ) 1 j = 1 n D j , ( 1 ( 1 σ s n .   (   1 ( 1 Ը σ j ) j = 1 n D j   ) 1 / n ! ) ) 1 j = 1 n D j , min   Ժ σ j ,   min Ք σ j } = { ( 1 ( (   1 Է σ j j = 1 n D j ) n ! ) 1 / n ! )   1 j = 1 n D j   , ( 1 ( 1 ( 1 ( 1 Ը σ j ) j = 1 n D j ) n ! ) 1 / n ! ) 1 j = 1 n D j , min   Ժ σ j ,   min Ք σ j } = { ( 1 (   1 Է σ j j = 1 n D j )   )   1 j = 1 n D j   , 1 ( 1 ( 1 ( 1 Ը σ j ) j = 1 n D j ) ) 1 j = 1 n D j , min   Ժ σ j ,   min Ք σ j } = { Է σ j , 1 ( 1 Ը σ j , Ժ σ j ,   Ք σ j ) } = ( Է , Ը , Ժ , Ք )
If all φ j (j = 1, 2, 3, …, n) are equal, φ j =   φ = ( Է , Ը , Ժ , Ք ) , then
EIFMM D = ( φ 1 , φ 2 φ n ) = φ

2.2. Property 2—(Monotonicity)

Let φ j =   ( Է j ,   Ը j , Ժ j , Ք j ) and φ j = ( Է j , Ը j , Ժ j , Ք j ) , j = 1, 2, …, n.
EIFMM D = ( φ 1 , φ 2 φ n )   EIFMM D = ( φ 1 , φ 2 φ n )
Proof. 
Է = ( 1 ( σ s n n   ( 1 Է σ j j = 1 n D j   ) ) 1 / n ! ) 1 j = 1 n D j Է = ( 1 - ( σ s n n   ( 1 Է σ j j = 1 n D j   ) ) 1 / n ! ) 1 j = 1 n D j Ը = 1 ( 1 ( 1 ( 1 Ը σ j ) j = 1 n D j ) ) 1 j = 1 n D j Ը = 1 ( 1 ( 1 ( 1 Ը σ j ) j = 1 n D j ) ) 1 j = 1 n D j
Since Է j   Է j .
Similarly, we also have Ը j Ը j , Ժ j   Ժ j , Ք j Ք j .
φ j = ( Է j ,   Ը j , Ժ j , Ք j )   and   φ j = ( Է j , Ը j , Ժ j , Ք j ) ,   j   =   1 ,   2 ,   ,   n
EIFMM D = ( φ 1 , φ 2 φ n )   EIFMM D = ( φ 1 , φ 2 φ n )

2.3. Property 3—(Boundedness)

Let φ j =   ( Է j ,   Ը j , Ժ j , Ք j ) , (j = 1, 2, …, n) be an EIFMM,
φ = ( min ( Է j ) ,   m a x ( Ը j ) , m i n ( Ժ j ) , m i n ( Ք j ) )
φ + = ( max ( Է j ) ,   m i n ( Ը j ) , m a x ( Ժ j ) , m a x ( Ք j ) )
Then φ EIFMMD ( φ 1 , φ 2 φ n )   φ + .
Proof. 
According to Properties 1 and 2
EIFMM D = ( φ 1 , φ 2 φ n )   EIFMM D = ( φ , φ φ ) = φ
EIFMM D = ( φ 1 , φ 2 φ n ) EIFMM D = ( φ + , φ + φ + ) = φ +
Therefore, φ EIFMMD ( φ 1 , φ 2 φ n )   φ +
Case (i)
M   ( φ 1 , φ 2 φ n ) = ( 1 n !   ( . σ s n (   φ σ j ) D j ) ) 1 j = 1 n D j = { ( 1 ( σ s n n   ( 1 j = 1 n Է σ j D j ) ) 1 / n ! ) 1 j = 1 n D j , ( 1 ( 1 σ s n .   ( 1 j = 1 n ( 1 Ը σ j ) D j ) 1 / n ! ) ) 1 j = 1 n D j ,   min Ժ σ j ,   min Ք σ j }
Case (ii)
M   ( φ 1 , φ 2 φ n )   = ( 1 n !     ( . σ s n (   φ σ j ) D j ) ) 1 j = 1 n D j = { ( 1 ( σ s n n   ( 1 j = 1 n Է σ j D j ) ) 1 / n ! ) 1 j = 1 n D j , ( 1 ( 1 σ s n .   ( 1 j = 1 n ( 1 Ը σ j ) D j ) 1 / n ! ) ) 1 j = 1 n D j ,   max Ժ σ j ,   max Ք σ j }
Equations (7) and (8) are the elliptic intuitionistic fuzzy MM aggregation operators. □

3. Extension of EIFS in MCDM

Fuzzy logic provides a rigorous framework for modeling uncertainty, vagueness, and linguistic ambiguity inherent in expert-driven MCDM problems; however, it lacks inherent mechanisms for handling high-dimensional data and redundant or correlated criteria. In complex decision environments such as renewable energy evaluation, the presence of numerous interrelated criteria may degrade computational efficiency and compromise decision accuracy.
In IFSs, the mean values of both membership and non-membership attributes are frequently utilized to address MCDM challenges. To refine this methodology, geometric IFS have been introduced. The C-IFS is employed to pinpoint the centroid of IF numbers and to assess their respective distances. The most extreme distance from the centroid is designated as the radius, thereby facilitating the creation of a circle that encompasses all relevant points. This approach guarantees comprehensive coverage utilizing the maximal spatial region. Conversely, to attain coverage with the minimal spatial region, the EIFS is implemented. The computation of the semi-major and semi-minor axes of the ellipsoid occurs, thereby ensuring that all points are contained within the minimal possible area.
In real-world MCDM problems such as renewable energy selection, decision data are often uncertain, imprecise, and expressed linguistically, making classical models inadequate. Although intuitionistic fuzzy sets (IFSs) capture uncertainty, they assume symmetric and independent information, which is unrealistic in practice. EIFSs are adopted for their ability to model asymmetric and directional uncertainty through an elliptical representation, providing more accurate and realistic expert evaluations. The Muirhead mean is utilized due to its capability to model nonlinear interactions among multiple criteria. Thus, the integration of EIFSs and Muirhead means (EIFWMMA) effectively addresses nonlinearity, asymmetric uncertainty and interrelated criteria, resulting in a more robust and reliable decision-making framework.
The EIFS provides a mathematical framework for articulating and processing complex evaluative data in MCDM scenarios characterized by imprecision and uncertainty. By integrating linguistic assessments from multiple decision-makers with the corresponding EIFS representations, it becomes feasible to capture the nuances of truth, indeterminacy, and falsity in a more comprehensive manner. Nonetheless, an abundance of criteria may lead to diminished accuracy in DM and escalate computational intricacies. To mitigate this, PCA can be employed to reduce dimensionality while preserving the most significant variance within the dataset. Furthermore, the optimal alternative can be discerned through effective information fusion facilitated by the EIFWMMA operator. The subsequent stages outlined below comprise the proposed methodology. The framework of implementing MCDM techniques using EIFS is presented in Figure 2.

Algorithem of Implementing MCDM Techniques Using EIFS

PCA’s Role in Decision Process in Machine Learning Techniques:
Step 1: Create the decision matrix.
Step 2: Standardize the data to put all criteria on the same scale: zij = x i j x ¯ j σ j .
Step 3: Compute the covariance matrix measure relationships between criteria: S = 1 n 1   Z T Z .
Step 4: Find eigenvalues of matrix S.
Step 5: Select principal components.
Step 6: Explain variance ratio.

4. Application EIFS: Selection of Sustainable Renewable Energy Sources

In the global transition towards sustainable and low-carbon energy systems, the selection of appropriate renewable energy sources has become a critical real-world decision problem for governments, policymakers, and energy planners. Rapidly increasing energy demand, environmental degradation, and international commitments to climate change mitigation necessitate the identification of efficient, reliable, and environmentally sustainable energy alternatives. Therefore, adopting a robust and systematic decision-making framework is essential to support long-term energy planning and policy formulation.
Renewable energy technologies such as biomass, hydel, geothermal, wind, solar, and tidal energy exhibit diverse characteristics in terms of cost, efficiency, environmental impact, and resource availability. The selection process is inherently complex due to the presence of multiple conflicting criteria and uncertainty in expert evaluations. In practical scenarios, decision-makers must balance economic feasibility, environmental sustainability, technological reliability, and social acceptance, making the problem highly suitable for advanced MCDM approaches. Renewable energy sources are shown in Figure 3.
The practical significance of this study lies in its ability to provide a realistic and reliable decision-support tool for evaluating renewable energy alternatives under uncertainty. The proposed EIFWMMA-based framework enables decision-makers to handle vague, imprecise, and asymmetric information effectively, thereby improving the quality and robustness of energy planning decisions. In sustainable renewable energy selection, expert assessments often exhibit directional variability and asymmetric uncertainty due to conflicting criteria, unequal confidence levels, and interdependent sustainability indicators. Traditional intuitionistic fuzzy models assume symmetric uncertainty, which limits their applicability in real-world decision contexts. In contrast, EIFS introduces an elliptical uncertainty structure that captures directional dominance, asymmetric hesitation, and interrelationships among criteria, resulting in a more accurate representation of practical evaluation scenarios.
Furthermore, the integration of the EIFWMMA operator allows for nonlinear aggregation of criteria, reflecting real-world interactions and trade-offs among decision factors. This ensures that the decision-making process aligns more closely with actual planning conditions, where criteria are often interdependent rather than independent.
By applying the proposed framework to a selection of six major renewable energy alternatives based on key sustainability criteria, this study demonstrates how advanced fuzzy MCDM techniques can support evidence-based decision-making in energy policy, infrastructure development, and resource management. Consequently, the proposed methodology offers a practically relevant, scalable, and uncertainty-resilient solution for sustainable energy planning and other complex decision-making problems.
The process of selecting sustainable renewable energy sources necessitates intricate DM frameworks that are shaped by various conflicting and uncertain factors, including cost, efficiency, environmental ramifications, and resource availability. Traditional MCDM methodologies, such as Analytic Hierarchy Process (AHP), Technique for Order of Preference by Similarity to Ideal Solution (TOPSIS), VIKOR, Complex Proportional Assessment (COPRAS), and Elimination and Choice Expressing Reality (ELECTRE), frequently encounter challenges in accurately depicting the uncertainty and ambivalence that characterizes expert assessments. To mitigate these deficiencies, this study adopts the EIFWMMA methodology. The EIFWMMA approach integrates the adaptability of the Muirhead mean operator with the expressive capabilities of EIFSs, thereby facilitating the concurrent evaluation of interrelationships among criteria alongside the vagueness inherent in decision-makers’ evaluations. The elliptic characterization within EIFSs effectively encapsulates the interdependence of membership and non-membership functions, presenting a more nuanced and thorough representation of uncertainty in contrast to conventional intuitionistic or fuzzy paradigms. Furthermore, the Muirhead mean element facilitates nonlinear aggregation, thereby mirroring the interactions and compensatory dynamics that exist among evaluation criteria. Unlike prevailing MCDM techniques that depend on linear aggregation or deterministic weighting, EIFWMMA guarantees enhanced robustness, precision, and adaptability in uncertain contexts. Consequently, the EIFWMMA methodology offers a more dependable, equitable, and uncertainty-resilient decision support framework for the identification of optimal renewable energy alternatives, exhibiting superior efficacy and consistency in comparison to traditional methodologies.
By formulating a structured framework for integrating EIFS into MCDM methodologies, this algorithm improves transparency, objectivity, and the overall quality of the decision-making process.
Step 1: Alternatives (Ѫ): From the provided list, we will select 6 distinct alternatives that represent different sustainable renewable energy sources (Table 1). The selection of suitable renewable energy sources plays a crucial role in achieving sustainable power generation and reducing dependence on fossil fuels. Various technologies harness natural resources such as sunlight, wind, water, and organic matter to produce clean energy. In this study, six major renewable energy alternatives are considered for evaluation, each possessing unique characteristics, resource requirements, and environmental implications.
Criteria (Ѩ): We will select 6 key criteria that are representative and can be used to differentiate the alternatives effectively. These criteria will be considered benefit criteria (Table 2).
By implementing an MCDM approach within this structured DM model, organizations can effectively evaluate and compare various alternatives to identify the most sustainable renewable energy source.
The following matrix presents the evaluation results provided by the decision-makers, expressed through linguistic variables. Comparative analysis of ranking and decisions in linguistic variables is shown in Table 3 and Table 4.
Step 2: Based on the reference values provided in Table 1, the linguistic evaluations from the previous matrix are converted into their corresponding Intuitionistic Fuzzy Numbers (IFNs). The intuitionistic fuzzy decision matrices are given in Table 5.
Step 3. IFSs into EIFSs
t(y) = min 1 i q y Է ( y i ) = min {0.76,0.85,0.56,0.38,0.45,0.93} = 0.38
p(y) = min 1 i q y Ը ( y i ) = min {0.20,0.10,0.40,0.60,0.52,0.06} = 0.06
g(y) = max 1 i q y Է ( y i ) , = max {0.76,0.85,0.56,0.38,0.45,0.93} = 0.93
s(y) = max 1 i q y Ը ( y i ) = max {0.20,0.10,0.40,0.60,0.52,0.06} = 0.60
Է ( y ) = t y + g ( y ) 2 = ( 0.38 + 0.93 ) 2 = 0.655
Ը ( y ) = p y + s ( y ) 2 = ( 0.06 + 0.60 ) 2 = 0.33
Ժ y =   t ( y ) 2 +   ( g y t ( y ) s y p ( y ) ) 2   p ( y ) 2 = 0.655
Ք y = p ( y ) 2 +   ( s y p ( y ) g y t ( y ) ) 2   t ( y ) 2 = 0.33
The EIFS is Է y , Ը y , Ժ y , Ք y =   0 . 655,0.33,0.385,0.378 .
The EIFS of the given matrix is given in Table 6.
Step 4. Decision Matrix
The decision matrix is given in Table 7. Score = Է Ը + Ժ   +   Ք 3 : S [ 1,1 ].
Step 5. Standardization
Z   =   1.7497 1.0755 0.9693 1.8558 0.2956 1.8144 0.4984 0.7964 1.3670   1.1699 2.3337 2.1083 0.0801 0.2893 4.1311 3.3654 1.2729 0.7407 0.4242 2.2689 0.3314 1.1453 0.7964 1.3836 1.5376 0.6404 0.3977   0.2083 0.8390 2.1937 0.1923 1.3018 1.1396 1.7147 0.3182 0.5983
Step 6. Covariance Matrix
S   =   1.0000 0.2605 0.8823 0.2605 1.0000 0.0945 0.8823 0.0945 1.0000   0.5104 0.9565 0.5546 0.2696 0.0760 0.3363 0.5155 0.8932 0.3962 0.5104 0.2696 0.5155 0.9565 0.0760 0.8932 0.5546 0.3363 0.3962   1.0000 0.4657 0.1794 0.4657 1.0000 0.4058 0.1794 0.4058 1.0000
Step 7. Eigenvalues
The eigenvalues are
λ 1 ≈ 3.449401, λ 2 ≈ 1.356246, λ 3 ≈ 0.614319,
λ 4 0.443303 , λ 5 ≈ 0.127763, λ 6 ≈ 0.008968
Step 8. Principal Components
i = 1 m λ i = 6.0000
The proportion of variance represented in Table 8.
In the Scree plot (Figure 4), the eigenvalues decline sharply from PC1 to PC3, forming an “elbow” at PC4. This indicates that the first three principal components account for most of the variance in the evaluation data, whereas PC4 and PC5 contribute negligibly.
Step 9. Explained variance ratio.
The explained variance ratio = λ k i = 1 m λ i is considered as a weight.
Therefore, weights = 0.5749, 0.2260, 0.1024.

4.1. Advantages of Integrating PCA with Machine Learning Techniques

To identify the irredundant criteria, machine learning techniques, particularly dimensionality reduction methods such as principal component analysis (PCA), are integrated to extract the most informative features. This facilitates noise reduction, mitigates multicollinearity, and enhances the stability of the decision model. Therefore, the integration of fuzzy logic with machine learning is well justified, as it synergistically combines uncertainty modeling with data-driven optimization, leading to a more robust, scalable, and computationally efficient MCDM framework.
In the context of the selection of sustainable renewable energy sources, it is evident that although the initial framework encompassed five criteria, the fundamental distinctions among the six alternatives can be proficiently elucidated through merely three principal components. By concentrating exclusively on PC1, PC2, and PC3, the decision-making process is rendered more streamlined and devoid of superfluous elements, while still adhering to a data-driven and precise methodology, which is congruent with PCA’s function as a machine learning approach for dimensionality reduction. The reduced EIFS is given below in Table 9, and a corresponding graphical representation is given in Figure 5.

4.2. Using EIFWMMA Operator in Equation (7)

EIFWMMA matrix with weight w1 = 0.5749, w2 = 0.2260, w3 = 0.1024
Է = ( ( 1 ( ( 1 0.655 0.5749 ) × 0.49 0.2260 × 0.715 0.1024 ) ×               ( ( 1 0.655 0.5749 ) × 0.715 0.2260 × 0.49 0.1024 )   ×               ( ( 1 0.49 0.5749 ) ×   0.655 0.2260 × 0.715 0.1024 ) ×               ( ( 1 0.49 0.5749 ) × 0.715 0.2260 × 0.655 0.1024 )   ×               ( ( 1 0.715 0.5749 ) × 0.655 0.2260 × 0.49 0.1024 ) ×               ( ( 1 0.715 0.5749 ) × 0.49 0.2260 × 0.655 0.1024 ) ) 1 / 3 ! ) 1 / 0.9033     = 0.7831
Ը = 1 ( 1 ( ( 1 ( 1 0.33 ) 0.5749 × 1 0.48 0.2260 × ( 1 0.27 ) 0.1024 ) ×               ( 1 ( 1 0.33 ) 0.5749 × 1 0.27 0.2260 × ( 1 0.48 ) 0.1024 ) ×               ( 1 ( 1 × 1 0.33 0.2260 × ( 1 0.27 ) 0.1024 ) ×               ( 1 ( 1 0.48 ) 0.5749 × 1 0.27 0.2260 × ( 1 0.33 ) 0.1024 ) ×               ( 1 ( 1 0.27 ) 0.5749 × 1 0.48 0.2260 × ( 1 0.33 ) 0.1024 ) ×               ( 1 ( 1 0.27 ) 0.5749 × 1 0.33 0.2260 × ( 1 0.48 ) 0.1024 ) ) 1 / 3 ! ) 1 / 0.9033     =   0.2069
Ը = min { 0.385 , 0.08 , 0.450 } = 0.08
Ք = min { 0.378 , 0.077 , 0.425 } = 0.077
The aggregated values provided by case(i)
The aggregated values are represented in Table 10. Now the score of aggregated values is given by [ Ѫ 1 = 0.2444, Ѫ2 = 0.3212, Ѫ3 = 0.2573, Ѫ4 = 0.2975, Ѫ5 = 0.2765, Ѫ6 = 0.2098]. Here, Ѫ2 > Ѫ4 > Ѫ5 > Ѫ3 > Ѫ 1 > Ѫ 6 . This indicates that Zero Trust outperforms the other approaches. Hence, Ѫ2 is the most suitable alternative.
The aggregated values are provided by case(ii) using Equation (8). The score of aggregated values is given by [ Ѫ 1 = 0.4837, Ѫ2 = 0.5645, Ѫ3 = 0.2910, Ѫ4 = 0.5371, Ѫ5 = 0.4095, Ѫ6 = 0.3648]. Here, Ѫ2 > Ѫ4 > Ѫ3 > Ѫ4 > Ѫ 5 > Ѫ 3 . This indicates that Zero Trust outperforms the other approaches. Hence, Ѫ2 is the most suitable alternative.

5. Comparison with the Existing Methods

The comparative assessment elucidates that although C-IFS and IVIFS yield analogous ranking structures, the proposed EIFWMMA methodology demonstrates a markedly superior capacity for discrimination, enhanced score differentiation, and increased resilience under sensitivity scenarios. The methodology sustains ranking stability while facilitating clearer distinctions among competing alternatives. Moreover, EIFWMMA amalgamates sophisticated geometric uncertainty modeling with weighted aggregation, thereby providing augmented representational flexibility in comparison to extant circular and interval-based fuzzy methodologies. Consequently, EIFWMMA can be regarded as a more resilient and discerning geometric decision-making framework suited for intricate multi-criteria environments. The comparative analysis is given in Table 11 and the comparative analysis with existing methods is represented in Figure 6.
The proposed EIFWMMA methodology outperforms C-IFS and IVIFS by delivering greater score separation and clearer prioritization among renewable energy alternatives. Its elliptical uncertainty representation more effectively captures asymmetry and directional variation than circular or interval-based approaches. Sensitivity analysis further confirms that EIFWMMA maintains superior ranking stability under criteria weight fluctuations, whereas C-IFS and IVIFS exhibit noticeable rank shifts under minor parameter changes. By integrating advanced geometric modeling with weighted aggregation, EIFWMMA offers enhanced flexibility in handling complex uncertainty structures. These combined advantages improved score dispersion, ranking consistency, and robustness, validating that EIFWMMA can be regarded as a more resilient and discerning geometric DM framework suited for multi-criteria environments such as sustainable renewable energy source selection.

Comparitive Score Values

The comparative score values in Table 11 reveal notable differences among the methods AHP, TOPSIS, VIKOR, C-IFS, IVIFS, and EIFWMMA. It is observed that the EIFWMMA method produces relatively balanced and discriminative scores across all alternatives, indicating its superior capability in handling uncertainty. In particular, alternative Ѫ4 attains the highest score under all methods, confirming its robustness as the most preferred option. However, variations in ranking scores for other alternatives, such as Ѫ1 and Ѫ5, highlight the sensitivity of traditional geometrical methods like C-IFS and IVIFS to uncertainty representation. Compared to these approaches, EIFWMMA demonstrates improved consistency and better differentiation among alternatives due to its enhanced aggregation mechanism. This indicates that the proposed method provides more reliable and stable decision-making results. Comparative analysis of graphical methods is represented in Figure 7.
The chart compares different MCDM methods across key performance criteria such as uncertainty handling, computational efficiency, and ranking stability. EIFWMMA consistently achieves the highest scores in most categories, indicating superior overall performance. Traditional methods like AHP and TOPSIS show moderate performance, particularly in computational efficiency and interpretability. Overall, EIFWMMA demonstrates a better capability for handling complex decision-making with improved stability and reliability.

6. Decision Matrix Using Min–Max Normalization Method

The decision matrix was normalized using the Min–Max (linear) normalization method, as commonly applied in MCDM literature ([30]).
To ensure comparability across models, the closeness coefficients were normalized using Q i ( m ) = Q i ( m ) Q m i n ( m ) Q m a x ( m ) Q m i n ( m ) . The normalized score is presented in Table 12.
The Min–Max normalization values under EIFWMMA (min) and EIFWMMA (max) show that Alternative Ѫ2 consistently ranks first in both cases, indicating strong robustness and stability. Alternative Ѫ4 also maintains high performance with only slight variation, confirming its reliability.
Q i ( s )   =   2 1 m = 1 2 Q i ( m ) . The integrated results are given in Table 13.
Accordingly, the final consensus ranking is Ѫ2 > Ѫ4 > Ѫ5 > Ѫ1 > Ѫ3 > Ѫ6.
The sensitivity index analysis reveals that Alternative A2 is completely stable across min and max scenarios, while A4 also exhibits strong robustness with minimal variation. In contrast, A1 shows the highest sensitivity to aggregation strategy changes, followed by A3 and A5. These results indicate that the proposed model demonstrates overall robustness, with only a few alternatives showing moderate sensitivity. The sensitivity analysis demonstrates that the ranking of alternatives remains largely stable under variations in normalization methods and MCDM approaches, confirming the robustness of the model. Minor fluctuations in lower-ranked alternatives indicate some sensitivity, while top-ranked options (Ѫ2 and Ѫ4) consistently maintain their positions. The graphical sensitivity analysis is presented in Figure 8.

7. Criteria-Wise Visualization of EIFS

In this section we visualize the E-IFS for each criterion C1 to C6 in Figure 9.

8. Conclusions

This study articulates a ground-breaking and exhaustive DM framework based on EIFSs and the EIFWMMA operator. By incorporating an elliptical representation of membership and non-membership degrees, the proposed methodology offers a more nuanced and adaptable delineation of uncertainty and indecision in expert assessments when juxtaposed with conventional fuzzy models. The amalgamation of machine learning methodologies for dimensionality reduction and weight optimization further augments computational efficiency and DM precision. The deployment of the proposed EIFWMMA operator in addressing an MCDM challenge, particularly in the context of selecting sustainable renewable energy sources, showcases its resilience and efficacy. Comparative evaluations against existing methodologies, such as C-IFS and IVIFS [4,11], indicate that the elliptical-based framework consistently yields more stable, accurate, and geometrically interpretable results.
In summary, the described EIFS-based methodology demonstrates its superiority and exceptional efficacy as a tool for addressing intricate MCDM challenges amidst uncertainty. Its ability to accurately model real-world ambiguities, coupled with its flexibility across diverse DM scenarios, substantiates its potential as a next-generation framework for intelligent decision support systems. By employing this model to address the sustainable renewable energy selection dilemma, six alternatives, tidal, solar, geothermal, wind, hydel, and biomass, were systematically assessed against six pivotal criteria pertaining to efficiency, environmental impact, reliability, resource availability, land/water footprint, and socio-policy acceptability. Consequently, hydel energy is identified as the most appropriate and sustainable renewable energy option. The results highlight that EIFS-based models not only yield superior accuracy and interpretability in comparison to Circular and Interval-Valued IFS frameworks but also furnish a dependable, adaptable, and holistic instrument for tackling intricate DM issues amidst uncertainty.

8.1. Limitations

A key limitation of EIFSs lies in the geometric constraint of eccentricity e(x), which must remain less than 1 to maintain a valid elliptical representation. If e(x) = 1, the shape becomes parabolic, and if e(x) > 1, it turns hyperbolic. This restriction limits the range of uncertainty modeling and constrains the decision maker’s ability to fully express preferences within the MCDM framework.

8.2. Future Work

Future research can extend the proposed framework by applying the EIFWMMA operator to a wider range of real-world MCDM problems. Incorporating advanced machine learning techniques beyond PCA, such as deep learning and hybrid optimization models, may further improve criteria weighting and decision accuracy. Additionally, exploring alternative dimensionality reduction methods and geometric fuzzy representations can enhance model robustness and insight. Comparative studies with emerging fuzzy frameworks and large-scale datasets will help validate the scalability and effectiveness of the proposed approach in complex environments like sustainable renewable energy planning.

Author Contributions

Conceptualization, methodology, formal analysis, V.T., S.K. and M.S.K.; writing—review and editing, V.T. and S.K.; supervision, M.S.K. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The original contributions presented in this study are included in the article. Further inquiries can be directed to the corresponding author.

Acknowledgments

The authors express their sincere thanks to all reviewers and editors for their valuable comments and suggestions, which helped to improve the quality and clarity of this paper.

Conflicts of Interest

The authors declare no conflicts of interest.

Nomenclature

The following abbreviations are used in this manuscript:
MCDMMulti-Criteria Decision-Making
IFSIntuitionistic Fuzzy Set
EIFSElliptic Intuitionistic Fuzzy Set
C-IFSCircular Intuitionistic Fuzzy Set
IVIFSInterval-Valued Intuitionistic Fuzzy Set
EIFWMMAElliptic Intuitionistic Fuzzy Weighted Muirhead Mean Aggregation
DMDecision-Making
PCAPrincipal Component Analysis
(Է, Ը, Ժ , Ք )Membership, Non-Membership Hesitancy Degree and Semi-Major And Semi-Minor Axes

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Figure 1. Geometrical interpretation of the E-IFS element.
Figure 1. Geometrical interpretation of the E-IFS element.
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Figure 2. Implementing MCDM techniques using EIFS.
Figure 2. Implementing MCDM techniques using EIFS.
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Figure 3. Sources of renewable energy.
Figure 3. Sources of renewable energy.
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Figure 4. Scree plot.
Figure 4. Scree plot.
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Figure 5. (A)—represents no. of criteria before the application of PCA and (B)—represents no. of criteria after the application of PCA.
Figure 5. (A)—represents no. of criteria before the application of PCA and (B)—represents no. of criteria after the application of PCA.
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Figure 6. Comparative analysis with existing methods.
Figure 6. Comparative analysis with existing methods.
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Figure 7. Comparative score values of alternatives across MCDM methods.
Figure 7. Comparative score values of alternatives across MCDM methods.
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Figure 8. Graphical sensitivity analysis.
Figure 8. Graphical sensitivity analysis.
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Figure 9. Criteria 1 to 6.
Figure 9. Criteria 1 to 6.
Mathematics 14 01633 g009aMathematics 14 01633 g009b
Table 1. Alternatives of Sustainable Renewable Energy Sources.
Table 1. Alternatives of Sustainable Renewable Energy Sources.
Ѫ1Biomass Energy
Ѫ2Hydel Energy
Ѫ3Geothermal Energy
Ѫ4Wind Energy
Ѫ5Solar Energy
Ѫ6Tidal Energy
Table 2. Key criteria.
Table 2. Key criteria.
Ѩ1Energy EfficiencyMeasures how effectively a technology converts natural energy into usable electricity, emphasizing conversion performance and system optimization.
Ѩ2Environmental Impact (CO2 Emissions)Assesses the total life-cycle carbon footprint of technology, ensuring that the energy generation process supports long-term environmental sustainability.
Ѩ3Energy ReliabilityEvaluates the consistency and dependability of power generation under diverse climatic and operational conditions
Ѩ4Resource AvailabilityDetermines how the ease of access and abundance of a natural resource and its scalability within a specific region.
Ѩ5Land and Water FootprintExamines the spatial and water resource requirements necessary for installation and operation, focusing on ecological balance and sustainability.
Ѩ6Social and Policy AcceptabilityConsiders public perception, regulatory support, and socio-economic compatibility that influence large-scale adoption and implementation.
Table 3. Comparative analysis of ranking.
Table 3. Comparative analysis of ranking.
Linguistic VariablesAbbreviationIFNs
Extremely GoodԪ1(0.98,0.02)
Very Very GoodԪ2(0.93,0.06)
Very GoodԪ3(0.85,0.10)
GoodԪ4(0.76,0.20)
Medium GoodԪ5(0.65,0.25)
MediumԪ6(0.56,0.40)
Medium BadԪ7(0.45,0.52)
BadԪ8(0.38,0.60)
Very BadԪ9(0.28,0.70)
Very Very BadԪ10(0.16,0.80)
Extremely BadԪ11(0.05,0.90)
Table 4. Decision in linguistic variables.
Table 4. Decision in linguistic variables.
DMCriteriaѨ1Ѩ2Ѩ3Ѩ4Ѩ5Ѩ6
1 ̿ Ѫ1Ԫ4Ԫ2Ԫ1Ԫ4Ԫ2Ԫ5
Ѫ2Ԫ1Ԫ2Ԫ1Ԫ10Ԫ3Ԫ4
Ѫ3Ԫ2Ԫ4Ԫ10Ԫ1Ԫ6Ԫ10
Ѫ4Ԫ1Ԫ7Ԫ3Ԫ10Ԫ1Ԫ4
Ѫ5Ԫ9Ԫ5Ԫ6Ԫ7Ԫ11Ԫ9
Ѫ6Ԫ1Ԫ2Ԫ1Ԫ2Ԫ6Ԫ7
2 ̿ Ѫ1Ԫ3Ԫ6Ԫ2Ԫ5Ԫ4Ԫ6
Ѫ2Ԫ3Ԫ7Ԫ2Ԫ7Ԫ1Ԫ2
Ѫ3Ԫ8Ԫ4Ԫ3Ԫ5Ԫ2Ԫ11
Ѫ4Ԫ5Ԫ6Ԫ4Ԫ8Ԫ7Ԫ7
Ѫ5Ԫ9Ԫ6Ԫ9Ԫ8Ԫ4Ԫ6
Ѫ6Ԫ11Ԫ3Ԫ4Ԫ5Ԫ10Ԫ8
3 ̿ Ѫ1Ԫ6Ԫ9Ԫ3Ԫ9Ԫ5Ԫ10
Ѫ2Ԫ4Ԫ8Ԫ4Ԫ5Ԫ10Ԫ5
Ѫ3Ԫ8Ԫ8Ԫ6Ԫ6Ԫ5Ԫ8
Ѫ4Ԫ10Ԫ4Ԫ2Ԫ7Ԫ4Ԫ11
Ѫ5Ԫ6Ԫ8Ԫ10Ԫ4Ԫ7Ԫ8
Ѫ6Ԫ4Ԫ4Ԫ2Ԫ6Ԫ9Ԫ10
4 ̿ Ѫ1Ԫ8Ԫ10Ԫ7Ԫ11Ԫ7Ԫ9
Ѫ2Ԫ7Ԫ2Ԫ5Ԫ4Ԫ8Ԫ9
Ѫ3Ԫ10Ԫ11Ԫ4Ԫ7Ԫ10Ԫ9
Ѫ4Ԫ8Ԫ5Ԫ6Ԫ6Ԫ2Ԫ1
Ѫ5Ԫ8Ԫ10Ԫ11Ԫ9Ԫ9Ԫ9
Ѫ6Ԫ7Ԫ5Ԫ5Ԫ10Ԫ11Ԫ2
5 ̿ Ѫ1Ԫ7Ԫ11Ԫ5Ԫ7Ԫ6Ԫ11
Ѫ2Ԫ8Ԫ10Ԫ3Ԫ2Ԫ5Ԫ6
Ѫ3Ԫ10Ԫ10Ԫ2Ԫ8Ԫ9Ԫ10
Ѫ4Ԫ9Ԫ3Ԫ7Ԫ2Ԫ5Ԫ10
Ѫ5Ԫ4Ԫ11Ԫ8Ԫ10Ԫ10Ԫ11
Ѫ6Ԫ10Ԫ10Ԫ7Ԫ9Ԫ7Ԫ10
6 ̿ Ѫ1Ԫ2Ԫ2Ԫ4Ԫ6Ԫ3Ԫ2
Ѫ2Ԫ6Ԫ10Ԫ6Ԫ1Ԫ6Ԫ7
Ѫ3Ԫ5Ԫ9Ԫ1Ԫ3Ԫ11Ԫ7
Ѫ4Ԫ7Ԫ2Ԫ8Ԫ3Ԫ9Ԫ9
Ѫ5Ԫ11Ԫ4Ԫ7Ԫ2Ԫ1Ԫ4
Ѫ6Ԫ9Ԫ9Ԫ9Ԫ11Ԫ8Ԫ2
Table 5. The intuitionistic fuzzy decision matrices.
Table 5. The intuitionistic fuzzy decision matrices.
DMCriteriaѨ1Ѩ2Ѩ3Ѩ4Ѩ5Ѩ6
1 ̿ Ѫ1(0.76,0.20)(0.93,0.06)(0.98,0.02)(0.76,0.20)(0.93,0.06)(0.65,0.25)
Ѫ2(0.98,0.02)(0.93,0.06)(0.98,0.02)(0.16,0.80)(0.85,0.10)(0.76,0.20)
Ѫ3(0.93,0.06)(0.76,0.20)(0.16,0.80)(0.98,0.02)(0.56,0.40)(0.16,0.80)
Ѫ4(0.98,0.02)(0.45,0.52)(0.85,0.10)(0.16,0.80)(0.98,0.02)(0.76,0.20)
Ѫ5(0.28,0.70)(0.65,0.25)(0.56,0.40)(0.45,0.52)(0.05,0.30)(0.28,0.70)
Ѫ6(0.98,0.02)(0.93,0.06)(0.98,0.02)(0.93,0.06)(0.56,0.40)(0.45,0.52)
2 ̿ Ѫ1(0.85,0.10)(0.56,0.40)(0.93,0.06)(0.65,0.25)(0.76,0.20)(0.56,0.40)
Ѫ2(0.85,0.10)(0.45,0.52)(0.93,0.06)(0.45,0.52)(0.98,0.02)(0.93,0.06)
Ѫ3(0.38,0.60)(0.76,0.20)(0.85,0.10)(0.65,0.25)(0.93,0.06)(0.05,0.92)
Ѫ4(0.65,0.25)(0.56,0.40)(0.76,0.20)(0.38,0.60)(0.45,0.52)(0.45,0.52)
Ѫ5(0.28,0.70)(0.56,0.40)(0.28,0.70)(0.38,0.70)(0.76,0.20)(0.56,0.40)
Ѫ6(0.05,0.90)(0.85,0.10)(0.76,0.20)(0.65,0.25)(0.16,0.80)(0.38,0.60)
3 ̿ Ѫ1(0.56,0.40)(0.28,0.70)(0.85,0.10)(0.28,0.70)(0.65,0.25)(0.16,0.80)
Ѫ2(0.76,0.20)(0.38,0.60)(0.76,0.20)(0.65,0.25)(0.16,0.80)(0.65,0.25)
Ѫ3(0.38,0.60)(0.38,0.60)(0.56,0.40)(0.56,0.40)(0.65,0.25)(0.38,0.40)
Ѫ4(0.16,0.80)(0.76,0.20)(0.93,0.06)(0.45,0.52)(0.76,0.20)(0.05,0.90)
Ѫ5(0.56,0.40)(0.38,0.60)(0.16,0.80)(0.76,0.20)(0.45,0.52)(0.38,0.60)
Ѫ6(0.76,0.20)(0.76,0.20)(0.93,0.06)(0.56,0.40)(0.28,0.70)(0.16,0.80)
4 ̿ Ѫ1(0.38,0.60)(0.16,0.80)(0.45,0.52)(0.05,0.90)(0.45,0.52)(0.28,0.70)
Ѫ2(0.45,0.52)(0.93,0.06)(0.65,0.25)(0.76,0.20)(0.38,0.60)(0.28,0.70)
Ѫ3(0.16,0.80)(0.05,0.90)(0.76,0.20)(0.45,0.52)(0.16,0.80)(0.28,0.70)
Ѫ4(0.38,0.60)(0.65,0.25)(0.56,0.40)(0.56,0.40)(0.93,0.06)(0.98,0.02)
Ѫ5(0.38,0.60)(0.16,0.80)(0.05,0.92)(0.28,0.70)(0.28,0.70)(0.28,0.70)
Ѫ6(0.45,0.52)(0.65,0.25)(0.65,0.25)(0.16,0.80)(0.05,0.92)(0.93,0.06)
5 ̿ Ѫ1(0.45,0.52)(0.05,0.90)(0.65,0.25)(0.45,0.52)(0.56,0.40)(0.05,0.90)
Ѫ2(0.38,0.60)(0.16,0.80)(0.85,0.10)(0.93,0.06)(0.65,0.25)(0.56,0.40)
Ѫ3(0.16,0.80)(0.16,0.80)(0.93,0.06)(0.38,0.60)(0.28,0.70)(0.16,0.80)
Ѫ4(0.28,0.70)(0.85,0.10)(0.45,0.52)(0.93,0.06)(0.65,0.25)(0.16,0.80)
Ѫ5(0.76,0.20)(0.05,0.90)(0.38,0.40)(0.16,0.80)(0.16,0.80)(0.05,0.90)
Ѫ6(0.16,0.80)(0.56,0.40)(0.45,0.52)(0.28,0.70)(0.45,0.52)(0.16,0.80)
6 ̿ Ѫ1(0.93,0.06)(0.93,0.06)(0.76,0.20)(0.56,0.40)(0.85,0.10)(0.93,0.06)
Ѫ2(0.56,0.40)(0.16,0.80)(0.56,0.40)(0.98,0.02)(0.56,0.40)(0.45,0.52)
Ѫ3(0.65,0.25)(0.28,0.70)(0.98,0.02)(0.85,0.10)(0.05,0.90)(0.45,0.52)
Ѫ4(0.45,0.52)(0.93,0.06)(0.38,0.60)(0.85,0.10)(0.28,0.70)(0.28,0.70)
Ѫ5(0.05,0.90)(0.76,0.20)(0.45,0.52)(0.93,0.06)(0.98,0.02)(0.76,0.20)
Ѫ6(0.28,0.70)(0.28,0.70)(0.28,0.70)(0.05,0.90)(0.38,0.40)(0.93,0.06)
Table 6. Elliptic intuitionistic fuzzy decision matrices.
Table 6. Elliptic intuitionistic fuzzy decision matrices.
Ѩ1Ѩ2Ѩ3
Ѫ1(0.655,0.33,0.385,0.378)(0.49,0.48,0.08,0.077)(0.715,0.270,0.450,0.425)
Ѫ2(0.68,0.31,0.381,0.368)(0.545,0.43,0.172,0.165)(0.770,0.210,0.560,0.507)
Ѫ3(0.545,0.43,0.172,0.165)(0.405,0.55,0.209,0.206)(0.570,0.410,0.161,0.154)
Ѫ4(0.57,0.41,0.161,0.154)(0.640,0.27,0.538,0.493)(0.655,0.33,0.385,0.378)
Ѫ5(0.405,0.55,0.209,0.206)(0.405,0.55,0.209,0.206)(0.305,0.650,0.411,0.403)
Ѫ6(0.515,0.46,0.054,0.051)(0.605,0.38,0.287,0.282)(0.63,0.36,0.281,0.273)
Ѩ4Ѩ5Ѩ6
Ѫ1(0.405,0.55,0.209,0.206)(0.69,0.29,0.454,0.435)(0.49,0.48,0.080,0.077)
Ѫ2(0.57,0.41,0.161,0.154)(0.57,0.41,0.161,0.153)(0.63,0.36,0.281,0.273)
Ѫ3(0.68,0.31,0.381,0.368)(0.49,0.48,0.080,0.077)(0.305,0.650,0.411,0.403)
Ѫ4(0.545,0.431,0.172,0.165)(0.63,0.36,0.281,0.273)(0.515,0.46,0.054,0.051)
Ѫ5(0.545,0.43,0.172,0.165)(0.515,0.46,0.054,0.051)(0.405,0.55,0.209,0.206)
Ѫ6(0.49,0.48,0.080,0.077)(0.305,0.650,0.411,0.403)(0.545,0.43,0.172,0.165)
Table 7. Decision matrix.
Table 7. Decision matrix.
CriteriaѨ1Ѩ2Ѩ3Ѩ4Ѩ5Ѩ6
Ѫ10.3630.0560.4400.0900.4300.056
Ѫ20.3730.1510.5420.1580.1580.275
Ѫ30.1510.0900.1580.3730.0560.156
Ѫ40.1580.4670.3630.1500.2750.053
Ѫ50.0900.0900.1560.1510.0530.090
Ѫ60.0530.2650.2750.0560.1560.151
Table 8. Proportion of variance.
Table 8. Proportion of variance.
Principal ComponentsEigenvaluesProportion of Variance
PC13.449457.49%
PC21.356222.60%
PC30.614310.24%
PC40.44337.39%
PC50.12782.13%
PC60.00900.15%
Table 9. Reduced elliptic intuitionistic fuzzy decision matrices.
Table 9. Reduced elliptic intuitionistic fuzzy decision matrices.
Ѩ1Ѩ2Ѩ3
Ѫ1(0.655,0.33,0.385,0.378)(0.49,0.48,0.08,0.077)(0.715,0.270,0.450,0.425)
Ѫ2(0.68,0.31,0.381,0.368)(0.545,0.43,0.172,0.165)(0.770,0.210,0.560,0.507)
Ѫ3(0.545,0.43,0.172,0.165)(0.405,0.55,0.209,0.206)(0.570,0.410,0.161,0.154)
Ѫ4(0.57,0.41,0.161,0.154)(0.640,0.27,0.538,0.493)(0.655,0.33,0.385,0.378)
Ѫ5(0.405,0.55,0.209,0.206)(0.405,0.55,0.209,0.206)(0.305,0.650,0.411,0.403)
Ѫ6(0.515,0.46,0.054,0.051)(0.605,0.38,0.287,0.282)(0.63,0.36,0.281,0.273)
Table 10. Aggregated values.
Table 10. Aggregated values.
Է Ը Ժ Ք
Ѫ10.78310.20690.080.077
Ѫ20.80810.18160.1720.165
Ѫ30.72210.26420.160.154
Ѫ40.77800.19760.1610.154
Ѫ50.66180.24720.2090.206
Ѫ60.75860.23320.0540.05
Table 11. Comparative analysis.
Table 11. Comparative analysis.
Method Ѫ 1 Ѫ 2 Ѫ 3 Ѫ 4 Ѫ 5 Ѫ 6
Fuzzy AHP0.2330.2850.2480.2720.2610.214
Fuzzy TOPSIS0.5120.6330.4650.5890.5030.474
Fuzzy VIKOR0.4720.6190.4570.5720.4890.462
C-IFS-MMA DM0.29080.31920.23030.29480.20830.2679
IVIFS-MMA-DM0.27600.31200.25400.29500.24300.2600
EIFWMMA-DM0.24440.32120.25730.29750.27650.2098
Table 12. Min–Max normalization.
Table 12. Min–Max normalization.
AlternativesEIFWMMAEIFWMMAMin–Max Normalization Method
MinMaxEIFWMMA MinEIFWMMA Max
Ѫ10.24440.48370.31060.7046
Ѫ20.32120.56451.00001.0000
Ѫ30.25730.29100.42640.2132
Ѫ40.29750.53710.78730.8435
Ѫ50.27560.40950.79070.5120
Ѫ60.20980.36480.00000.1349
Table 13. Synthesized scores.
Table 13. Synthesized scores.
RankAlternativesSynthesized Score Q i ( s )
1Ѫ21.0000
2Ѫ40.8435
3Ѫ50.5120
4Ѫ10.5076
5Ѫ30.2133
6Ѫ60.1349
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Tharakeswari, V.; Kameswari, M.S.; Krishnaprakash, S. Sustainable Renewable Energy Source Selection Using a Machine Learning-Integrated Elliptic Intuitionistic Fuzzy Muirhead Mean Framework. Mathematics 2026, 14, 1633. https://doi.org/10.3390/math14101633

AMA Style

Tharakeswari V, Kameswari MS, Krishnaprakash S. Sustainable Renewable Energy Source Selection Using a Machine Learning-Integrated Elliptic Intuitionistic Fuzzy Muirhead Mean Framework. Mathematics. 2026; 14(10):1633. https://doi.org/10.3390/math14101633

Chicago/Turabian Style

Tharakeswari, Vasudevan, Meenakshi Sundaram Kameswari, and Shanmugavel Krishnaprakash. 2026. "Sustainable Renewable Energy Source Selection Using a Machine Learning-Integrated Elliptic Intuitionistic Fuzzy Muirhead Mean Framework" Mathematics 14, no. 10: 1633. https://doi.org/10.3390/math14101633

APA Style

Tharakeswari, V., Kameswari, M. S., & Krishnaprakash, S. (2026). Sustainable Renewable Energy Source Selection Using a Machine Learning-Integrated Elliptic Intuitionistic Fuzzy Muirhead Mean Framework. Mathematics, 14(10), 1633. https://doi.org/10.3390/math14101633

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