key: cord-0860310-qfz4rdq3 authors: Garg, Harish; Ullah, Kifayat; Mahmood, Tahir; Hassan, Nasruddin; Jan, Naeem title: T-spherical fuzzy power aggregation operators and their applications in multi-attribute decision making date: 2021-01-22 journal: J Ambient Intell Humaniz Comput DOI: 10.1007/s12652-020-02600-z sha: eb99fa8550f37f022d6416cd737f8326539ba513 doc_id: 860310 cord_uid: qfz4rdq3 The paper aims to present the concept of power aggregation operators for the T-spherical fuzzy sets (T-SFSs). T-SFS is a powerful concept, with four membership functions denoting membership, abstinence, non-membership and refusal degree, to deal with the uncertain information as compared to other existing fuzzy sets. On the other hand, the relationship between the different pairs of the attributes are well recorded in terms of power operators. Thus, keeping these advantages of T-SFSs and power operator, the objective of this work is to define several weighted averaging and geometric power aggregation operators. The stated operators named as T-spherical fuzzy weighted, ordered weighted, hybrid averaging and geometric operators for the collection of the T-SFSs. The various properties and the special cases of them are also derived. Further, the consequences of proposed new power aggregation operators are studied in view of some constraints. Finally, a multiple attribute decision making algorithm, based on the proposed operators, is established to solve the problems with uncertain information and illustrate with numerical examples. A comparative study, superiority analysis and discussion of the proposed approach are furnished to confirm the approach. Multiple attribute decision making (MADM) process includes the examination of a limited arrangement of options and positioning them as far as the fact that they are so trustworthy to decision-maker(s) when all the rules are thought of at the same time. In this procedure, the rating estimations of every option incorporate both exact information and specialists' subjective data. However, generally, it is expected that the data gave by them are fresh in nature. In any case, because of the unpredictability of the framework step by step, the genuine contains numerous MADM issues where the data is either ambiguous, lose or dubious in nature. To manage it, Atanassov (1986) developed the framework of intuitionistic fuzzy set (IFS) which described the degree of imprecision in terms of two functions known as membership and non-membership functions with a condition that their sum must not exceed 1 . Atanassov's intuitionistic fuzzy model enhanced the concept of Zadeh's fuzzy set (FS) (Zadeh 1965 ) which described the imprecision in an uncertain event with the help of only one function known as membership function on a scale of 0 to 1 . Atanassov's IFS restricts decision-makers in two ways; first, it restricts the sum of membership and non-membership grades up to unit interval due to which decision makers cannot assign these grades by their own consent. Second, it fails to be applied to those problems where opinion is not of yes or no type, but it has abstinence as well as refusal degree. However, in sequence to negotiate the ambiguities in the data, theories such as interval-valued IFS (IVIFS) (Atanassov and Gargov 1989) , cubic intuitionistic fuzzy set , Pythagorean fuzzy set (PyFS) (Yager 2013) , picture fuzzy set (PFS) (Cuong 2014) , linguistic interval-valued IFS (Garg and Kumar 2019) , linguistic interval-valued PyFS (Garg 2020b) , q-rung orthopair fuzzy set (q-ROPFS) (Yager 2017) are used by the researchers. The benefits of such elongated extensions are that they serve uncertain information using membership, non-membership and the degree of hesitancy. Since, the domain of Atanassov's IFS is very narrow which could not be applied to situations where opinion could be of more than two types such as yes, abstain, no and refusal. For this purpose, Cuong (2014) introduced a generalized model in FS theory known as picture fuzzy set (PFS) which describe four aspects of an imprecise event. In decision making, human opinion can be favor, abstinence, and disfavor and refusal degree represented by four membership functions of a PFS. Like Atanassov's IFS, Cuong's PFS has a restriction that the sum of three membership grades must not exceed 1 which somehow restricts the decision maker from setting up the membership values by their own consent. Mahmood et al. (2018) proposed a solution for the limited structure of PFS and developed the framework of spherical fuzzy set (SFS) by increasing the range of PFS. This concept of SFS is further extended to the idea of T-spherical fuzzy set (T-SFS) by introducing a parameter t that allows the decision makers to choose the values of membership grades from anywhere in the interval [0, 1] . A T-SFS is the most generalized fuzzy framework that can represent human opinion about any imprecise event in a flexible way with no limitations. The geometrical comparison between the ranges of PFS, SFS and T-SFS is portrayed in Fig. 1 which supports the superiority of T-SFS over other fuzzy frameworks. MADM is a hot research area in fuzzy mathematics. It is regarded as one of the most influential topics that are discussed in almost every fuzzy framework. The commonly known tools for MADM process are the aggregation operators and in some cases distance, similarity measures. Several aggregation operators have been developed so far under the different environment. For example, under the IFS and PyFS environment, authors in (Xu 2007; Xu and Yager 2006) presented some weighted averaging (WA) and weighted geometric (WG) operators to aggregate the information. Peng and Yang (2015) examined the new operations on PyFS like division, subtraction to find the superiority and inferiority with the help of ranking method in MADM problems. The idea of Pythagorean fuzzy TODIM (an acronym in Portuguese for interactive Multi-criteria Decision Making) approach to MADM is developed by Ren et al. (2016) . In the work of Garg (2017a) , author investigated some new generalized Pythagorean fuzzy information aggregation operators by combining Einstein operations and studied some of their desirable properties. Kaur and Garg (2019) presented some t-norm based operators for cubic IFS to solve the MADM problems. Yang et al. (2020c) used Heronian mean operators and designed a MADM algorithm for online shopping. However, under q-ROPFS environment, the WA and WG operators are defined by Liu and Wang (2018) and studied their applications in MADM. Yang et al. (2020a) further investigated the multiple heterogeneous relationships using MADM approach of q-rung orthopair fuzzy information. Under the PFS environment, Garg (2017b) defined the weighted averaging and geometric operators while Wang et al. (2017) presented some geometric operators to solve the decision-making problems. Mahmood et al. (2018) extended these operations to the spherical fuzzy set (SFS) while Ullah et al. (2019) presented such operators to the T-SFS. The practicality of these aggregation operators is discussed in MADM problems. In Yang et al. (2020b) , authors investigated the selection of antivirus mask in light of COVID-19 pandemic using SFSs. Ullah et al. (2020b) defined the Hamacher aggregation operators for T-SFS. Munir et al. (2020) used Einstein hybrid aggregation operators based on T-SFSs for solving MADM problems. presented some improved interactive operators for T-SFSs. In Liu et al. (2019) , authors have solved the MADM problem by define the Muirhead mean operators for the T-SFS information. However, in terms of information measures such as similarity and correlation, some algorithms are presented in the literature (Ullah et al. , 2020a to solve the pattern recognition and other problems. All the above stated measures and operators have been greatly utilized to solve the MADM problems. However, it is observed from these studies that all these algorithms are stated under the assumption that the considered attributes are independent to each other. But it is quite obvious that in our real-life, all the considered attributes are directly impact on each other. For instance, consider a decision making problem related to purchase of house then their corresponding attributes or parameters such as locality, price, features are directly depend on each other. Hence, in the above stated algorithm, such features are not considered. In other words, all the above defined operators do not consider the relationship of the values being used. To overcome this difficulty, a concept of power aggregation operator has been defined by Yager (2001) . Power aggregation operators significantly involve the relationship of information being aggregated. Due to the importance of power aggregation operators, several authors have addressed the various MADM problems by utilizing the power operator. For instance, Xu and Yager (2010) proposed some power WG aggregation operators in fuzzy environment. Wei et al. (2013) utilized fuzzy power aggregation operators to solve the MADM problem. Wei and Lu (2018) express the power WA and WG operators for PyFS features. Xu (2011) examined these power operators with IFS features. Garg and Kumar (2020) utilized the concept of the connection number under IFS environment to define the power geometric operators. Zhou et al. (2012) defined the generalized power aggregation operators for solving the group decision making problems. defined interactive power Hamacher operators with PyFS information to solve the problems. defined interactive power Bonferroni mean operators to solve the MADM problem under the PyFS environment. Arora (2018, 2019) defined some scaled prioritized interactive and Archimedean t-norm based operators to solve the MADM problems. Rani and Garg (2018) developed the concept of complex intuitionistic fuzzy power aggregation operators and their applications in MADM process. With the increasing complexities in the system, it is perceived that the above defined literature and the extension of FS, T-SFS is one of the most promotable and useful tool to express the uncertainties in the data. On the other hand, by considering the importance of power an aggregation operator which takes into account the relationship of the information being aggregated, and the flexibilities of the T-SFS to describe the uncertain information in the data, it is observed that the existing power operators (Garg and Kumar 2020; Yager 2001; Xu and Yager 2010; Wei et al. 2013; Wei and Zhang 2019; Wei and Lu 2018; Arora 2018, 2019; under the different environment could not handle the case where the information has abstinence and refusal membership grades along with membership and non-membership grades. To address it completely, in this paper, our aim is to introduce the concept of power operator for the T-SFSs. The primary objectives of the work are listed as follows. 1. A concept of T-SFS has been utilized to express the uncertainties in the data. 2. To develop several powers weighted operators to aggregate the collective information. 3. Some special cases of the proposed operators are deduced under the existing environment. 4. To establish an MADM method based on the proposed operators to solve the problems. 5. To show the significance and superiority of proposed power aggregation operators over existing power aggregation operators numerically. The rest of the paper is summarized as. In Sect. 2, we briefly overview some basic concepts related to T-SFS. In Sect. 3, we propose the power weighted averaging and geometric aggregation operators for T-SFNs and investigates their properties. The consequences and the special cases of the proposed operators are investigated in Sect. 4. In Sect. 5, we established an algorithm to deal with MADM problems based on the proposed operators. A numerical example is discussed in Sect. 6 to demonstrate the stated algorithm while a comparative analysis is summarized in Sect. 7 with the existing studies. Finally, a concrete conclusion is given in Sect. 8. In this section, some basic notions about T-SFSs are reviewed. Definition 1 A T-SFS is defined in terms of three functions known as membership (s) , abstinence (u) and non-membership (d) function with a restriction that for some t ∈ ℤ + and t ≥ 1 . Moreover, the term refusal degree is denoted by r and obtained as For convenience, the triplet (s, u, d) is referred as T-spherical fuzzy number (T-SFN). Remark 1 clearly establishes the superiority of T-SFS over the pre-existing concepts. A T-SFS is described in terms of four membership functions denoting membership, abstinence, non-membership and refusal degree. Therefore, it can describe any human opinion in a better way comparative to SFS, PFS, q-ROPFS, PyFS and IFS. In voting phenomena or human decision making, human opinions are based on four aspects as vote in favor, abstain, vote against and refused to vote. In such type of problems, the idea of T-SFS can successfully be utilized for better results. Further, the parameter t in T-SFS allows the decision makers to select any value from the unit interval with no restrictions. Hence, the concept of T-SFS is more likely to be utilized in practical problems than other pre-existing fuzzy frameworks. The versatile nature of T-SFS over other fuzzy frameworks is geometrically demonstrated in Fig. 1 where the first shape shows the range of PFNs, second one demonstrates the range of SFNs while the third one shows the range of T-SFNs for t = 5 . Increasing the value of t will increase the space of T-SFNs which makes it the most reliable and generalized fuzzy framework. Now we discuss the concept of power aggregation operators and their significance. The idea of power aggregation operator was first proposed by Yager (2001) when he developed the concept of power WA aggregation operators in fuzzy environment. The reason to develop power aggregation operator is that all other aggregation tools do not consider the relationship of the information being used. Yager (2001) introduced power WA operators for FSs which leads Xu and Yager (2010) to propose power WG operators in fuzzy environment for aggregation purpose. Definition 2 (Xu and Yager 2010) Let Ţ i (i = 1, 2, 3, … n) denote FSs. Then PWA and PWG operators are defined as: Motivated by the inspiring work on power aggregation operators in fuzzy environment by Yager (2001) and Xu and Yager (2010) , proposed the idea of power aggregation operators in the environment of IFS which was further extended by Wei and Lu (2018) to handle Pythagorean fuzzy information. The power aggregation operators developed by for IFSs and by Wei and Lu (2018) for PyFSs are given as follows: Then PWA and PWG operators are defined as: Definition 4 (Wei and Lu 2018) Let Ţ i denote some PyFSs. Then PWA and PWG operators are defined as: Keeping the significance of power aggregation operators and inspiring work in this direction, we proposed the power aggregation operators for T-SFSs and consequently for SFSs, PFSs and q-ROPFSs. In this section, using the idea of power aggregation operators, we present the concept of power aggregation operator for T-SFSs and proposed TSFPWA operator, TSFPOWA operator, TSFPHA operator. The investigation of properties of the newly established concepts is carried out and their consequences are discussed. Throughout this paper, the weight vector is denoted by w = w 1 , w 2 , … w n Ţ such that w i > 0 and ∑ n 1 w i = 1 . The terms i, j and k denote the indexing sets such that i, j, k = 1, 2, 3, … n . Let Γ be a collection of T-SFNs. The aggregated operator defined in Definition 4 likely to satisfy the following basic properties of aggregation. The TSFPWA operator defined in Definition 4 does not weigh the ordered position of T-SFNs but in only weigh the T-SFNs. There are many decision-making problems where the information is arranged in ascending or descending order and their ordered positions are weighted. To cope with such situation, inspired by the idea of Yager (2001), we proposed the concept of TSFPOWA operators in the following definition. Then TSFPOWA operator is defined as where σ(j) is a permutation such that Ţ σ(j−1) ≥ Ţ σ(j) ∀ j and w j denotes the collection of weights such that where Ş Ţ σ(j) denote the support of j th largest T-SFN Ţ σ(j) for i th greatest T-SFN Ţ σ(i) and g ∶ [0, 1] → [0, 1] is a monotonic function having the properties g(0) = 0 , g(1) = 1 and g(x) ≥ g(y) if x > y. The aggregated operator defined in Definition 5 likely to satisfy the following basic properties (1-3) of aggregation operators. The TSFPWA operator weighs the argument only while the TSFPOWA operator weighs the ordered position of the argument instead i.e. both operators have two separate aspects. Therefore, in the following Definition, we proposed the concept of hybrid operator known as TSFPHA operator which weighs the argument as well as its ordered position. Then TSFPHA operator is defined as where Ţ σ(j) is the j th largest of the T-SFN Ţ j = mw j Ţ j with w j as the weight vector of T-spherical fuzzy arguments Ţ j such that w j ∈ [0, 1] and ∑ n 1 w j = 1 and m is the balancing coefficient. Further, w j is such that where Ş Ţ σ(j) denote the support of j th largest T-SFN Ţ σ(j) for i th greatest T-SFN Ţ σ(i) and g ∶ [0, 1] → [0, 1] is a monotonic function having the properties g(0) = 0 , g(1) = 1 and g(x) ≥ g(y) if x > y. R e m a r k 2 P l a c i n g w j = 1 n , 1 n , 1 n , … 1 n T a n d w j = 1 n , 1 n , 1 n , … 1 n T , the TSFPHA operator reduces to TSFPWA operator and TSFPOWA operator respectively. The concept of power geometric aggregation operators is proposed by Xu and Yager (2010) . We use the idea of power geometric aggregation operators developed by Xu and Yager (2010) and by using the operational laws developed by Ullah et al. (2019) to develop the concept of power geometric aggregation operators for T-SFSs and proposed TSFPG operator, TSFPOWG operator and TSFPHG operator. It is discussed that power geometric aggregation operators of T-SFSs satisfy the basic properties of aggregation including monotonicity, idempotency and boundedness. The consequences of the new proposed aggregation operators are also investigated. Then TSFPWG operator is defined as where The aggregated operator defined in Definition 7 likely to satisfy the following basic properties of aggregation. TSFPWG Ţ 1 , Ţ 2 , Ţ 3 … Ţ n ≤ TSFPWG P 1 , P 2 , P 3 … P n Ţ − ≤ TSFPWG Ţ 1 , Ţ 2 , Ţ 3 … Ţ n ≤ Ţ + Property 6 (Idempotency) If ∀ j = 1, 2, 3, … n , Ţ j = Ţ = (s, u, d) . Then Here again, the TSFPWG operator only weigh the T-spherical fuzzy argument but not its ordered position. Therefore, inspired by the idea of Xu and Yager (2010) , the concept of TSFPOWG operator is proposed as follows. Then TSFPOWG operator is defined as where σ(j) is a permutation such that Ţ σ(j−1) ≥ Ţ σ(j) ∀ j and w j denotes the collection of weights such that where Ş Ţ σ(j) denote the support of j th largest T-SFN Ţ σ(j) for i th greatest T-SFN Ţ σ(i) and g ∶ [0, 1] → [0, 1] is a monotonic function having the properties g(0) = 0 , g(1) = 1 and g(x) ≥ g(y) if x > y. The aggregated operator defined in Definition 8 likely to satisfy the following basic properties (4-6) of aggregation operators. The TSFPWG operator weighs the T-spherical fuzzy argument only while the TSFPOWG operator weighs the ordered position of the argument instead. Therefore, we proposed the concept of TSFPHG operator which weighs the T-spherical fuzzy argument as well as its ordered position. Definition 9 Let Ţ i = s i , u i , d i denote some T-SFNs. Then TSFPHG operator is defined as where Ţ σ(j) is the j th largest of the T-SFN Ţ j = Ţ mw j j with w j as the weight vector of T-spherical fuzzy arguments Ţ j such that w j ∈ [0, 1] and ∑ n 1 w j = 1 and m is the balancing coefficient. Further, w j is such that where Ş Ţ σ(j) denote the support of j th largest T-SFN Ţ σ(j) for i th greatest T-SFN Ţ σ(i) and g ∶ [0, 1] → [0, 1] is a monotonic function having the properties g(0) = 0 , g(1) = 1 and g(x) ≥ g(y) if x > y. R e m a r k s 3 P l a c i n g w j = 1 n , 1 n , 1 n , … 1 n T a n d w j = 1 n , 1 n , 1 n , … 1 n T reduces the TSFPHG operator to TSF-PWG operator and TSFPOWG operator respectively. In this section, the consequences of theory developed in Sect. 3 are investigated which shows the superiority of proposed work over the pre-existing notions. Here using some restrictions, we show that proposed TSFPWA and TSFPWG operators are generalizations of power WA and power WG operators of IFSs and PyFSs studied in Wei and Lu (2018) and . Further, some restrictions on TSFPWA and TSFPWG aggregation operators also results in the development of power WA and power WG operators for SFSs, PFSs and q-ROPFSs. Consider the following TSFPWA and TSFPWG operators labeled by Eqs. (7) and (10) respectively; The Eqs. (7) and (10) results in the power WA and power WG aggregation operators of SFSs by taking t = 2 and given as: 2. The Eqs. (7) and (10) results in the power WA and power WG aggregation operators of PFSs by taking t = 1 and given as: 3. The Eqs. (7) and (10) results in the power WA and power WG aggregation operators of q-ROPFSs by taking u j = 0 and given as: 4. The Eqs. (7) and (10) results in the power WA and power WG aggregation operators of PyFSs proposed by Wei and Lu (2018) by taking t = 2 and u j = 0 and given as: 5. The Eqs. (7) and (10) results in the power WA and power WG aggregation operators of IFSs proposed by Xu (2011) by taking t = 1 and u j = 0 and given as: Here, Eqs. (15-24) provide the power WA and power WG operators for SFSs, PFSs and q-ROPFSs for which these types of aggregation operators are not defined yet. Equations (21-24) are special cases of TSFPWA and TSFPWG operators in which these operations reduced to the environment of PyFSs and IFSs studied in . All this clearly shows the significance and diverse structure of TSFPWA and TSFPWG operators. The superiority of power aggregation operators of T-SFSs can be seen in the flowchart given in Fig. 2 . The aim of this section is to develop the algorithm for solving MADM problems using TSFPWA and TSFPWG operators. The process of MADM is briefly demonstrated followed by an algorithmic approach. In MADM process, the selection of most suitable alternative is carried out under some attributes having weights and using the information provided by the decision makers. Suppose there are n alternatives A i with m attributes g j having weight w j . Further, let d n×m = Ţ ij n×m = s ij , u ij , d ij denote the decision matrix where s ij , u ij and d ij are the degrees of satisfaction, abstinence and dissatisfaction respectively with denote the refusal degree of alternative A i 's under attributes g j 's. The following steps are followed for solving MADM problems based on the stated aggregation operators in the environment of T-SFNs. Step 1: This first step involves the formation of decision matrix and investigation of data for finding the value of t for which all the triplets becomes T-SFNs. (23) Step 5: This step involves the aggregation of decision matrix d using TSFPWA and TSFPWG operators given in Eqs. (29) and (30). Step 6: Utilize the following score function to rank the alternatives based on the aggregated information obtained in Step 5. Step 7: Based on the ranking of alternatives, the selection of best alternative is carried out. In this section, a numerical real-life problem is solved using the MADM method by utilizing the TSFPWA and TSFPWG aggregation operators for selection of best alternative. Example 1 In this example, we consider the famous software selection problem in which the selection of a suitable software package is carried out among a list of software packages under some attributes. According to this problem, the university computer center needs to select an information system for a better research work production. For this case the computer center, along with HR department of the university, selected four alternatives A i (i = 1, 2, 3, 4) after initial screening based on their past records. The four alternatives are to be evaluated under four attributes g j (j = 1, 2, 3, 4) where g 1, g 2 , g 3 and g 4 denote "Cost of information system", "involvement in performance of university", "Reliability of information system" and "efforts to transform from current system". The weight vector of these four attributes is w = (0.3, 0.25, 0.25, 0.2) T . The decision makers critically observed the four alternatives based on the four attributes and presented their information in the form of T-SFNs in the following decision matrix given in Table 1 . This problem is solved using the MADM algorithm proposed in Sect. 5 and the detailed stepwise illustration of the process is as follows: Step 1: The decision matrix containing the information about the four alternatives by anonymous decision makers. Upon investigation, it is observed that the information provided in Table 1 cannot be considered as picture fuzzy numbers because their sum exceeds 1. The sum of all membership grades of information in Table 1 is given is Table 2 (Table 3) . It is observed that the information provided in Table 1 cannot be considered as spherical fuzzy numbers because the square of their sum exceeds 1. The sum of squares of all elements of Table 1 is given Table 2 . The sum of all triplets of Table 1 is less than 1 if we take t = 3 and are shown in Table 4 . All these observations clearly indicate that the aggregation tools of PFSs as well SFSs could not deal with such type of information. Further, T-SFNs involve four membership grades and hence cannot be aggregated by the aggregation tools of q-ROPFSs, PyFSs as well as IFSs. This shows that existing aggregation tools are unable to deal with T-spherical fuzzy information. Using Eqs. (25-28) discussed in Steps 2, 3 and 4, we found the value of δ ij given by: where Step 5: Utilizing Eqs. (29, 30) and δ ij obtained in Steps 2-5, we aggregate the information of decision makers given in Table 1 and the aggregated data using TSFPWA and TSF-PWG operators is given in Table 5 . Step 6: Utilizing Eq. (31) to get the score values of data obtained in Table 6 . Step 7: Based on the score values obtained in Step 6, the four alternatives are ranked in Table 7 The ranking of alternatives using TSFPWA and TSFPWG operators in Table 7 gives us two possible best alternatives. According to TSFPWA operator, A 2 is the best option while if we consider TSFPWG operator then it comes out that A 4 is the best option. The selection of aggregation tool is up to decision makers. (0.311573, 250135, 247281, 191012) In this section, the comparative study of TSFPWA and TSF-PWG operators is established with power aggregation operators of IFSs and PyFSs. From our study we claim that the pre-existing power aggregation operators in the environment of PyFSs and IFSs cannot handle the data provided in the form of T-SFNs. This is clearly shown in Sect. 6, Example 1. On the other hand, we show that the proposed TSFPWA and TSFPWG aggregation operators can solve the problems having information in the form of q-ROPFSs, PyFSs as well as IFSs. Example 2 We consider the MADM problem discussed in Sect. 6 and drop the abstinence degree. In this way, the data provided in Table 1 will be reduced to q-ROPFNs for q = 3 and is given in Table 8 below. The weight vector of these four attributes is same i.e. w = (0.3, 0.25, 0.25, 0.2) T . We utilized q-ROPFPWA and q-ROPFPWG operators by following the algorithm proposed in Sect. 5 and the results are listed in Tables 8, 9, 10 respectively. TSFPWAoperator TSFPWGoperator Using Eqs. (25-28) discussed in Steps 2, 3 and 4, we found the value of δ ij given by: Step 5: Utilizing Eqs. (19, 20) and δ ij , we aggregate the information of decision makers given in Table 8 and the aggregated data using q-ROPFPWA and q-ROPFPWG operators is given in Table 9 . Step 6: Utilizing Eq. (31) to get the score values of data obtained in Table 10 . Step 7: Based on the score values obtained in Step 6, the four alternatives are ranked in Table 11 . The ranking of alternatives using q-ROPFPWA and q-ROPFPWG operators in Table 11 gives us two possible best alternatives which are totally different from the ranking obtained using TSFPWA and TSFPWG operators given in δ ij = (0.312311, 0.249562, 0.247797, 0.190329) T Table 7 . This shows the importance of using T-SFSs over of other fuzzy frameworks such as IFSs, PyFSs, q-ROPFSs and PFSs. Here the same problem is considered with same data as well. The only difference is that in Example 1 degree of abstinence is considered while in Example 2 the degree of abstinence is neglected. Therefore, the results obtained in Example 1 are more reliable than that of obtained in Example 2. This shows the superiority of T-SFSs and consequently T-spherical fuzzy power aggregation operators over the existing related tools. The advantages of T-spherical fuzzy power aggregation operators are as follows: 1. T-spherical fuzzy power aggregation operators take into account the relationship of the information being used (aggregated) however the previous aggregation operators fail to do so. 2. T-spherical fuzzy power aggregation operators take into account the abstinence and refusal degree while power aggregation operators of IFSs, PyFSs and q-ROFSs consider only membership and non-membership grades. This inclusion of abstinence and refusal grade of membership improves the results and decrease information loss as shown in Example 1 and 2. 3. While using T-spherical fuzzy power aggregation operators, the decision makers have a larger range for assigning membership grades due the parameter t unlike in case of picture fuzzy power aggregation operators or spherical fuzzy power aggregation operators. The key contribution of the work can be summarized below. 1. A concept of T-spherical fuzzy set has been utilized to describe the uncertainties in the data. A T-SFS utilize four functions to describe the imprecision of an event including favor, abstinence, and disfavor and refusal degrees. From the geometry of T-SFS (given in Fig. 1) , it is observed that it has wider range of information as compared to existing IFS, PyFS, PFS, SFS and q-ROFS. Thus, a concept of T-SFS affords an alternative way to trade with the uncertainties. 2. A T-SFS is an extension of several existing sets (see Remark 1) and hence by setting a parameter t , we can deduce such existing sets and their corresponding studies from the presented work. 3. In the work, we stated several power weighted aggregation operators namely, T-spherical fuzzy power weighted, ordered weighted and hybrid average operators. Several desirable relations have been derived to Further, we extend them to geometric operators also and study their features. The major advantage of using such power aggregation operators is that it takes into account the relationship of the information being aggregated as compared to several other existing operators (Garg and Kumar 2020 The MADM algorithm based on the stated operators is explained, which is more generalized and flexible with the parameter t to the decision-maker. The applicability of the algorithm is demonstrated through a numerical example (in Example 1). 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(2018) given by:Step 3: Compute the weighted support Ş Ţ ij of T-SFNs Ţ ij using the following formula given in Eq. (27)where w j is the weight vector of attributes g j .Step 4: Compute the weight δ ij associated with T-SFNs Ţ ij using Eq. (28) where δ ij > 0 such that ∑ n j=1 δ ij = 1. Conflict of interest The authors declare that they have no conflicts of interest regarding the publication of this article.