Aggregation Operators for Interval-Valued Intuitionistic Fuzzy Hypersoft Set with Their Application in Material Selection

The intuitionistic fuzzy hypersoft set (IFHSS) is the most generalized form of the intuitionistic fuzzy soft set used to resolve uncertain and vague data in the decision-making process, considering the parameters’ multi-sub-attributes. Aggregation operators execute a dynamic role in assessing the two prospect sequences and eliminating anxieties from this perception. This paper prolongs the IFHSS to interval-valued IFHSS (IVIFHSS), which proficiently contracts with hesitant and unclear data. It is the most potent technique for incorporating insecure data into decision-making (DM). The main objective of this research is to develop the algebraic operational laws for IVIFHSS. Furthermore, using the algebraic operational law, some aggregation operators (AOs) for IVIFHSS have been presented, such as interval-valued intuitionistic fuzzy hypersoft weighted average (IVIFHSWA) and interval-valued intuitionistic fuzzy hypersoft weighted geometric (IVIFHSWG) operators with their essential properties. Multi-criteria group decision-making (MCGDM) technique is vigorous for material selection. However, conventional methods of MCGDM regularly provide inconsistent results. Based on the expected AOs, industrial enterprises propose a robust MCGDM material selection method to meet this shortfall. The real-world application of the planned MCGDM method for cryogenic storing vessel material selection (MS) is presented. The implication is that the designed model is more efficient and consistent in handling information based on IVIFHSS.


Introduction
MCGDM is deliberated as the most suitable method for verdict the adequate alternative from all probable choices, following conditions or features. Maximum judgments are taken when the intentions and con nes are usually unspeci ed or unclear in real-life circumstances. Zadeh presented the notion of the fuzzy set (FS) [1] to overcome such vagueness and doubts in decision-making (DM). Turksen [2] presented the interval-valued FS (IVFS) with fundamental operations. If the experts consider a membership degree (MD) and a non-membership degree (NMD) in the DM procedure, the FS theories cannot handle the situation. Atanassov [3] resolved the abovementioned limitations and developed the intuitionistic fuzzy set (IFS). Garg and Rani [4] projected some distance measures under IFS setting to resolve DM obstacles. Wang and Liu [5] introduced several operations such as Einstein product, Einstein sum, etc., and AOs for IFS. Garg [6] developed the cosine similarity measures (SM) for IFS considering the interaction between the couples of MD and NMD. Atanassov [7] introduced the topological operators and discussed some essential properties. Garg and Kumar [8] projected the SM to extend the power of distinct IFS. Ejegwa and Agbetayo [9] developed several SM and distance measures under the IFS environment and used their presented measures to resolve DM complications. To measure their relation, Garg and Rani [10] established the correlation coefficient (CC) for complex IFS. Khan et al. [11] offered a MADM technique using complex T-spherical fuzzy power AOs. Atanassov [12] introduced the interval-valued intuitionistic fuzzy set (IVIFS) with some basic operations. Wang et al. [13] proposed the weighted average AOs for IVIFS and established a multi-criteria decision-making (MCDM) technique to resolve DM obstacles. Arora and Garg [14] prolonged the linguistic IFS with prioritized AOs. Garg and Rani [15] settled the MULTIMOORA technique under IFS information using their presented AOs. Xu and Chen [16] developed the weighted geometric and hybrid weighted geometric AOs for IVIFS. ey also constructed the multi-attribute decisionmaking (MADM) technique using their established AOs to resolve DM issues.
Jia and Zhang [17] prolonged the weighted arithmetic AOs for IVIFS and presented the multi-attribute group decision-making (MAGDM) model. Xu and Gou [18] developed several DM methodologies under the IVIFS setting and utilized their methodologies in various real-life problems. Ze-Shui [19] proposed the weighted arithmetic and geometric AOs for IVIFS. Mu et al. [20] protracted the Zhenyuan average and geometric AOs for IVIFS. ey also established some DM approaches to resolve MADM obstacles using Zhenyuan AOs. Zhang [21] developed the Bonferroni mean geometric AOs under the IVIFS setting and presented the MAGDM approach. Park et al. [22] proposed the hybrid geometric aggregation operator for IVIFS and utilized it for MAGDM problems. Gupta et al. [23] developed a corrective model for determining the weight of experts. e weight information of experts is conveyed by interval-valued intuitionistic fuzzy numbers (IVIFNs). Garg and Kumar [24] extended the AOs with their fundamental properties under the linguistic IVIFS environment to solve group decision-making problems. Peng and Yang [25] presented the idea of interval-valued PFS (IVPFS) and prolonged the AOs under-considered environment. Rahman et al. [26] offered geometric and ordered AOs for IVPFS and used their established operators to resolve DM issues. e above-stated FS, IVFS, IFS, IVIFS, PFS, and IVPFS cannot deal with the parametrized values of the alternatives. Molodtsov [27] introduced soft sets (SS) theory and explained some basic operations with their features to handle confusion and uncertainties. Fatimah et al. [28] extended the concept of SS to N-soft set with some basic operations and their properties. Maji et al. [29] extended the SS theory and developed some fundamental operations. Yuksel et al. [30] extended the SS theory to soft expert sets and utilized their theory to calculate the patient's prostate cancer risk. Maji et al. [31] introduced the fuzzy soft set theory by merging SS and FS. Fatimah and Alcantud [32] proposed the multi fuzzy-soft set theory with fundamental operations and their properties. ey also established a DM methodology employing their progressive approach to resolve DM obstacles. Garg et al. [33] presented the spherical fuzzy soft topology with some fundamental operations and discussed their properties. Maji et al. [34] developed basic operations for their properties for the intuitionistic fuzzy soft set (IFSS). Arora and Garg [35] proposed the AOs for IFSS and utilized their developed AOs to solve MCDM obstacles. Garg and Arora [36] extended the TOPSIS technique by employing the CC under the IFSS environment. ey also developed the Maclaurin symmetric mean AOs for the IFSS setting [37]. Garg and Arora [38] proposed the idea of generalized IFSS with some fundamental operations and essential properties. Jiang et al. [39] introduced the interval-valued IFSS (IVIFSS) with some basic operations and their properties. Zulqarnain et al. [40] planned the TOPSIS technique for IVIFSS based on correlation measures to solve MADM problems. Smarandache [41] projected the idea of the hypersoft set (HSS), which penetrates multiple sub-attributes in the parameter function f, which is a characteristic of the Cartesian product with the n attribute. Associated with SS and other prevailing ideas, Smarandache HSS is the most appropriate model that grips the deliberated constraints' multiple sub-attributes. Zulqarnain et al. [42] extended the TOPSIS approach using the correlation coefficient for IFHSS to solve MADM complications. Zulqarnain et al. [43] prolonged the AOs for the IFHSS setting and established a DM technique based on their developed AOs. Jafar et al. [44] developed the intuitionistic fuzzy hypersoft matrices with fundamental operations. Debnath [45] introduced the IVIFHSS with several fundamental operations and their properties. Sunthrayuth et al. [46] established a novel MCDM technique based on Einstein's weighted average operator for Pythagorean fuzzy hypersoft sets. IFHSS plays a vital role in decision-making by combining multiple sources into a single value. IFHSS is a hybrid intellectual structure of IFSS. A boosted sorting development captivates the investigators to crash unsolved and insufficient facts. Interpreting the exploration consequences, it is concluded that the IFHSS performs an energetic part in DM by assembling several causes into a solitary value. erefore, to inspire the current research on IVIFHSS, we will describe AOs built on irregular information. e core objectives of the present study are as follows: (i) IVIFHSS deals competently with multidimensional concerns by looking at the multi-sub-attributes of the considered parameters in the DM procedure. To preserve this benefit in concentration, we extend IFHSS to IVIFHSS and set up AOs for IVIFHSS.
(ii) AOs for IVIFHSS are well-known attractive estimate AOs. It has been observed that the prevailing AOs aspect is irresponsible for scratching the correct detection of the DM process. To overcome these specific complications, these existing AOs need to be reviewed. We introduce the advanced operational laws for interval-valued intuitionistic fuzzy hypersoft numbers (IVIFHSNs).
(iii) IVIFHSWA and IVIFHSWG operators have been introduced with their essential features using developed operational laws. (iv) A new algorithm based on planned operators has been established to solve the problems of MCGDM under the IVIFHSS scenario. (v) Material selection is an essential feature of manufacturing as it understands the stable conditions for all components. MS is a complex but essential step in professional development. Lack of material selection will damage the manufacturer's efficiency, productivity, and eccentricity. (vi) A comparative analysis of the latest MCGDM technique and existing methods is presented to consider the utility and superiority.
e organization of this research is estimated to be as follows: e Section 2 of this study contains some basic concepts that help us develop the structure of the later research. Section 3 introduces some new operational laws for IVIFHSN. Also, in the same section, IVIFHSWA and IVIFHSWG operators are presented based on the basic features of our developed operators. In Section 4, an MCGDM approach is developed based on the proposed AOs. A numerical example for material selection in the manufacturing industry is discussed in the same section to confirm the practicality of the established technique. In addition, Section 5 provides a brief comparative analysis to confirm the validity of the advanced approach.

Preliminaries
is section contains some basic definitions that will structure the following work.
Definition 1 (see [27]). Let U and N be the universe of discourse and set of attributes, respectively. Let P(U) be the power set of U and A⊆N. A pair (Ω, A) is called a SS over U, and its mapping is expressed as follows: Also, it can be defined as follows: Definition 2 (see [41]). Let U be a universe of discourse and P(U) be a power set of U and t � t 1 ; t 2 ; t 3 , ..., t n , n ≥ 1 and T i represented the set of attributes and their corresponding sub-attributes, such as nl is a collection of sub-attributes, where 1 ≤ h ≤ α; 1 ≤ k ≤ β; and 1 ≤ l ≤ c, and α; β; c ∈ N, en the pair (F, T 1 × T 2 × T 3 × ... × T n ) � (Ω, A) is known as HSS and defined as follows: It is also defined as Definition 3 (see [12]). U be a universe of discourse, and A be any subset of U. en, the IVIFS A over U is defined as: represents the MD and NMD intervals, respectively. Also, κ l Definition 4 (see [39]). Let U be a universe of discourse and N be a set of attributes. en a pair (Ω, N) is called an IVIFSS over U. Its mapping can be expressed as where IK U represents the collection of interval-valued intuitionistic fuzzy subsets of the universe of discourse U.
represents the MD and NMD intervals, respectively. Also, Definition 5 (see [41]). Let U be a universe of discourse and P(U) be a power set of U and t � t 1 ; t 2 ; t 3 , ..., t n , n ≥ 1 and T i represented the set of attributes and their corresponding sub-attributes, such as T i ∩ T j � φ, where i ≠ j for each n ≥ 1 and i, j ∈ 1, 2, 3 ..., n nl is a collection of sub-attributes, where 1 ≤ h ≤ α; 1 ≤ k ≤ β;, and 1 ≤ l ≤ c, and α; β; c ∈ N. en the pair (F, T 1 × T 2 × T 3 × ... × T n ) � (Ω, A) is known as IFHSS and defined as follows: It is also defined as , represents the MD and NMD, respectively, such as Definition 6 (see [45]). Let U be a universe of discourse and P(U) be a power set of U and t � t 1 ; t 2 ; t 3 , ..., t n , n ≥ 1 and T i represented the set of attributes and their corresponding sub-attributes, such as T i ∩ T j � φ, where i ≠ j for each n ≥ 1 and i, j ∈ 1, 2, 3, . . . , n { }. Assume T 1 × T 2 × T 3 × · · · × � A � d 1h × d 2k × · · · × d nl is a collection of sub-attributes, where 1 ≤ h ≤ α; 1 ≤ k ≤ β; and 1 ≤ l ≤ c, and α; β; c ∈ N. en the pair (F, T 1 × T 2 × T 3 × · · · × T n ) � (Ω, A) is known as IVIFHSS and defined as follows: Mathematical Problems in Engineering 3 It is also defined as (Ω, represents the MD and NMD intervals, respectively, such as, κ l To compute the alternative ranking, the score function and accuracy function for IVIFHSS can be stated as, if F � And conditions ω i > 0, n i�1 ω i � 1; ] j > 0, m j�1 ] j � 1. en, the IVIFHSWA operator is defined as IVIFHSWA: Ψ n > Ψ.
ω i and ] j shows the expert's and multi-sub-attributes weights, respectively, such as ω i > 0, n Proof. e proof of the above presented IVIFHSWA operator can be proved by mathematical induction: For n � 1, we get ω 1 � 1. en, we have For m � 1, we get ] 1 � 1. en, we have So, the above theorem is proved for n � 1 and. m � 1. Assume that for m � α 1 + 1, n � α 2 and m � α 1 , n � α 2 + 1, the above theorem holds. Such as For m � α 1 + 1 and n � α 2 + 1, we have Hence, it holds for m � α 1 + 1 and n � α 2 + 1. So, we can say that eorem 1 holds for all values of m and. n.
As m j�1 ] j � 1 and n i�1 ω i � 1, then we have 6 Mathematical Problems in Engineering Proof. As we know that Similarly, respectively.
Using the score function, we have Using order relation among two IVIFHSNs, we have ) be two IVIFHSNs. en, using Definition 7 (1) ) be an IVIFHSN and β > 0. en using Definition 7, we have ) be a collection of IVIFHSNs, and ω i and ] j are the weight vector for experts and multi sub-parameters, respectively, with given condi- ω i and ] j are expert's and multi-sub-attributes weights respectively, such as.
Proof. e proof of the above theorem can be proved using mathematical induction. For n � 1, we get ω 1 � 1. en, we have For m � 1, we get ] 1 � 1. en, we have Mathematical Problems in Engineering 9 So, for n � 1 and m � 1 the IVIFHSWG operators hold. Now, for m � α 1 + 1, n � α 2 and m � α 1 , n � α 2 + 1, such as For m � α 1 + 1 and n � α 2 + 1, we have So, it is proved the for m � α 1 + 1 and n � α 2 + 1 holds. So, the IVIFHSWG operator holds for all values of m and n.   3×4 given as

Properties of IVIFSWG
Proof. As we know that all As m j�1 ] j � 1 and n i�1 ω i � 1, then we have □

Boundedness. Let F� d ij be a collection of IVIFHSNs
Proof. As we know that Similarly,

then inequalities (C) and (D) can be transferred into the form:
and respectively. Using the score function, By order relation between two IVIFHSNs, we have ) be an IVIFHSN. en, ) be two IVIFHSNs. en, using Def- (50) So, ) be an IVIFHSN and β > 0. en using Definition 7, we have

Multi-Criteria Group Decision-Making Approach Based on Proposed Operators
To validate the implications of planned AOs, a DM approach is developed to remove MCGDM obstacles. In addition, numerical illustration is provided to endorse the convenience of the proposed method.

Proposed MCGDM Approach.
Let I � I 1 , I 2 , I 3 , . . . , I s } and U � U 1 , U 2 , U 3 , . . . , U r be the set of alternatives and experts, respectively. e weights of experts are given as gives their opinion on each alternative in IVIFHSNs. e algorithmic rule-based on developed operators is given as follows: Step 1: Expert's opinion for each alternative in the form of IVIFHSNs.
Step 2: Develop the normalized decision matrices for each alternative by converting the cost type attributes to benefit type using the normalization rule.
cost type parameter, benefit type parameter.
Step 3: Compute the aggregated values using IVIFHSWA and IVIFHSWG operators for each alternative.
Step 4: Compute the score values for each alternative using the score function.
Step 5: Determine the most suitable alternative.

Numerical Example.
It is an intelligent transformation of fossil waste energy, such as natural gas first converted into hydrogen. e energy content per kilogram of hydrogen is 120 MJ. e advantage of methanol is an extraordinary six times [47]. Hydrogen has a bit of volumetric energy density associated with its particular gravimetric density. A stable thickness of up to 700 bar is not a large enough property for hydrocarbons like gasoline and diesel. Only liquid hydrogen can affect a realistic extent, still less than a quarter of the quantity of gasoline. erefore, hydrogen vessels for motor tenders will surmount more than used fluid hydrocarbon containers [48]. Cryogenic storage containers are also considered cryogenic storage containers. e Dewar is a double-walled super-insulated container. e vehicles fluid oxygen, nitrogen, hydrogen, helium, and argon, temperatures <110 K/163°C. e assortment method begins with a preliminary screening of the material used for the dashboard and is captivated by the validation configuration built into the application. Defining the ingredients used by the preliminary MS of the dashboard fashioning is serious. en select from four material assessment abilities: I 1 � Ti-6Al-4V, I 2 � SS301-FH, I 3 � 70Cu-30Zn, and I 4 � Inconel 718. e aspect of material assortment is specified as follows: L � d 1 � Specific gravity � attaining data around the meditation of resolutions of numerous materials, e corresponding sub-attributes of the considered parameters, Specific gravity � attaining data around the meditation of resolutions of numerous materials � d 1 � d 11 � assess corporal variations, d 12 � govern the degree of regularity among tasters}, be a set of all sub-attributes with weights (0.3, 0.1, 0.2, 0.4) T . Let U 1 , U 2 , U 3 , U 4 be a set of four experts with weights (0.1, 0.2, 0.4, 0.3) T . To judge the optimal alternative, experts deliver their preferences in IVIFHSNs.

By IVIFHSWA Operator
Step 1: e expert's opinion in the IVIFHSNs form for each alternative is given in Tables 1-4.
Step 2: All parameters are of the same type. So, no need to normalize.
Step 3: Compute the aggregated values for each alternative using the IVIFHSWA operator.            Step 4: Applying the score function S � κ l Step 5: From the above calculation, we get S(Θ 4 ) > S(Θ 3 ) > S(Θ 2 ) > S(Θ 1 ). Which shows that I 4 is the best alternative.
Step 6: So, I 4 > I 3 > I 2 > I 1 is the obtained ranking of alternatives.

By IVIFHSWG Operator
Step 1 and step 2 are similar to section 4.2.1.
Step 3: Utilized the developed IVIFHSWG operator to compute the aggregated values for each alternative.      Step 5: From the above calculation, we get the ranking of alternatives S(Θ 4 ) > S(Θ 2 ) > S(Θ 3 ) > S(Θ 1 ). Which shows that I 4 is the best alternative.
Step 6: So, I 4 > I 2 > I 3 > I 1 is the obtained ranking of alternatives.
e material assessment through the intended imagery phase is excellent on a hypothetical level. Specific content is more likely to be accurate. Face-centered cube materials are typically used at minor temperatures -163°C and I 1 � Ti-6Al-4V ratings first.
is is steadfast in employing initial investigations and real-world maneuvers. Austenitic steels are still classically used in melted nitrogen or hydrogen storing vessels [49].

Comparative Studies
To validate the usefulness of the proposed technique, a comparison between the proposed model and the prevailing methods is planned in the next section.

Supremacy of the Proposed Technique.
e proposed method competently delivers realistic decisions in the DM procedure. We introduced the MCGDM approach using our developed IVIFHSWA and IVIFHSWG operators. Our plan MCGDM technique provides the most subtle and precise information on DM complications. e proposed model is multi-purpose and communicative, adapting to changing instability, commitment, and productivity. Different models have specific classification processes, so there is a direct change in the classification of expected methods according to their expectations. is systematic study and evaluation determined that the results obtained from the conventional method are erroneously equal to the hybrid structure. In addition, due to some favorable conditions, many composite structures of FS such as IVFS, IVIFS, and IVIFSS concentrate in IVIFHSS. It is easy to syndicate insufficient and obscure data in the DM method. Data about the matter can be described more accurately and rationally. erefore, our proposed method is more efficient, meaningful, superior, and better than multiple mixed FS structures. Table 5 below provides an analysis of the technique presented and the features of some existing models.

Comparative Analysis.
To prove the utility of the planned method, we equate the attained consequences with some prevailing approaches under IVPFS, IVIFSS, and IVPFSS. A summary of all values is specified in Table 6. Wang and Liu [13] developed IVIFWA, and Xu and Chen [16] presented that IVIFWG operators cannot compute the parametrized values of the alternatives. Furthermore, if any expert considers the MD and NMD whose sum exceeds 1, the aforementioned AOs fail to accommodate the scenario. Zulqarnain et al. [40] established AOs for IVIFSS that cannot accommodate the decision-maker's selection when the sum of upper MD and NMD parameters surpasses one. It is detected that, in certain conditions, the existing AOs provide some unattractive outcomes. So, to resolve such complications, we developed the AOs for IVIFHSS, which capably deal with the multi-sub attributes compared to existing AOs. us, IVIFHSS is the most generalized form of IVIFSS. Hence, based on the abovementioned details, the anticipated operators in this paper are more influential, consistent, and Mathematical Problems in Engineering 19 prosperous. A comparison of the proposed model with prevailing models is given in the following Table 6. e graphical demonstration of Table 6 is given in the following Figure 1.

Conclusion
Decision-making is a pre-planned process for arranging and choosing logical preferences from multiple alternatives. DM is a multifaceted procedure because it can switch from one scene to another. It is serious about differentiating how much real perspective data decision-makers need. e most operational approach in DM is paying close attention and focusing on your goals. In manufacturing, the better stability of manipulation is neutral; Authoritative material and fabricated surround extensive content. In a real DM, assessing alternative facts as told by a professional is permanently incorrect, irregular, and impressive. erefore, IVIFHSNs can be used to match this uncertain data. e main determination of this work is to extend the AOs for interval-valued intuitionistic fuzzy hypersoft sets. First, we introduce the operational laws for the interval-valued intuitionistic fuzzy hypersoft environment. Considering the developed operational laws, we introduced IVIFHSWA and IVIFHSWG operators with their fundamental properties. Also, a DM method is planned to deal with the complications of MCGDM based on established operators. To illustrate the strength of the developed method, we present a comprehensive mathematical example for MS in manufacturing engineering. A comprehensive analysis and some existing methods are presented to confirm the practicality of the intended approach. Finally, based on the results obtained, it is determined that the method proposed in this study is the most practical and operative to resolve MCGDM obstacles compared to existing techniques. Future investigations highlight emergent DM methods, such as Einstein's hybrid AOs in the IVIFHSS setting. We are confident that these extensive growths and conjectures will support considered professional consideration extents convoluted in the world's environment.

Data Availability
No data were used to support this study.

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