Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information

Kamacı, Hüseyin; Marinkovic, Dragan; Petchimuthu, Subramanian; Riaz, Muhammad; Ashraf, Shahzaib

doi:10.3390/sym14102140

Open AccessArticle

Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information

by

Hüseyin Kamacı

¹,

Dragan Marinkovic

^2,*

,

Subramanian Petchimuthu

³,

Muhammad Riaz

⁴

and

Shahzaib Ashraf

⁵

¹

Department of Mathematics, Faculty of Science and Arts, Yozgat Bozok University, Yozgat 66100, Turkey

²

Department of Structural Analysis, Technical University of Berlin, 10623 Berlin, Germany

³

Department of Science and Humanities (Mathematics), University College of Engineering, Nagercoil 629004, India

⁴

Department of Mathematics, University of the Punjab, Lahore 54590, Pakistan

⁵

Institute of Mathematics, Khwaja Fareed University of Engineering and Information Technology, Rahim Yar Khan 64200, Pakistan

^*

Author to whom correspondence should be addressed.

Symmetry 2022, 14(10), 2140; https://doi.org/10.3390/sym14102140

Submission received: 18 September 2022 / Revised: 26 September 2022 / Accepted: 30 September 2022 / Published: 13 October 2022

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Abstract

:

The advantages of the intuitionistic fuzzy set, Pythagorean fuzzy set, and q-rung orthopair fuzzy set are all carried over into the linear Diophantine fuzzy set by extending the restrictions on the grades. Linear Diophantine fuzzy sets offer a wide range of practical applications because the reference parameters allow evaluation andto express their judgments about membership and nonmembership degrees in a variety of ways. Linguistic-valued information cannot be described by linear Diophantine fuzzy numbers since precise numbers are used in linear Diophantine fuzzy systems. In this paper, we first present the novel idea of a linguistic linear Diophantine fuzzy set, which is the hybrid structure of the linear Diophantine fuzzy set and the linguistic term set. Furthermore, some basic operational rules with novel distance measures, namely, Hamming, Euclidean, and Chebyshev distance measures, are established. Based on the newly defined concept of distance measure, an extended TOPSIS technique is presented to tackle the linguistic uncertainty in real-world decision support problems. A numerical example is illustrated to support the applicability of the proposed methodology and to analyze symmetry of the optimal decision. A comparison analysis is constructed to show the symmetry, validity, and effectiveness of the proposed method over the existing decision support techniques.

Keywords:

fuzzy modeling; linear Diophantine fuzzy set; linguistic linear Diophantine fuzzy set; symmetry; TOPSIS; MCDM

MSC:

03E72; 94D05; 90B50

1. Introduction

The fuzzy set, which was first developed by Zadeh in 1965 [1], has had considerable success in a number of different domains and is regarded as a useful tool for decision-making, medical diagnosis, pattern recognition, and fuzzy inference (Cateni, S., Colla, V., & Nastasi, G. (2013) [2]; Das et al., 2016 [3]; Yager, 1977 [4]). The fuzzy set has been extended in several ways since it was first introduced. The intuitionistic fuzzy set (IFS), developed by Atanassov, is one of a fuzzy set’s generalizations (1986) [5]. The membership and nonmembership functions can be stated as the grade of satisfactory and unsatisfactory, respectively, which is a typical aspect of IFS. The sum of the membership degree and the nonmembership degree must, however, be equal to or lower than one, according to IFSs. Some information related to decision evaluation cannot be successfully communicated in this situation due to the possibility that certain decision-makers may supply information for an attribute where the total of membership degree and nonmembership degree is more than one. As a result, to address these issues, Yager (2013) [6] proposed the idea of a Pythagorean fuzzy set (PyFS), which has the distinguishing characteristic that the square sum of the grade of membership and grade of nonmembership is less than or equal to one. With the development of PyFS theory, considering the complexity of the problems, a new concept was described again by Yager (2017) [7], the q-rung orthopair fuzzy set (q-ROFS), where the sum of the qth power

(q \geq 1)

of membership degree and nonmembership degree is restricted to one. It can be seen that q-ROFs are general because IFSs and PyFSs are their special cases. Many authors have studied them extensively and deeply; these studies mainly include the following aspects: (1) the basic theory research, such as operational laws (Peng & Luo, 2021 [8]; Rahman et al., 2017 [9]), similarity and distance measures (Ejegwa, 2020 [10]; Farhadinia et al., 2021 [11]; Garg, (2018a) [12]; Hussian et al., (2019) [13]), (2) some extended multicriteria decision-making (MCDM) methods (Aydemir & Gunduz, 2019; Biswas, & Deb, 2021; Büyüközkan et al., 2021; Ejegwa, 2019, Jana et al., 2019), (3) aggregation operators research (Aydemir, & Gunduz, 2019 [14]; Biswas, & Deb, (2021) [15]; Jana et al., (2019) [16]), and so on. Akram et al. (2022) [17] proposed a new combined model of complex Fermatean fuzzy N-soft set, and Feng el al. (2022) [18] proposed a new SF for ranking order of q-ROFNs for MADM. Karaaslan and Cagman (2022) [19] developed some similarity measures with parameter trees based on soft set theory.

According to Riaz and Hashmi (2019) [20], these set theories have restrictions in relation to membership and nonmembership degrees. They suggested the use of reference/control parameters along with a linear Diophantine fuzzy set (LDFS) to remove these restrictions. Riaz et al. (2019; 2020) and Ayub et al. (2021) [21] argued that LDFS is more flexible and reliable than existing concepts of IFSs, PFSs, and q-ROFSs. In 2021, Kamacı et al. [22,23] studied the theoretical aspects and complex types of LDFSs. Due to the advantages of LDFS in practice, they attracted the attention of many researchers in different scientific fields, and many seminal articles were published (Almagrabi et al., 2021 [24]; Izmand et al., 2021 [25]; Mahmood et al., 2021 [26]). The research on other generalizations of a fuzzy set has been growing rapidly (Ashraf et al., 2019 [27]; Cuong, 2014 [28]; Kamacı et al., 2021a, 2021b [29,30]). Decision support systems in real-life scenarios can be seen (Deveci et al., 2022a; 2022b [31,32]).

Real-world problems are fuzzy and unpredictable, making it challenging to give qualitative evaluation using accurate values. People frequently express their ideas at this period using linguistic words. In some real-world situations, evaluators treat linguistic data as the values of linguistic variables; that is, the variables’ values are expressed linguistically, rather than numerically, using terms such as “very awful”, “bad”, “fair”, “better”, “good”, and “somewhat good”. The concept of linguistic variables was first developed by Zadeh (1975 [33]), who then concentrated on its usage in fuzzy reasoning to describe information that cannot be represented by precise numbers. Based on linguistic evaluations, Herrera et al. (1996a, 1996b, 2000 [34,35,36]) suggested some consensus models for group decision-making. Additionally, linguistic ordered weighted geometric operator and linguistic hybrid aggregation operator were developed by Xu (2014, 2015 [37,38]), who subsequently used them to solve multiple attribute group decision-making problems including linguistic information. Some authors studied multi-bijective linguistic decision systems (Gong et al., 2010 [39]). Rodríquez et al., (2021) [40] and Yu et al., (2017 [41]) focused on the fuzzy linguistic term sets and their applications in handling multicriteria decision-making. The linguistic intuitionistic fuzzy numbers (LIFNs) and linguistic intuitionistic fuzzy sets (LIFSs) were characterized by deriving the language forms of intuitionistic fuzzy variables (Chen et al., 2015 [42]; Ou et al., 2018 [43]; Zhang, 2014 [44]). In recent years, many researchers focused on the aggregation operators (AOs) of LIFNs, such as power AOs (Garg, & Kumar, 2019 [45]; Liu, & Qin, 2017 [46]; Liu, & Wang, 2017 [47]), Einstein AOs (Garg, & Kumar, 2018 [48]), Heronian AOs (Liu et al., 2014 [49]), and Bonferroni AOs (Wei et al., 2013 [50]). Later, Garg (2018b [51]) proposed an extended form of the LIFS which is called the linguistic Pythagorean fuzzy set (LPyFS). There are many papers in the literature related to LDFSs [52]. Lin et al. (2020 [53]) investigated the difference between LIFS and LPyFS, and then initiated the theory of linguistic q-rung orthopair fuzzy set (Lq-ROFS), which loosened the existing constraints for linguistic membership and nonmembership degrees in the structures of LIFS and LPyFS. For more linguistic fuzzy approaches, see (Jin et al., 2019 [54]; Liu et al., 2020 [55]). Some extensive work related to different extensions of fuzzy sets can be seen in (Deveci et al., 2022c; 2022d; 2022e [56,57,58]). Ali et al. [59] and Ashraf et al. [60] proposed some AOs for interval-valued picture fuzzy set. Kazemitash et al. [61] and Bozanic et al. [62] gave some ideas related to some different extensions of fuzzy set. For other terminologies not discussed in the paper, the readers are referred to [63,64,65].

The prevalent theories of LIFS, LPyFS, and Lq-ROFS have many applications in a variety of real-world contexts, but they also have some drawbacks connected to linguistic membership and nonmembership grades. With the addition of reference parameters that are expressed in linguistic terms, we develop the novel idea of the linguistic linear Diophantine fuzzy set (LLDFS) to remove these limitations. Due to the usage of linguistic-valued reference parameters, the suggested notion of LLDFS is more effective and adaptable than other linguistic fuzzy techniques. Additionally, LDFS models under linguistic information can likewise be applied to LLDFS models. By altering the physical meaning of membership, nonmembership, and reference parameters in the structure of LDFS, we may state that LLDFS categorizes the data in linguistic multicriteria decision-making (LMCDM) situations. With the use of linguistic reference/control parameters, this set widens the space for linguistic membership and nonmembership degrees, covering the spaces of the linguistic fuzzy structures previously stated. The following list includes some of this paper’s key points.

(1): More broadly applicable than LIFS, LPyFS, and Lq-ROFS are the theories of LLDFS.
(2): The idea of LLDFS makes it possible to express, in language terms, the degrees of membership and nonmembership as well as the reference parameters found in the structure of LDFSs. As a result, it can handle decision-making based on LDFS with regard to linguistic information.
(3): In some real-life problems, the sum of linguistic-valued degrees of membership and nonmembership to which an alternative satisfying an attribute provided by the decision-maker (DM) may be larger than g, where $g + 1$ is the number of elements of the linguistic term set, and their sum of squares is also larger than $g^{2}$ . The LIFS and LPyFS fail in such situations. To overcome these shortcomings, Lq-ROFS is proposed, using the condition that the sum of the qth power ( $q \geq 1$ ) of linguistic membership degree and linguistic nonmembership degree is limited to the interval $[0, g^{q}]$ . In some practical problems, both the linguistic membership degree and the linguistic nonmembership degree may be equal to g, which contradicts the constraint of Lq-ROFS. LLDFS can deal with such situations, and thus provides a large number of applications to the LMCDM for such real-life problems.
(4): The proposed model and LMCDM issues are shown to be closely related. This link leads to the construction of a modified TOPSIS algorithm to handle uncertainty in multi-attribute data in a parametric way. LMCDM issues are satisfactorily solved by the linguistic linear Diophantine fuzzy TOPSIS (LLDF-TOPSIS) approach, which enhances the TOPSIS methods based on LIFSs, LPyFSs, and Lq-ROFSs.

The rest of the paper is organized as follows. In Section 2, some basic concepts of linguistic term set and LDFS are briefly reviewed. In Section 3, we introduce the concept of LLDFS and discuss their basic operational laws, weighted aggregation operators, and score functions. Section 4 presents some formulas to measure the distance between two linguistic linear Diophantine fuzzy numbers (LLDFNs). Section 5 proposes a modified TOPSIS procedure to deal with LMCDM under the LLDF environment. To determine the consistency and validity of the elaborated LLDF-TOPSIS, an illustrative example is given that selects the best software consultants. Finally, the sensitivity analysis, comparison analysis, and merits of the proposed LLDF-TOPSIS method are also discussed. The conclusions are given in Section 6.

2. Preliminaries

This section reviews some related concepts to facilitate the discussions in the next sections.

2.1. Linguistic Term Set

The linguistic approach is an approximate technique that represents qualitative aspects as linguistic values by means of linguistic variables.

Definition 1

(Herrera et al., 1996a, 2000 [34,35]). The set

Ł = {ł_{0}, ł_{1}, \dots, ł_{g}}

is called a (finite) linguistic term set with odd cardinality

g + 1

, where

ł_{κ}

represents a possible value of a linguistic variable. The linguistic terms should satisfy the following characteristics:

(1): The order relation: $ł_{κ} \geq ł_{τ}$ if $κ \geq τ$ ;
(2): The negation operator: $n e g (ł_{κ}) = ł_{g - κ}$ ;
(3): The max (maximization) operator: $m a x {ł_{κ}, ł_{τ}} = ł_{κ}$ if $ł_{κ} \geq ł_{τ}$ ;
(4): The min (minimization) operator: $m i n {ł_{κ}, ł_{τ}} = ł_{κ}$ if $ł_{κ} \leq ł_{τ}$ .

Example 1.

For

g = 10

,

\begin{matrix} Ł = \{\begin{matrix} ł_{0} = A b s o l u t e l y L o w (A L), ł_{1} = E x t r e m e l y L o w (E L), ł_{2} = Q u i t e L o w (Q L), ł_{3} = L o w (L), \\ ł_{4} = M i l d l y L o w (M L), ł_{5} = M e d i u m (M), ł_{6} = M i l d l y H i g h (M H), ł_{7} = H i g h (H), \\ ł_{8} = Q u i t e H i g h (Q H), ł_{9} = E x t r e m e l y H i g h (E H), ł_{10} = A b s o l u t e l y H i g h (A H) \end{matrix}\} \end{matrix}

is a linguistic term set. The cardinality of this set is

g + 1 = 11

.

Considering the set Ł in Example 1, the symmetrical and nonsymmetrical distributions of the eleven linguistic labels of this linguistic term set can be presented as in Figure 1 and Figure 2, respectively.

To preserve all the given information, Xu (2004 [37]) extended discrete linguistic term set Ł to a continuous linguistic term set.

Definition 2

(Xu, 2004 [37]). Let

Ł = {ł_{0}, ł_{1}, \dots, ł_{g}}

be a linguistic term set with odd cardinality

g + 1

. Then,

Ł_{[0, g]} = {ł_{κ} : ł_{0} \leq ł_{κ} \leq ł_{g}, κ \in [0, g]}

is an extended form of and it is termed to be a continuous linguistic term set for Ł.

If

ł_{κ} \in Ł

, then

ł_{κ}

is termed to be the original linguistic term, otherwise

ł_{κ}

is said to be the virtual linguistic term (Xu, 2004 [37]).

Example 2.

Consider the linguistic term set Ł in Example 1.

Ł_{[0, 10]} = {ł_{κ} : ł_{0} \leq ł_{κ} \leq ł_{10}, κ \in [0, 10]}

is a continuous linguistic term set for Ł. For example,

ł_{7} \in Ł

is an original linguistic term, but

ł_{7.4} \notin Ł

(

ł_{7.4} \in Ł_{[0, 10]}

) is a virtual linguistic term and it can be considered as the corresponding degree between high (H) and quite high (QH).

2.2. Linear Diophantine Fuzzy Set

Riaz and Hashmi (2019 [20]) emphasized that while the theories of IFSs, PyFSs, and q-ROFSs are excellent tools in handling multicriteria decision-making problems where alternatives are evaluated by an expert(s) according to the choice parameters, they cannot deal with multicriteria decision-making problems where alternatives are evaluated by an expert(s) according to the choice parameters controlled by the reference parameters. Thus, they argued that the theories of IFSs, PyFSs, and q-ROFSs have their limitations related to the membership degree and nonmembership degree. To remove these restrictions, they proposed the idea of LDFS by integrating reference/control parameters into the structures of IFS, PyFS, and q-ROFS. Moreover, they proposed that considering the special cases of reference parameters, it is obvious that LDFSs are the more general forms of FSs, IFSs, PyFSs, and q-ROFSs. Therefore, LDFS-based decision-making methods can deal with multicriteria decision-making problems under the environments of FSs, IFS, PyFS, and q-ROFS. The definition of LDFS is as follows.

Throughout this paper,

H = {ℏ_{i} : i = 1, 2, \dots, s}

denotes the universal discourse set.

Definition 3

(Riaz, & Hashmi, 2019 [20]). An LDFS D in

H

is described as

\begin{matrix} D = {(ℏ_{i}, 〈 Ψ_{D} (ℏ_{i}), Θ_{D} (ℏ_{i}) 〉, 〈 ρ_{D} (ℏ_{i}), σ_{D} (ℏ_{i}) 〉) : ℏ_{i} \in H} \end{matrix}

(1)

where

ψ_{D} (ℏ_{i}), Θ_{D} (ℏ_{i}), ρ_{D} (ℏ_{i}), σ_{D} (ℏ_{i}) \in [0, 1]

, respectively, represent the degrees of membership, nonmembership, and reference/control parameters of

ℏ_{i} \in H

into the set D. These degrees fulfill the constraint

\begin{matrix} 0 \leq ρ_{D} (ℏ_{i}) + σ_{D} (ℏ_{i}) \leq 1 and 0 \leq ρ_{D} (ℏ_{i}) Ψ_{D} (ℏ_{i}) + σ_{D} (ℏ_{i}) Θ_{D} (ℏ_{i}) \leq 1 . \end{matrix}

for all

ℏ_{i} \in H

. The hesitation margin of each

ℏ_{i} \in H

is

π_{D} (ℏ_{i}) Φ_{D} (ℏ_{i}) = 1 - (ρ_{D} (ℏ_{i}) Ψ_{D} (ℏ_{i}) + σ_{D} (ℏ_{i}) Θ_{D} (ℏ_{i}))

, where

π_{D}

is the reference/control parameter related to the degree of hesitancy. Simply,

ℵ = (〈 Ψ_{D}, Θ_{D} 〉, 〈 ρ_{D}, σ_{D} 〉)

is named linear Diophantine fuzzy number (LDFN) with

0 \leq ρ_{D} + σ_{D} \leq 1

and

0 \leq ρ_{D} Ψ_{D} + σ_{D} Θ_{D} \leq 1

.

Example 3.

Let

H = {ℏ_{i} : i = 1, 2, \dots, 5}

be a collection of some life-saving drugs. Let us define the following notions.

\begin{matrix} Ψ_{D} (ℏ) & = M e m b e r s h i p g r a d e . \\ Θ_{D} (ℏ) & = N o n m e m b e r s h i p g r a d e . \\ ρ_{D} (ℏ) & = G o o d i m p a c t a g a i n s t i n f e c t i o n . \\ σ_{D} (ℏ) & = N o t g o o d i m p a c t a g a i n s t i n f e c t i o n . \end{matrix}

Then, its LDFS is given in Table 1.

Further, Riaz and Hasmi (2019) described some operational rules for the LDFNs as follows:

Let

ℵ = (〈 Ψ_{D}, Θ_{D} 〉, 〈 ρ_{D}, σ_{D} 〉)

,

ℵ_{1} = (〈^{1} Ψ_{D},^{1} Θ_{D} 〉, 〈^{1} ρ_{D},^{1} σ_{D} 〉)

and

ℵ_{2} = (〈^{2} Ψ_{D},^{2} Θ_{D} 〉, 〈^{2} ρ_{D},^{2} σ_{D} 〉)

be three LDFNs in D and

ϖ > 0

. Then,

$ℵ_{1} \subseteq ℵ_{2} \Leftrightarrow$ $^{1} Ψ_{D} \leq^{2} Ψ_{D}$ , $^{1} Θ_{D} \geq^{2} Θ_{D}$ , $^{1} ρ_{D} \leq^{2} ρ_{D}$ and $^{1} σ_{D} \geq^{2} σ_{D}$ ;
$ℵ_{1} = ℵ_{2} \Leftrightarrow$ $^{1} Ψ_{D} =^{2} Ψ_{D}$ , $^{1} Θ_{D} =^{2} Θ_{D}$ , $^{1} ρ_{D} =^{2} ρ_{D}$ and $^{1} σ_{D} =^{2} σ_{D}$ ;
$ℵ^{c} = (〈 Θ_{D}, Ψ_{D} 〉, 〈 σ_{D}, ρ_{D} 〉)$ ;
$ℵ_{1} \cup ℵ_{2} = (〈 sup {^{1} Ψ_{D},^{2} Ψ_{D}}, inf {^{1} Θ_{D},^{2} Θ_{D}} 〉, 〈 sup {^{1} ρ_{D},^{2} ρ_{D}}, inf {^{1} σ_{D},^{2} σ_{D}} 〉)$ ;
$ℵ_{1} \cap ℵ_{2} = (〈 inf {^{1} Ψ_{D},^{2} Ψ_{D}}, sup {^{1} Θ_{D},^{2} Θ_{D}} 〉, 〈 inf {^{1} ρ_{D},^{2} ρ_{D}}, sup {^{1} σ_{D},^{2} σ_{D}} 〉)$ ;
$ℵ_{1} \oplus ℵ_{2} = (〈^{1} Ψ_{D} +^{2} Ψ_{D} -^{1} Ψ_{D}^{2} Ψ_{D},^{1} Θ_{D}^{2} Θ_{D} 〉, 〈^{1} ρ_{D} +^{2} ρ_{D} -^{1} ρ_{D}^{2} ρ_{D},^{1} σ_{D}^{2} σ_{D} 〉)$ ;
$ℵ_{1} \otimes ℵ_{2} = (〈^{1} Ψ_{D}^{2} Ψ_{D},^{1} Θ_{D} +^{2} Θ_{D} -^{1} Θ_{D}^{2} Θ_{D} 〉, 〈^{1} ρ_{D}^{2} ρ_{D},^{1} σ_{D} +^{2} σ_{D} -^{1} σ_{D}^{2} σ_{D} 〉)$ ;
$γ ℵ = (〈 1 - {(1 - Ψ_{D})}^{γ}, Θ_{D}^{γ} 〉, 〈 1 - {(1 - ρ_{D})}^{γ}, σ_{D}^{γ} 〉)$ ;
$ℵ^{γ} = (〈 Ψ_{D}^{γ}, 1 - {(1 - Θ_{D})}^{γ} 〉, 〈 ρ_{D}^{γ}, 1 - {(1 - σ_{D})}^{γ} 〉)$ .

3. Linguistic Linear Diophantine Fuzzy Sets

3.1. Construction of Linguistic Linear Diophantine Fuzzy Set

In some complex situations (especially for some qualitative arguments), it is difficult for one to give the degrees of membership, nonmembership, and reference/control parameters with real numbers. A practicable solution is to express them by linguistic arguments. Based on this idea, we can propose the LLDF concepts to express the LDF information based on linguistic variables. In this part, we propose an LLDFS, whose degrees of membership, nonmembership, and reference/control parameters are represented by linguistic variables.

In real life, we occasionally encounter some problems in which the LDF information cannot be expressed by real numbers, that is, the LDF information we collect is qualitative. To describe the LDF information based on linguistic variables, the concept of the LLDFS is defined as follows.

Definition 4.

Let

Ł = {ł_{0}, ł_{1}, \dots, ł_{g}}

be a linguistic term set with odd cardinality

q + 1

and

Ł_{[0, g]} = {ł_{κ} : ł_{0} \leq ł_{κ} \leq ł_{g}, κ \in [0, g]}

. Then, an LLDFS

D

in

H

is defined as

\begin{matrix} D = {(ℏ_{i}, 〈 ł_{Ψ_{D}} (ℏ_{i}), ł_{Θ_{D}} (ℏ_{i}) 〉, 〈 ł_{ρ_{D}} (ℏ_{i}), ł_{σ_{D}} (ℏ_{i}) 〉) : ℏ_{i} \in H} \end{matrix}

(2)

where

ł_{Ψ_{D}} (ℏ_{i}), ł_{Θ_{D}} (ℏ_{i}), ł_{ρ_{D}} (ℏ_{i}), ł_{σ_{D}} (ℏ_{i}) \in Ł_{[0, g]}

represent the linguistic-valued degrees of membership, nonmembership, and reference/control parameters of

ℏ_{i}

into

D

, respectively, with conditions for every

ℏ_{i} \in H

,

\begin{matrix} 0 \leq ρ_{D} (ℏ_{i}) + σ_{D} (ℏ_{i}) \leq g and 0 \leq ρ_{D} (ℏ_{i}) Ψ_{D} (ℏ_{i}) + σ_{D} (ℏ_{i}) Θ_{D} (ℏ_{i}) \leq g^{2} . \end{matrix}

where

0 \leq Ψ_{D} (ℏ_{i}), Θ_{D} (ℏ_{i}), ρ_{D} (ℏ_{i}), σ_{D} (ℏ_{i}) \leq g

. Moreover,

(〈 ł_{Ψ_{D}} (ℏ_{i}), ł_{Θ_{D}} (ℏ_{i}) 〉, 〈 ł_{ρ_{D}} (ℏ_{i}), ł_{σ_{D}}

(ℏ_{i}) 〉)

is called a linguistic linear Diophantine fuzzy number (LLDFN) and it is simply denoted as

N = (〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉)

. In addition, if

ł_{Ψ}, ł_{Θ}, ł_{ρ}, ł_{σ} \in Ł

, then

N

is said to be an original LLDFN; otherwise, it is said to be a virtual LLDFN.

In this paper, all LLDFNs defined on

Ł_{[0, g]}

are denoted by

℧_{[0, g]} = {(〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉) : ł_{Ψ}, ł_{Θ}, ł_{ρ}, ł_{σ} \in Ł_{[0, g]}}

and the set of all LLDFSs in

H

for

Ł_{[0, g]}

is denoted by

℧_{[0, g]}^{H}

.

Example 4.

Let

H = {ℏ_{1}, ℏ_{2}, ℏ_{3}, ℏ_{4}}

be a set of washing machines. We can easily categorize these washing machines according to the physical properties of the machine equipment considering the reference parameters: long life and short life (not long life). In this evaluation, linguistic values are used instead of exact values, and the linguistic term set is

\begin{matrix} Ł = \{\begin{matrix} ł_{0} = A b s o l u t e l y L o w (A L), ł_{1} = V e r y L o w (V L), ł_{2} = L o w (L), \\ ł_{3} = F a i r l y L o w (F L), ł_{4} = M e d i u m (M), ł_{5} = F a i r l y H i g h (F H), \\ ł_{6} = H i g h (H), ł_{7} = V e r y H i g h (V H), ł_{8} = A b s o l u t e l y H i g h (A H) \end{matrix}\} . \end{matrix}

Then, we can obtain the following LLDFS in

H

:

\begin{matrix} D = \{\begin{matrix} (ℏ_{1}, 〈 ł_{3}, ł_{7} 〉, 〈 ł_{5}, ł_{2} 〉), (ℏ_{2}, 〈 ł_{4}, ł_{4} 〉, 〈 ł_{3}, ł_{5} 〉), (ℏ_{3}, 〈 ł_{7}, ł_{6} 〉, 〈 ł_{1}, ł_{6} 〉), (ℏ_{4}, 〈 ł_{0}, ł_{2} 〉, 〈 ł_{3}, ł_{3} 〉) \end{matrix}\} . \end{matrix}

Theorem 1.

The space of LLDFS is larger than the space of LIFS, LPyFS, and Lq-ROFS.

Proof.

Each of LIFN, PyFN and Lq-ROFN is also an LLDFN. Let

N = (〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉)

be an LLDFN with the conditions

0 \leq ρ + σ \leq g

and

0 \leq ρ Ψ + σ Θ \leq g^{2}

, where

ρ, Ψ, σ, Θ \in [0, g]

. It is obvious that by the arbitrary choice of reference parameters, the above inequality holds for every LIFN, LPyFN, and Lq-ROFN.

Conversely, the LIFN, PyFN, and Lq-ROFN may not necessarily be an LLDFN with the given set of reference/control parameters. For instance, if we assume

ł_{4}, ł_{2} \in Ł_{[0, 4]}

, then we have

4^{q} + 2^{q} ≰ 4^{q}

for

q \geq 1

(note that Lin et al. (2020) proved that an Lq-ROFN is also LIFN (Chen et al., 2015) and PyFN (Garg, 2018b) for

q = 1

and

q = 2

, respectively). However, by the arbitrary choice of reference/control parameters

ł_{ρ}, ł_{σ} \in Ł_{[0, 4]}

where

0 \leq ρ + σ \leq 4

, we have

4 ρ + 2 σ \leq 4^{2}

, e.g., for

〈 ł_{ρ}, ł_{σ} 〉 = 〈 ł_{2}, ł_{2} 〉

.

Consequently, the above cases apply to every element (LLDFN) in LLDFS. Therefore, we successfully establish that the space of LDFSs is larger than the space of LIFS, LPyFS, and Lq-ROFS. □

To illustrate Theorem 1, we present a graphical representation of LLDFS as in Figure 3. This figure shows the graphical comparison of LLDFNs with some existing fuzzy numbers.

3.2. Operational Laws for Linguistic Linear Diophantine Fuzzy Sets

In this part, we discuss some operational laws on LLDFNs which are also applicable for LLDFSs.

Definition 5.

Let

N = (〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉)

,

N_{1} = (〈 ł_{Ψ_{1}}, ł_{Θ_{1}} 〉, 〈 ł_{ρ_{1}}, ł_{σ_{1}} 〉)

and

N_{2} = (〈 ł_{Ψ_{2}}, ł_{Θ_{2}} 〉, 〈 ł_{ρ_{2}}, ł_{σ_{2}} 〉)

be three LLDFNs, then

(a): $N^{c} = (〈 ł_{Θ}, ł_{Ψ} 〉, 〈 ł_{σ}, ł_{ρ} 〉);$
(b): $\begin{matrix} N_{1} \cap N_{2} & = & (〈 min {ł_{Ψ_{1}}, ł_{Ψ_{2}}}, max {ł_{Θ_{1}}, ł_{Θ_{2}}} 〉, 〈 min {ł_{ρ_{1}}, ł_{ρ_{2}}}, max {ł_{σ_{1}}, ł_{σ_{2}}} 〉) \\ = & (〈 ł_{min {Ψ_{1}, Ψ_{2}}}, ł_{max {Θ_{1}, Θ_{2}}} 〉, 〈 ł_{min {ρ_{1}, ρ_{2}}}, ł_{max {σ_{1}, σ_{2}}} 〉); \end{matrix}$
(c): $\begin{matrix} N_{1} \cup N_{2} & = & (〈 max {ł_{Ψ_{1}}, ł_{Ψ_{2}}}, min {ł_{Θ_{1}}, ł_{Θ_{2}}} 〉, 〈 max {ł_{ρ_{1}}, ł_{ρ_{2}}}, min {ł_{σ_{1}}, ł_{σ_{2}}} 〉) \\ = & (〈 ł_{max {Ψ_{1}, Ψ_{2}}}, ł_{min {Θ_{1}, Θ_{2}}} 〉, 〈 ł_{max {ρ_{1}, ρ_{2}}}, ł_{min {σ_{1}, σ_{2}}} 〉); \end{matrix}$
(d): $N_{1} \leq N_{2}$ if $ł_{Ψ_{1}} \leq ł_{Ψ_{2}}$ , $ł_{Θ_{1}} \geq ł_{Θ_{2}}$ , $ł_{ρ_{1}} \leq ł_{ρ_{2}}$ and $ł_{σ_{1}} \geq ł_{σ_{2}}$ ;
(e): $N_{1} = N_{2}$ if $ł_{Ψ_{1}} = ł_{Ψ_{2}}$ , $ł_{Θ_{1}} = ł_{Θ_{2}}$ , $ł_{ρ_{1}} = ł_{ρ_{2}}$ and $ł_{σ_{1}} = ł_{σ_{1}}$ .

Example 5.

Let

N_{1} = (〈 ł_{3}, ł_{6} 〉, 〈 ł_{4}, ł_{2} 〉)

,

N_{2} = (〈 ł_{4}, ł_{4} 〉, 〈 ł_{3}, ł_{0} 〉)

, and

N_{3} = (〈 ł_{5}, ł_{1} 〉, 〈 ł_{5}, ł_{0} 〉)

be three LLDFNs defined on

Ł_{[0, 6]}

, then

1.: $N_{1}^{c} = (〈 ł_{6}, ł_{3} 〉, 〈 ł_{2}, ł_{4} 〉)$ ;
2.: $N_{1} \cap N_{2} = (〈 ł_{3}, ł_{6} 〉, 〈 ł_{3}, ł_{2} 〉)$ ;
3.: $N_{1} \cup N_{2} = (〈 ł_{4}, ł_{4} 〉, 〈 ł_{4}, ł_{0} 〉)$ ;
4.: $N_{2} \leq N_{3}$ since $ł_{4} \leq ł_{5}$ , $ł_{4} \geq ł_{1}$ , $ł_{3} \leq ł_{5}$ and $ł_{0} \geq ł_{0}$ .

Theorem 2.

For the LLDFNs

N

,

N_{1}

, and

N_{2}

, the numbers

N^{c}

,

N_{1} \cap N_{2}

, and

N_{1} \cup N_{2}

are also LLDFNs.

Proof.

Now, we prove that the intersection of LLDFNs

N_{1}

and

N_{2}

, i.e.,

N_{1} \cap N_{2}

, is an LLDFN. Others can be proved by using similar techniques.

Let

N_{1} = (〈 ł_{Ψ_{1}}, ł_{Θ_{1}} 〉, 〈 ł_{ρ_{1}}, ł_{σ_{1}} 〉)

and

N_{2} = (〈 ł_{Ψ_{2}}, ł_{Θ_{2}} 〉, 〈 ł_{ρ_{2}}, ł_{σ_{2}} 〉)

be two LLDFNs defined on

Ł_{[0, g]}

. Then, we have

0 \leq ρ_{1} + σ_{1} \leq g

,

0 \leq ρ_{1} Ψ_{1} + σ_{1} Θ_{1} \leq g^{2}

and

0 \leq ρ_{2} + σ_{2} \leq g

,

0 \leq ρ_{2} Ψ_{2} + σ_{2} Θ_{2} \leq g^{2}

. By Definition 5, we can write the intersection of

N_{1}

and

N_{2}

as

N_{1} \cap N_{2} = (〈 ł_{min {Ψ_{1}, Ψ_{2}}}, ł_{max {Θ_{1}, Θ_{2}}} 〉, 〈 ł_{min {ρ_{1}, ρ_{2}}}, ł_{max {σ_{1}, σ_{2}}} 〉)

. Since

0 \leq Ψ_{1}, Θ_{1}, ρ_{1}, σ_{1}, Ψ_{2}, Θ_{2}, ρ_{2}, σ_{2} \leq g

, we can say that

0 \leq min {Ψ_{1}, Ψ_{2}}, max {Θ_{1}, Θ_{2}}, min {ρ_{1}, ρ_{2}}, max {σ_{1}, σ_{2}} \leq g

. Now, we must demonstrate that

0 \leq min {ρ_{1}, ρ_{2}} + max {σ_{1}, σ_{2}} \leq g

and

0 \leq min {ρ_{1}, ρ_{2}} min {Ψ_{1}, Ψ_{2}} + max {σ_{1}, σ_{2}} max {Θ_{1}, Θ_{2}} \leq g^{2}

. Let us examine four different cases for

0 \leq min {ρ_{1}, ρ_{2}} + max {σ_{1}, σ_{2}} \leq g

.

Case 1. Assume that

min {ρ_{1}, ρ_{2}} = ρ_{1}

and

max {σ_{1}, σ_{2}} = σ_{1}

. Then, it is quite obvious since

0 \leq ρ_{1} + σ_{1} \leq g

.

Case 2. For

min {ρ_{1}, ρ_{2}} = ρ_{2}

and

max {σ_{1}, σ_{2}} = σ_{2}

, the assertion seems evident (similar to Case 1).

Case 3. Suppose that

min {ρ_{1}, ρ_{2}} = ρ_{1}

and

max {σ_{1}, σ_{2}} = σ_{2}

. For

min {ρ_{1}, ρ_{2}} = ρ_{1} \Rightarrow ρ_{1} \leq ρ_{2}

and

ρ_{2} + σ_{2} \leq g \Rightarrow ρ_{2} \leq g - σ_{2}

, we obtain

ρ_{1} + σ_{2} \leq ρ_{2} + σ_{2} \leq g - σ_{2} + σ_{2} = g

. This result verifies the assertion.

Case 4. For

min {ρ_{1}, ρ_{2}} = ρ_{2}

and

max {σ_{1}, σ_{2}} = σ_{1}

, it can be demonstrated similar to Case 3.

As a result of four cases, we have

\begin{matrix} 0 \leq min {ρ_{1}, ρ_{2}} + max {σ_{1}, σ_{2}} \leq g \end{matrix}

(3)

Since

0 \leq min {Ψ_{1}, Ψ_{2}}, max {Θ_{1}, Θ_{2}} \leq g

, we obtain that

\begin{matrix} 0 \leq min {ρ_{1}, ρ_{2}} min {Ψ_{1}, Ψ_{2}} + max {σ_{1}, σ_{2}} max {Θ_{1}, Θ_{2}} \leq g \end{matrix}

(4)

By Equations (3) and (4), we conclude that

N_{1} \cap N_{2}

is an LLDFN defined on

Ł_{[0, g]}

. □

Proposition 1.

Let

N, N_{1}, N_{2} \in ℧_{[0, g]}

, then we have

(i): $N_{1} \cap N_{2} = N_{2} \cap N_{1}$ ;
(ii): $N_{1} \cap (N_{2} \cap N_{3}) = (N_{1} \cap N_{2}) \cap N_{3}$ ;
(iii): $N_{1} \cup N_{2} = N_{2} \cup N_{1}$ ;
(iv): $N_{1} \cup (N_{2} \cup N_{3}) = (N_{1} \cup N_{2}) \cup N_{3}$ ;
(v): $N_{1} \cap (N_{2} \cup N_{3}) = (N_{1} \cap N_{2}) \cup (N_{1} \cap N_{3})$ ;
(vi): $N_{1} \cup (N_{2} \cap N_{3}) = (N_{1} \cup N_{2}) \cap (N_{1} \cup N_{3})$ ;
(vii): ${(N_{1} \cap N_{2})}^{c} = N_{1}^{c} \cup N_{2}^{c}$ ;
(viii): ${(N_{1} \cup N_{2})}^{c} = N_{1}^{c} \cap N_{2}^{c}$ .

Proof.

They are easy to see from Definition 5, so they are omitted. □

Definition 6.

Let

N = (〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉)

,

N_{1} = (〈 ł_{Ψ_{1}}, ł_{Θ_{1}} 〉, 〈 ł_{ρ_{1}}, ł_{σ_{1}} 〉)

and

N_{2} = (〈 ł_{Ψ_{2}}, ł_{Θ_{2}} 〉, 〈 ł_{ρ_{2}}, ł_{σ_{2}} 〉)

be three LLDFNs and

ξ > 0

be any real number. Then,

(a): $\begin{matrix} N_{1} \oplus N_{2} & = & (〈 ł_{g (\frac{Ψ_{1}}{g} + \frac{Ψ_{2}}{g} - \frac{Ψ_{1} Ψ_{2}}{g^{2}})}, ł_{g (\frac{Θ_{1} Θ_{2}}{g^{2}})} 〉, 〈 ł_{g (\frac{ρ_{1}}{g} + \frac{ρ_{2}}{g} - \frac{ρ_{1} ρ_{2}}{g^{2}})}, ł_{g (\frac{σ_{1} σ_{2}}{g^{2}})} 〉) \\ = & (〈 ł_{Ψ_{1} + Ψ_{2} - \frac{Ψ_{1} Ψ_{2}}{g}}, ł_{\frac{Θ_{1} Θ_{2}}{g}} 〉, 〈 ł_{ρ_{1} + ρ_{2} - \frac{ρ_{1} ρ_{2}}{g}}, ł_{\frac{σ_{1} σ_{2}}{g}} 〉); \end{matrix}$
(b): $\begin{matrix} N_{1} \otimes N_{2} & = & (〈 ł_{g (\frac{Ψ_{1} Ψ_{2}}{g^{2}})}, ł_{g (\frac{Θ_{1}}{g} + \frac{Θ_{2}}{g} - \frac{Θ_{1} Θ_{2}}{g^{2}})} 〉, 〈 ł_{g (\frac{ρ_{1} ρ_{2}}{g^{2}})}, ł_{g (\frac{σ_{1}}{g} + \frac{σ_{2}}{g} - \frac{σ_{1} σ_{2}}{g^{2}})} 〉) \\ = & (〈 ł_{\frac{Ψ_{1} Ψ_{2}}{g}}, ł_{Θ_{1} + Θ_{2} - \frac{Θ_{1} Θ_{2}}{g}} 〉, 〈 ł_{\frac{ρ_{1} ρ_{2}}{g}}, ł_{σ_{1} + σ_{2} - \frac{σ_{1} σ_{2}}{g}} 〉); \end{matrix}$
(c): $\begin{matrix} ξ N & = & (〈 ł_{g - g {(1 - \frac{Ψ}{g})}^{ξ}}, ł_{g {(\frac{Θ}{g})}^{ξ}} 〉, 〈 ł_{g - g {(1 - \frac{ρ}{g})}^{ξ}}, ł_{g {(\frac{σ}{g})}^{ξ}} 〉) \\ = & (〈 ł_{g (1 - {(1 - \frac{Ψ}{g})}^{ξ})}, ł_{g {(\frac{Θ}{g})}^{ξ}} 〉, 〈 ł_{g (1 - {(1 - \frac{ρ}{g})}^{ξ})}, ł_{g {(\frac{σ}{g})}^{ξ}} 〉); \end{matrix}$
(d): $\begin{matrix} N^{ξ} & = & (〈 ł_{g {(\frac{Ψ}{g})}^{ξ}}, ł_{g - g {(1 - \frac{Θ}{g})}^{ξ}} 〉, 〈 ł_{g {(\frac{ρ}{g})}^{ξ}}, ł_{g - g {(1 - \frac{σ}{g})}^{ξ}} 〉) \\ = & (〈 ł_{g {(\frac{Ψ}{g})}^{ξ}}, ł_{g (1 - {(1 - \frac{Θ}{g})}^{ξ})} 〉, 〈 ł_{g {(\frac{ρ}{g})}^{ξ}}, ł_{g (1 - {(1 - \frac{σ}{g})}^{ξ})} 〉) . \end{matrix}$

Example 6.

Let us consider the LLDFNs

N_{1}

,

N_{2}

and

N_{3}

defined on

Ł_{[0, 6]}

in Example 5 and

ξ = 0.3

, then we obtain

(1): $N_{1} \oplus N_{2} = (〈 ł_{5}, ł_{4} 〉, 〈 ł_{5}, ł_{0} 〉)$ ;
(2): $N_{1} \otimes N_{2} = (〈 ł_{2}, ł_{6} 〉, 〈 ł_{2}, ł_{2} 〉)$ ;
(3): $ξ N_{3} = (〈 ł_{2.4948}, ł_{3.5052} 〉, 〈 ł_{2.4948}, ł_{0} 〉)$ ;
(4): $N_{3}^{ξ} = (〈 ł_{5.6808}, ł_{0.3192} 〉, 〈 ł_{5.6808}, ł_{0} 〉)$ .

Theorem 3.

For the LLDFNs

N

,

N_{1}

, and

N_{2}

with

ξ > 0

, the numbers

N_{1} \oplus N_{2}

N_{1} \otimes N_{2}

,

ξ N

, and

N^{ξ}

are also LLDFNs.

Proof.

These can be proved by proceeding with similar techniques used in the proof of Theorem 2. □

Proposition 2.

Let

N, N_{1}, N_{2} \in ℧_{[0, g]}

and

ξ, ξ_{1}, ξ_{2} > 0

be any real numbers, then we have

(i): $N_{1} \oplus N_{2} = N_{2} \oplus N_{1}$ ;
(ii): $N_{1} \oplus N_{2} \oplus N_{3} = N_{1} \oplus N_{3} \oplus N_{2}$ ;
(iii): $ξ (N_{1} \oplus N_{2}) = ξ N_{1} \oplus ξ N_{2}$ ;
(iv): $ξ_{1} N \oplus ξ_{2} N = (ξ_{1} + ξ_{2}) N$ ;
(v): $N_{1} \otimes N_{2} = N_{2} \otimes N_{1}$ ;
(vi): $N_{1} \otimes N_{2} \otimes N_{3} = N_{1} \otimes N_{3} \otimes N_{2}$ ;
(vii): ${(N_{1} \otimes N_{2})}^{ξ} = N_{1}^{ξ} \otimes N_{2}^{ξ}$ ;
(viii): $N^{ξ_{1}} \otimes N^{ξ_{2}} = N^{ξ_{1} + ξ_{2}}$ ;
(ix): ${(N_{1} \oplus N_{2})}^{c} = N_{1}^{c} \otimes N_{2}^{c}$ ;
(x): ${(N_{1} \otimes N_{2})}^{c} = N_{1}^{c} \oplus N_{2}^{c}$ ;
(xi): $ξ (N^{c}) = {(N^{ξ})}^{c}$ ;
(xii): ${(N^{c})}^{ξ} = {(ξ N)}^{c}$ .

Proof.

It can be easily demonstrated using the equations in Definition 6, therefore it is omitted. □

Proposition 3.

Let

N_{1}, N_{2}, N_{3} \in ℧_{[0, g]}

, then we have

(i): $(N_{1} \cap N_{2}) \oplus (N_{1} \cup N_{2}) = N_{1} \oplus N_{2}$ ;
(ii): $(N_{1} \cap N_{2}) \otimes (N_{1} \cup N_{2}) = N_{1} \oplus N_{2}$ ;
(iii): $N_{1} \oplus (N_{2} \cap N_{3}) = (N_{1} \oplus N_{2}) \cap (N_{1} \oplus N_{3})$ ;
(iv): $N_{1} \oplus (N_{2} \cup N_{3}) = (N_{1} \oplus N_{2}) \cup (N_{1} \oplus N_{3})$ ;
(v): $N_{1} \otimes (N_{2} \cap N_{3}) = (N_{1} \otimes N_{2}) \cap (N_{1} \otimes N_{3})$ ;
(vi): $N_{1} \otimes (N_{2} \cup N_{3}) = (N_{1} \otimes N_{2}) \cup (N_{1} \otimes N_{3})$ .

Proof.

We will prove the assertion (i), the proofs of others are similar.

(i) Since

\begin{matrix} N_{1} \cap N_{2} = (〈 ł_{min {Ψ_{1}, Ψ_{2}}}, ł_{max {Θ_{1}, Θ_{2}}} 〉, 〈 ł_{min {ρ_{1}, ρ_{2}}}, ł_{max {σ_{1}, σ_{2}}} 〉) \end{matrix}

and

\begin{matrix} N_{1} \cup N_{2} = (〈 ł_{max {Ψ_{1}, Ψ_{2}}}, ł_{min {Θ_{1}, Θ_{2}}} 〉, 〈 ł_{max {ρ_{1}, ρ_{2}}}, ł_{min {σ_{1}, σ_{2}}} 〉) \end{matrix}

we obtain

(N_{1} \cap N_{2}) \oplus (N_{1} \cup N_{2})

\begin{matrix} = & (\begin{matrix} 〈 ł_{g (\frac{min {Ψ_{1}, Ψ_{2}}}{g} + \frac{max {Ψ_{1}, Ψ_{2}}}{g}) - \frac{min {Ψ_{1}, Ψ_{2}} max {Ψ_{1}, Ψ_{2}}}{g^{2}}}, ł_{g (\frac{max {Θ_{1}, Θ_{2}}}{g} \frac{min {Θ_{1}, Θ_{2}}}{g})} 〉, \\ 〈 ł_{g (\frac{min {ρ_{1}, ρ_{2}}}{g} + \frac{max {ρ_{1}, ρ_{2}}}{g}) - \frac{min {ρ_{1}, ρ_{2}} max {ρ_{1}, ρ_{2}}}{g^{2}}}, ł_{g (\frac{max {σ_{1}, σ_{2}}}{g} \frac{min {σ_{1}, σ_{2}}}{g})} 〉 \end{matrix}) \\ = & (〈 ł_{g (\frac{Ψ_{1}}{g} + \frac{Ψ_{2}}{g} - \frac{Ψ_{1} Ψ_{2}}{g^{2}})}, ł_{g (\frac{Θ_{1} Θ_{2}}{g^{2}})} 〉, 〈 ł_{g (\frac{ρ_{1}}{g} + \frac{ρ_{2}}{g} - \frac{ρ_{1} ρ_{2}}{g^{2}})}, ł_{g (\frac{σ_{1} σ_{2}}{g^{2}})} 〉) \\ = & (〈 ł_{Ψ_{1} + Ψ_{2} - \frac{Ψ_{1} Ψ_{2}}{g}}, ł_{\frac{Θ_{1} Θ_{2}}{g}} 〉, 〈 ł_{ρ_{1} + ρ_{2} - \frac{ρ_{1} ρ_{2}}{g}}, ł_{\frac{σ_{1} σ_{2}}{g}} 〉) \\ = & N_{1} \oplus N_{2} . \end{matrix}

□

Now, we describe the score function and accuracy function to compare the LLDFNs.

Definition 7.

Let

N = (〈 ł_{Ψ}, ł_{Θ} 〉, 〈 ł_{ρ}, ł_{σ} 〉) \in ℧_{[0, g]}

, then

(a): The score function on $N$ can be described by the mapping $ℑ^{S} : ℧_{[0, g]} \to [0, 1]$ and given by

$\begin{matrix} ℑ_{N}^{S} = ℑ^{S} (N) = \frac{1}{4 g} (2 g + (Ψ - Θ) + (ρ - σ)) \end{matrix}$

(5)
(b): The accuracy function on $N$ can be described by the mapping $ℑ^{A} : ℧_{[0, g]} \to [0, 1]$ and given by

$\begin{matrix} ℑ_{N}^{A} = ℑ^{A} (N) = \frac{1}{2 g} ((\frac{Ψ + Θ}{2}) + (ρ + σ)) \end{matrix}$

(6)

Let

N_{1},

N_{2} \in ℧_{[0, g]}

, then by using the score function and accuracy function we give the comparative relations between these LLDFNs as follows:

1.

If

ℑ_{N_{1}}^{S} < ℑ_{N_{2}}^{S}

then

N_{1} ≺ N_{2}

;

2.

If

ℑ_{N_{1}}^{S} > ℑ_{N_{2}}^{S}

then

N_{1} ≻ N_{2}

;

3.

If

ℑ_{N_{1}}^{S} = ℑ_{N_{2}}^{S}

then

i.: If $ℑ_{N_{1}}^{A} < ℑ_{N_{2}}^{A}$ then $N_{1} ≺ N_{2}$ ;
ii.: If $ℑ_{N_{1}}^{A} > ℑ_{N_{2}}^{A}$ then $N_{1} ≻ N_{2}$ ;
iii.: If $ℑ_{N_{1}}^{A} = ℑ_{N_{2}}^{A}$ then $N_{1} \approx N_{2}$ .

For the comparison in the definition above, we can simplify it as a binary relation

⪯_{(ℑ^{S}, ℑ^{A})}

on

℧_{[0, g]}

given as

N_{1} ⪯_{(ℑ^{S}, ℑ^{A})} N_{2} \Leftrightarrow (ℑ_{N_{1}}^{S} < ℑ_{N_{2}}^{S}) \lor ((ℑ_{N_{1}}^{S} = ℑ_{N_{2}}^{S}) \land (ℑ_{N_{1}}^{A} \leq ℑ_{N_{2}}^{A}))

.

Example 7.

We consider the LLDFNs

N_{1}

and

N_{2}

defined on

Ł_{[0, 6]}

in Example 5. Then, we compute the score values of LLDFNs

N_{1}

and

N_{2}

as

ℑ_{N_{1}}^{S} = 0.4583

and

ℑ_{N_{2}}^{S} = 0.625

, so we have

N_{1} ≺ N_{2}

.Assume that

N_{3} = (〈 ł_{1}, ł_{4} 〉, 〈 ł_{2}, ł_{0} 〉) \in ℧_{[0, 6]}

, then we calculate

ℑ_{N_{3}}^{S} = 0.4583

. By using the score values of LLDFNs

N_{2}

and

N_{3}

, we have

N_{2} ≻ N_{3}

. However, the score values of LLDFNs

N_{1}

and

N_{3}

are equal. Then, we can calculate their accuracy values. As a result of the calculations, we obtain

ℑ_{N_{1}}^{A} = 0.875 > 0.375 = ℑ_{N_{3}}^{A}

and so

N_{1} ≻ N_{3}

.

3.3. Weighted Aggregation Operators for Linguistic Linear Diophantine Fuzzy Sets

In this part, we propose some weighted aggregation operators to fuse the LLDFSs/ LLDFNs, namely, LLDF weighted averaging aggregation operator and LLDF weighted averaging aggregation operator.

Throughout this part,

N_{k} = (〈 ł_{Ψ_{k}}, ł_{Θ_{k}} 〉, 〈 ł_{ρ_{k}}, ł_{σ_{k}} 〉) \in ℧_{[0, g]}

(k = 1, 2, \dots, t)

is a collection of LLDFNs and

ϖ = {(ϖ_{1}, ϖ_{2}, \dots, ϖ_{t})}^{T}

is the weight vector with

\sum_{k = 1}^{t} ϖ_{k} = 1

for

ϖ_{k} \in (0, 1]

(k = 1, 2, \dots, t)

.

Definition 8.

The LLDF weighted averaging aggregation (LLDFWAA) operator is a mapping

L L D F W A A_{ϖ} : ℧_{[0, g]}^{t} \to ℧_{[0, g]}

such that

\begin{matrix} L L D F W A A_{ϖ} (N_{1}, N_{2}, \dots, N_{t}) = ⨁_{k = 1}^{t} ϖ_{k} N_{k} = ϖ_{1} N_{1} \oplus ϖ_{2} N_{2} \oplus \dots \oplus ϖ_{t} N_{t} \end{matrix}

(7)

Theorem 4.

The aggregated operator of all LLDFNs

N_{k} = (〈 ł_{Ψ_{k}}, ł_{Θ_{k}} 〉, 〈 ł_{ρ_{k}}, ł_{σ_{k}} 〉)

(k = 1, 2, \dots, t)

by using LLDFWAA operator is still an LLDFN, and

L L D F W A A_{ϖ} (N_{1}, N_{2}, \dots, N_{t}) = ⨁_{k = 1}^{t} ϖ_{k} N_{k}

\begin{matrix} = (〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}

(8)

Proof.

Let

N_{k} = (〈 ł_{Ψ_{k}}, ł_{Θ_{k}} 〉, 〈 ł_{ρ_{k}}, ł_{σ_{k}} 〉)

(k = 1, 2, \dots, t)

be a collection of LLDFNs and

ϖ = {(ϖ_{1}, ϖ_{2}, \dots, ϖ_{t})}^{T}

be the weight vector.

(i) This part can be demonstrated by using the mathematical induction technique. For

k = 2

, since

\begin{matrix} ϖ_{1} N_{1} & = & (〈 ł_{g - g {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}}}, ł_{g {(\frac{Θ_{1}}{g})}^{ϖ_{1}}} 〉, 〈 ł_{g - g {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}}}, ł_{g {(\frac{σ_{1}}{g})}^{ϖ_{1}}} 〉) \end{matrix}

and

\begin{matrix} ϖ_{2} N_{2} & = & (〈 ł_{g - g {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}}}, ł_{g {(\frac{Θ_{2}}{g})}^{ϖ_{2}}} 〉, 〈 ł_{g - g {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}}}, ł_{g {(\frac{σ_{2}}{g})}^{ϖ_{2}}} 〉) \end{matrix}

By Definition 6 (a), there is the following result:

ϖ_{1} N_{1} \oplus ϖ_{2} N_{2}

\begin{matrix} = & (\begin{matrix} 〈 ł_{g (\frac{g - g {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}}}{g} + \frac{g - g {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}}}{g} - \frac{(g - g {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}}) (g - g {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}})}{g^{2}})}, ł_{g (\frac{g {(\frac{Θ_{1}}{g})}^{ϖ_{1}} g {(\frac{Θ_{2}}{g})}^{ϖ_{2}}}{g^{2}})} 〉, \\ 〈 ł_{g (\frac{g - g {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}}}{g} + \frac{g - g {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}}}{g} - \frac{(g - g {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}}) (g - g {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}})}{g^{2}})}, ł_{g (\frac{g {(\frac{σ_{1}}{g})}^{ϖ_{1}} g {(\frac{σ_{2}}{g})}^{ϖ_{2}}}{g^{2}})} 〉 \end{matrix}) \\ = & (\begin{matrix} 〈 ł_{g (1 - {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}} + 1 - {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}} - (1 - {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}} - {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}} + {(1 - \frac{Ψ_{1}}{g})}^{ϖ_{1}} {(1 - \frac{Ψ_{2}}{g})}^{ϖ_{2}}))}, ł_{g ({(\frac{Θ_{1}}{g})}^{ϖ_{1}} {(\frac{Θ_{2}}{g})}^{ϖ_{2}})} 〉, \\ 〈 ł_{g (1 - {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}} + 1 - {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}} - (1 - {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}} - {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}} + {(1 - \frac{ρ_{1}}{g})}^{ϖ_{1}} {(1 - \frac{ρ_{2}}{g})}^{ϖ_{2}}))}, ł_{g ({(\frac{σ_{1}}{g})}^{ϖ_{1}} {(\frac{σ_{2}}{g})}^{ϖ_{2}})} 〉 \end{matrix}) \\ = & (〈ł_{g - g \prod_{k = 1}^{2} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{2} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{2} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{2} {(\frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \\ = & L L D F W A A_{ϖ} (N_{1}, N_{2}) \end{matrix}

(9)

Suppose that the Equation (7) is verified for

k = r

, i.e.,

L L D F W A A_{ϖ} (N_{1}, N_{2}, \dots, N_{r}) = ⨁_{k = 1}^{r} ϖ_{k} N_{k}

\begin{matrix} = (〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r} {(\frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}

(10)

Then, we will prove that Equation (7) is verified for

k = r + 1

. By applying Equations (9) and (10), we calculate

\begin{matrix} L L D F W A A_{ϖ} (N_{1}, N_{2}, \dots, N_{r + 1}) = \prod_{k = 1}^{r} ϖ_{k} N_{k} \oplus ϖ_{k + 1} N_{k + 1} \\ = (〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r} {(\frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \\ \oplus (〈ł_{g - g {(1 - \frac{Ψ_{r + 1}}{g})}^{ϖ_{r + 1}}}, ł_{g {(\frac{Θ_{r + 1}}{g})}^{ϖ_{r + 1}}}〉, 〈ł_{g - g {(1 - \frac{ρ_{r + 1}}{g})}^{ϖ_{r + 1}}}, ł_{g {(\frac{σ_{r + 1}}{g})}^{ϖ_{r + 1}}}〉) \\ = (\begin{matrix} 〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}} + g - g {(1 - \frac{Ψ_{r + 1}}{g})}^{ϖ_{r + 1}} - \frac{(g - g \prod_{k = 1}^{r} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}) (g - g {(1 - \frac{Ψ_{r + 1}}{g})}^{ϖ_{r + 1}})}{g}}, ł_{\frac{(g \prod_{k = 1}^{r} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}) (g {(\frac{Θ_{r + 1}}{g})}^{ϖ_{r + 1}})}{g}}〉, \\ 〈ł_{g - g \prod_{k = 1}^{r} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}} + g - g {(1 - \frac{ρ_{r + 1}}{g})}^{ϖ_{r + 1}} - \frac{(g - g \prod_{k = 1}^{r} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}) (g - g {(1 - \frac{ρ_{r + 1}}{g})}^{ϖ_{r + 1}})}{g}}, ł_{\frac{(g \prod_{k = 1}^{r} {(\frac{σ_{k}}{g})}^{ϖ_{k}}) (g {(\frac{σ_{r + 1}}{g})}^{ϖ_{r + 1}})}{g}}〉 \end{matrix}) \\ = (〈ł_{g - g \prod_{k = 1}^{r + 1} {(1 - \frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r + 1} {(\frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{r + 1} {(1 - \frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{r + 1} {(\frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}

Thereby, the proof is completed.

(ii) It is similar to the proof of (i), so we omitted it here. □

Definition 9.

The LLDF weighted geometric aggregation (LLDFWGA) operator is a mapping

L L D F W G A_{ϖ} : ℧_{[0, g]}^{t} \to ℧_{[0, g]}

such that

\begin{matrix} L L D F W G A_{ϖ} (N_{1}, N_{2}, \dots, N_{t}) = ⨂_{k = 1}^{t} N_{k}^{ϖ_{k}} = N_{1}^{ϖ_{1}} \otimes N_{2}^{ϖ_{2}} \otimes \dots \otimes N_{t}^{ϖ_{t}} \end{matrix}

(11)

Theorem 5.

The aggregated operator of all LLDFNs

N_{k} = (〈 ł_{Ψ_{k}}, ł_{Θ_{k}} 〉, 〈 ł_{ρ_{k}}, ł_{σ_{k}} 〉)

(k = 1, 2, \dots, t)

by using LLDFWGA operator is still an LLDFN, and

L L D F W G A_{ϖ} (N_{1}, N_{2}, \dots, N_{t}) = ⨂_{k = 1}^{t} N_{k}^{ϖ_{k}}

\begin{matrix} = (〈ł_{g \prod_{k = 1}^{t} {(\frac{Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g \prod_{k = 1}^{t} {(\frac{ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}

(12)

Proof.

It can be proved similar to the proof of Theorem 5, therefore we omit it here. □

Example 8.

We consider the LLDFNs

N_{1}

,

N_{2}

and

N_{3}

defined on

Ł_{[0, 6]}

in Example 5. In addition, we take the weights

ϖ_{1} = 0.2

,

ϖ_{2} = 0.5

, and

ϖ_{3} = 0.3

. Then, we obtain

\begin{matrix} L L D F W A A_{ϖ} (N_{1}, N_{2}, N_{3}) & = & (〈 ł_{6 - 6 \prod_{k = 1}^{3} {(1 - \frac{Ψ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{3} {(\frac{Θ_{k}}{6})}^{ϖ_{k}}} 〉, 〈 ł_{6 - 6 \prod_{k = 1}^{3} {(1 - \frac{ρ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{3} {(\frac{σ_{k}}{6})}^{ϖ_{k}}} 〉) \\ = & (〈 ł_{3.5093}, ł_{2.8611} 〉, 〈 ł_{4.0108}, ł_{0} 〉) \end{matrix}

and

\begin{matrix} L L D F W G A_{ϖ} (N_{1}, N_{2}, N_{3}) & = & (〈 ł_{6 \prod_{k = 1}^{3} {(\frac{Ψ_{k}}{6})}^{ϖ_{k}}}, ł_{6 - 6 \prod_{k = 1}^{3} {(1 - \frac{Θ_{k}}{6})}^{ϖ_{k}}} 〉, 〈 ł_{6 \prod_{k = 1}^{3} {(\frac{ρ_{k}}{6})}^{ϖ_{k}}}, ł_{6 - 6 \prod_{k = 1}^{3} {(1 - \frac{σ_{k}}{6})}^{ϖ_{k}}} 〉) \\ = & (〈 ł_{3.8356}, ł_{6} 〉, 〈 ł_{3.6215}, ł_{0.6876} 〉) \end{matrix}

4. Some Distance Measures for Linguistic Linear Diophantine Fuzzy Numbers

The distance measure is an objective score that summarizes the relative difference between two objects/points. In this section, we propose some typical Minkowski-type approaches measuring the distance between two LLDFNs.

Definition 10.

Let

N_{1} = (〈 ł_{Ψ_{1}}, ł_{Θ_{1}} 〉, 〈 ł_{ρ_{1}}, ł_{σ_{1}} 〉), N_{2} = (〈 ł_{Ψ_{2}}, ł_{Θ_{2}} 〉, 〈 ł_{ρ_{2}}, ł_{σ_{2}} 〉) \in ℧_{[0, g]}

Then, the Minkowski distance measure between two LLDFNs

N_{1}

and

N_{2}

is defined as

\begin{matrix} Δ_{℘}^{d i s t} (N_{1}, N_{2}) = {(\frac{| Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} \end{matrix}

(13)

where

℘ \geq 1

.

When $℘ = 1$ , it is considered as the Hamming distance measure between $N_{1}$ and $N_{2}$ , that is,

$\begin{matrix} Δ_{1}^{d i s t} (N_{1}, N_{2}) = \frac{| Ψ_{1} - Ψ_{2} | + | Θ_{1} - Θ_{2} | + | ρ_{1} - ρ_{2} | + | σ_{1} - σ_{2} |}{4} \end{matrix}$

(14)
When $℘ = 2$ , it is considered as the Euclidean distance measure between $N_{1}$ and $N_{2}$ , that is,

$\begin{matrix} Δ_{2}^{d i s t} (N_{1}, N_{2}) = \sqrt{\frac{| Ψ_{1} - Ψ_{2} |^{2} + | Θ_{1} - Θ_{2} |^{2} + | ρ_{1} - ρ_{2} |^{2} + {| σ_{1} - σ_{2} |}^{2}}{4}} \end{matrix}$

(15)
When $℘ = \infty$ , it is considered as the Chebyshev distance measure between $N_{1}$ and $N_{2}$ , that is,

$\begin{matrix} Δ_{\infty}^{d i s t} (N_{1}, N_{2}) = max {| Ψ_{1} - Ψ_{2} |, | Θ_{1} - Θ_{2} |, | ρ_{1} - ρ_{2} |, | σ_{1} - σ_{2} |} \end{matrix}$

(16)

Example 9.

We consider the LLDFNs

N_{1}

,

N_{2}

, and

N_{3}

defined on

Ł_{[0, 6]}

in Example 5, and we obtain the distance measures of

N_{1}

,

N_{2}

, and

N_{3}

for some ℘ as in Table 2.

Theorem 6.

Let

N_{1}, N_{2} \in ℧_{[0, g]}

. The distance

Δ_{℘}^{d i s t} (N_{1}, N_{2})

between LLDFNs

N_{1}

and

N_{2}

satisfies the following properties.

(i): $0 \leq Δ_{℘}^{d i s t} (N_{1}, N_{2}) \leq g$ .
(ii): $N_{1} = N_{2} \Leftrightarrow Δ_{℘}^{d i s t} (N_{1}, N_{2}) = 0$ .
(iii): $Δ_{℘}^{d i s t} (N_{1}, N_{2}) = Δ_{℘}^{d i s t} (N_{2}, N_{1})$ .
(iv): $Δ_{℘}^{d i s t} (N_{1}, N_{2}) = Δ_{℘}^{d i s t} (N_{1}^{c}, N_{2}^{c})$ .
(v): If $N_{1} \leq N_{2} \leq N_{3}$ for $N_{3} \in ℧_{[0, g]}$ then $Δ_{℘}^{d i s t} (N_{1}, N_{2}) \leq Δ_{℘}^{d i s t} (N_{1}, N_{3})$ and $Δ_{℘}^{d i s t} (N_{2}, N_{3}) \leq Δ_{℘}^{d i s t} (N_{1}, N_{3})$ .

Proof.

Let

N_{1} = (〈 ł_{Ψ_{1}}, ł_{Θ_{1}} 〉, 〈 ł_{ρ_{1}}, ł_{σ_{1}} 〉), N_{2} = (〈 ł_{Ψ_{2}}, ł_{Θ_{2}} 〉, 〈 ł_{ρ_{2}}, ł_{σ_{2}} 〉) \in ℧_{[0, g]}

.

(i): From Definition 4, we know that $0 \leq Ψ_{k}, Θ_{j}, ρ_{k}, σ_{k} g$ for $k = 1, 2$ . Therefore, we have $0 \leq | Ψ_{1} - Ψ_{2} | \leq g$ , $0 \leq | Θ_{1} - Θ_{2} | \leq g$ , $0 \leq | ρ_{1} - ρ_{2} | \leq g$ and $0 \leq | σ_{1} - σ_{2} | \leq g$ , and so

$\begin{matrix} 0 \leq | Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘} \leq 4 g^{p} \\ \Leftrightarrow 0 \leq {(\frac{| Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} \leq g \end{matrix}$

Thus, we deduce that $0 \leq Δ_{℘}^{d i s t} (N_{1}, N_{2}) \leq g$ .
(ii): ⇒: If $N_{1} = N_{2}$ then

$\begin{matrix} Δ_{℘}^{d i s t} (N_{1}, N_{1}) = {(\frac{| Ψ_{1} - Ψ_{1} |^{℘} + | Θ_{1} - Θ_{1} |^{℘} + | ρ_{1} - ρ_{1} |^{℘} + {| σ_{1} - σ_{1} |}^{℘}}{4})}^{\frac{1}{℘}} = 0 \end{matrix}$

$\Leftarrow :$ Suppose that $Δ_{℘}^{d i s t} (N_{1}, N_{2}) = 0$ . Then, by Definition 10, we can write

$\begin{matrix} Δ_{℘}^{d i s t} (N_{1}, N_{2}) = {(\frac{| Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} = 0 \end{matrix}$

and so

$\begin{matrix} | Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘} = 0 . \end{matrix}$

This implies that $Ψ_{1} = Ψ_{2}$ , $Θ_{1} = Θ_{2}$ , $ρ_{1} = ρ_{2}$ and $σ_{1} = σ_{2}$ . By considering Definition 5, we have $N_{1} = N_{2}$ .
(iii): By using Equation (13), we obtain

$\begin{matrix} Δ_{℘}^{d i s t} (N_{1}, N_{2}) & = & {(\frac{| Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} \\ = & {(\frac{| Ψ_{2} - Ψ_{1} |^{℘} + | Θ_{2} - Θ_{1} |^{℘} + | ρ_{2} - ρ_{1} |^{℘} + {| σ_{2} - σ_{1} |}^{℘}}{4})}^{\frac{1}{℘}} \\ = & Δ_{℘}^{d i s t} (N_{2}, N_{1}) . \end{matrix}$
(iv): From Definition 5, we can write $N_{1}^{c} = (〈 ł_{Θ_{1}}, ł_{Ψ_{1}} 〉, 〈 ł_{σ_{1}}, ł_{ρ_{1}} 〉)$ and
$N_{2}^{c} = (〈 ł_{Θ_{2}}, ł_{Ψ_{2}} 〉, 〈 ł_{σ_{2}}, ł_{ρ_{1}} 〉)$ . By considering Definition 10, we obtain

$\begin{matrix} Δ_{℘}^{d i s t} (N_{1}^{c}, N_{2}^{c}) = {(\frac{| Θ_{1} - Θ_{2} |^{℘} + | Ψ_{1} - Ψ_{2} |^{℘} + | σ_{1} - σ_{2} |^{℘} + {| ρ_{1} - ρ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} \end{matrix}$

(17)

Thus, by Equations (13) and (17), we conclude that $Δ_{℘}^{d i s t} (N_{1}, N_{2}) = Δ_{℘}^{d i s t} (N_{1}^{c}, N_{2}^{c})$ .
(v): Assume that $N_{1} \leq N_{2} \leq N_{3}$ for $N_{1}, N_{2}, N_{3} \in ℧_{[0, g]}$ . Then, it is known from Definition 5 that

Ψ_{1} \leq Ψ_{2} \leq Ψ_{3}

,

Θ_{1} \geq Θ_{2} \geq Θ_{3}

,

ρ_{1} \leq ρ_{2} \leq ρ_{3}

and

σ_{1} \geq σ_{2} \geq σ_{3}

.

Thus, we obtain

| Ψ_{1} - Ψ_{3} | \geq | Ψ_{1} - Ψ_{2} |

,

| Θ_{1} - Θ_{3} | \geq | Θ_{1} - Θ_{2} |

,

| ρ_{1} - ρ_{3} | \geq | ρ_{1} - ρ_{2} |

and

| σ_{1} - σ_{3} | \geq | σ_{1} - σ_{2} |

.

Then, it is obvious that

\begin{matrix} | Ψ_{1} - Ψ_{3} | + | Θ_{1} - Θ_{3} | + | ρ_{1} - ρ_{3} | + | σ_{1} - σ_{3} | \geq | Ψ_{1} - Ψ_{2} | + | Θ_{1} - Θ_{2} | + | ρ_{1} - ρ_{2} | + | σ_{1} - σ_{2} | \end{matrix}

For

℘ \geq 1

, we have

\begin{matrix} | Ψ_{1} - Ψ_{3} |^{℘} + | Θ_{1} - Θ_{3} |^{℘} + | ρ_{1} - ρ_{3} |^{℘} + {| σ_{1} - σ_{3} |}^{℘} \\ \geq | Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘} \end{matrix}

(18)

and so

\begin{matrix} {(\frac{| Ψ_{1} - Ψ_{3} |^{℘} + | Θ_{1} - Θ_{3} |^{℘} + | ρ_{1} - ρ_{3} |^{℘} + {| σ_{1} - σ_{3} |}^{℘}}{4})}^{\frac{1}{℘}} \\ \geq {(\frac{| Ψ_{1} - Ψ_{2} |^{℘} + | Θ_{1} - Θ_{2} |^{℘} + | ρ_{1} - ρ_{2} |^{℘} + {| σ_{1} - σ_{2} |}^{℘}}{4})}^{\frac{1}{℘}} \end{matrix}

(19)

Hence, we deduce that

Δ_{℘}^{d i s t} (N_{1}, N_{3}) \geq Δ_{℘}^{d i s t} (N_{1}, N_{2})

. Proceeding with a similar technique, it can be shown that

Δ_{℘}^{d i s t} (N_{1}, N_{3}) \geq Δ_{℘}^{d i s t} (N_{2}, N_{3})

. Thus, the proof ends. □

5. LLDF-TOPSIS Method with Application in Linguistic Multicriteria Decision-Making

5.1. Linguistic Linear Diophantine Fuzzy TOPSIS Method

In this part, we construct the linguistic linear Diophantine fuzzy TOPSIS (technique for order preference by similarity to ideal solution) method to deal with the linguistic multicriteria decision-making problems.

Firstly, we describe the nature of linguistic multicriteria decision-making (LMCDM), known as multicriteria decision-making under linguistic information. The LMCDM is a sub-discipline of operations research that linguistically evaluates the alternatives (objects) concerning the multiple conflicting criteria in decision-making. An LMCDM problem is as follows:

The decision-maker (DM) is asked to assess a set of alternatives

H = {ℏ_{1}, ℏ_{2}, \dots, ℏ_{s}}

concerning the criteria

C = {c_{1}, c_{2}, \dots, c_{t}}

, where the linguistic term set is

Ł = {ł_{0}, ł_{1}, \dots, ł_{g}}

, then the linguistic linear Diophantine fuzzy assessment (LLDF assessment) of alternative

ℏ_{i}

under the criterion

c_{k}

provided by the DM is represented as

\begin{matrix} λ_{k} = (ℏ_{i}, 〈 ł_{Ψ}^{k} (ℏ_{i}), ł_{Θ}^{k} (ℏ_{i}) 〉, 〈 ł_{ρ}^{k} (ℏ_{i}), ł_{σ}^{k} (ℏ_{i}) 〉) \end{matrix}

(20)

where

ł_{Ψ}^{k} (ℏ_{i}), ł_{Θ}^{k} (ℏ_{i}), ł_{ρ}^{k} (ℏ_{i}), ł_{σ}^{k} (ℏ_{i}) \in ℧_{[0, g]}

represent the linguistic assessments of membership, nonmembership, and reference parameters of

ℏ_{i}

provided by the DM according to the criterion

c_{k}

. That is,

(〈 ł_{Ψ}^{k} (ℏ_{i}), ł_{Θ}^{k} (ℏ_{i}) 〉, 〈 ł_{ρ}^{k} (ℏ_{i}), ł_{σ}^{k} (ℏ_{i}) 〉)

is LLDF assessment of

ℏ_{i}

provided by the DM according to the criterion

c_{k}

. Here, the LLDF assessments of alternatives are LLDFNs on Ł.

Example 10.

Suppose that the set of alternatives is

H = {ℏ_{1}, ℏ_{2}, ℏ_{3}, ℏ_{4}}

, the criteria set is

C = {c_{1}, c_{2}, c_{3}, c_{4}, c_{5}}

, and the linguistic term set is

\begin{matrix} Ł = \{\begin{matrix} ł_{0} = W o r s t (W), ł_{1} = V e r y P o o r (V P), \\ ł_{2} = P o o r (P), ł_{3} = M e d i u m (M), ł_{4} = F i n e (F), \\ ł_{5} = V e r y F i n e (V F), ł_{6} = P e r f e c t (P R) \end{matrix}\} . \end{matrix}

Then, the LLDF assessments provided by the DM d are presented as in Table 3.

The procedure of TOPSIS is based on the decision matrix, distance measures, and aggregation operators (Shih et al., 2007). As a result of this procedure, the output data are expounded, and thereby the ranking order of alternatives is acquired. In a summary, the TOPSIS approach is a practical and useful technique for sorting, ranking, and choosing several externally determined alternatives using some distance measures. The main procedure of TOPSIS is described in a series of steps as follows (Hwang, & Yoon, 1981; Shih et al., 2007).

Collect the assessments of alternatives concerning the criteria.
Create the decision matrix corresponding to these collected assessments.
Obtain the positive ideal solution (PIS) and negative ideal solution (NIS) of alternatives.
Compute the relative closeness degrees of alternatives.
Rank alternatives according to their relative closeness degrees.

In the procedure of TOPSIS, we can utilize the LLDF assessments to express the assessments of alternatives concerning the criteria. That is, we can use LLDFS defined on

Ł_{[0, g]}

and the weights of criteria to represent the uncertain assessments of alternatives provided by DM concerning the criteria. Thus, by modifying the TOPSIS method for the LLDFS, we create an LLDF-TOPSIS method. For the steps of the LLDF-TOPSIS procedure, we describe the concepts of the LLDF decision matrix, positive and negative ideal solutions, and relative closeness degree.

Definition 11.

Let

H = {ℏ_{i} : i = 1, 2, \dots, s}

be the set of alternatives,

C = {c_{k} : k = 1, 2, \dots, t}

be the set of criteria, and

ϖ = {(ϖ_{1}, ϖ_{2}, \dots, ϖ_{t})}^{T}

be a weight vector, where

ϖ_{k}

is the weightage of criterion

c_{k}

for

k = 1, 2, \dots, t

. In addition, let

λ_{i k} = (〈 ł_{Ψ_{i k}}, ł_{Θ_{i k}} 〉, 〈 ł_{ρ_{i k}}, ł_{σ_{i k}} 〉)

be the LLDF assessment of the alternative

ℏ_{i}

provided by the DM concerning the criterion

c_{k}

(i.e.,

Λ_{i k}

is an LLDFN defined on

Ł_{[0, g]}

. Then, the LLDF decision matrix of an LMCDM can be described as

Λ = {(λ_{i k})}_{s \times t} =

[\begin{matrix} ℏ_{1} & (〈 ł_{Ψ_{11}}, ł_{Θ_{11}} 〉, 〈 ł_{ρ_{11}}, ł_{σ_{11}} 〉) & (〈 ł_{Ψ_{12}}, ł_{Θ_{12}} 〉, 〈 ł_{ρ_{12}}, ł_{σ_{12}} 〉) & \dots & (〈 ł_{Ψ_{1 t}}, ł_{Θ_{1 t}} 〉, 〈 ł_{ρ_{1 t}}, ł_{σ_{1 t}} 〉) \\ ℏ_{2} & (〈 ł_{Ψ_{21}}, ł_{Θ_{21}} 〉, 〈 ł_{ρ_{21}}, ł_{σ_{21}} 〉) & (〈 ł_{Ψ_{22}}, ł_{Θ_{22}} 〉, 〈 ł_{ρ_{22}}, ł_{σ_{22}} 〉) & \dots & (〈 ł_{Ψ_{2 t}}, ł_{Θ_{2 t}} 〉, 〈 ł_{ρ_{2 t}}, ł_{σ_{2 t}} 〉) \\ ⋮ & ⋮ & ⋮ & ⋱ & ⋮ \\ ℏ_{s} & (〈 ł_{Ψ_{s 1}}, ł_{Θ_{s 1}} 〉, 〈 ł_{ρ_{s 1}}, ł_{σ_{s 1}} 〉) & (〈 ł_{Ψ_{s 2}}, ł_{Θ_{s 2}} 〉, 〈 ł_{ρ_{s 2}}, ł_{σ_{s 2}} 〉) & ⋮ & (〈 ł_{Ψ_{s t}}, ł_{Θ_{s t}} 〉, 〈 ł_{ρ_{s t}}, ł_{σ_{s t}} 〉) \end{matrix}]

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Example 11.

We consider the LLDF assessments given in Table 3. In addition, we assume that the weight vector for the criteria

C = {c_{1}, c_{2}, c_{3}, c_{4}, c_{5}}

is

ϖ = {(0.1, 0.2, 0.3, 0.3, 0.1)}^{T}

. Then, the LLDF decision matrix of the LMCDM in Example 10 is represented as

Λ = {(λ_{i k})}_{4 \times 5} =

[\begin{matrix} ℏ_{1} & (〈 ł_{6}, ł_{1} 〉, 〈 ł_{4}, ł_{2} 〉) & (〈 ł_{5}, ł_{2} 〉, 〈 ł_{5}, ł_{0} 〉) & (〈 ł_{4}, ł_{2} 〉, 〈 ł_{4}, ł_{1} 〉) & (〈 ł_{6}, ł_{3} 〉, 〈 ł_{5}, ł_{1} 〉) & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{6}, ł_{0} 〉) \\ ℏ_{2} & (〈 ł_{4}, ł_{6} 〉, 〈 ł_{3}, ł_{2} 〉) & (〈 ł_{2}, ł_{7} 〉, 〈 ł_{2}, ł_{4} 〉) & (〈 ł_{1}, ł_{8} 〉, 〈 ł_{2}, ł_{4} 〉) & (〈 ł_{1}, ł_{5} 〉, 〈 ł_{1}, ł_{5} 〉) & (〈 ł_{3}, ł_{6} 〉, 〈 ł_{0}, ł_{4} 〉) \\ ℏ_{3} & (〈 ł_{3}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉) & (〈 ł_{2}, ł_{6} 〉, 〈 ł_{5}, ł_{1} 〉) & (〈 ł_{3}, ł_{2} 〉, 〈 ł_{2}, ł_{3} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{2}, ł_{4} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉) \\ ℏ_{4} & (〈 ł_{6}, ł_{4} 〉, 〈 ł_{4}, ł_{1} 〉) & (〈 ł_{3}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉) & (〈 ł_{6}, ł_{3} 〉, 〈 ł_{2}, ł_{1} 〉) & (〈 ł_{3}, ł_{4} 〉, 〈 ł_{3}, ł_{0} 〉) & (〈 ł_{3}, ł_{2} 〉, 〈 ł_{1}, ł_{2} 〉) \end{matrix}]

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Considering the LLDF decision matrix

Λ

(in Definition 11), we can describe the positive ideal solution (PIS) and negative ideal solution (NIS) of alternatives by employing the union and intersection operations of LLDFNs, respectively, concerning the LLDFWAA operator as follows.

Definition 12.

Let

Λ = {(λ_{i k})}_{s \times t}

be an LLDF decision matrix representing the LLDF assessments. Then,

(a): The positive ideal solution (PIS) of alternatives is denoted and defined as

$\begin{matrix} S^{+} & = & (〈 ł_{Ψ_{n}}, ł_{Θ_{n}} 〉, 〈 ł_{ρ_{n}}, ł_{σ_{n}} 〉) \\ = & L L D F W A A_{ϖ} (\lor c_{1}, \lor c_{2}, \dots, \lor c_{t}) \\ = & (〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{\lor Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{\lor Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{\lor ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{\lor σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}$

(23)

where $ϖ_{k}$ is the weightage of criterion $c_{k}$ , and

$\begin{matrix} \lor c_{k} & = & (〈 ł_{\lor Ψ_{k}}, ł_{\lor Θ_{k}} 〉, 〈 ł_{\lor ρ_{k}}, ł_{\lor σ_{k}} 〉) \\ = & ⋃_{i = 1}^{s} (〈 ł_{Ψ_{i k}}, ł_{Θ_{i k}} 〉, 〈 ł_{ρ_{i k}}, ł_{σ_{i k}} 〉) \\ = & (〈 ł_{max {Ψ_{1 k}, \dots, Ψ_{s k}}}, ł_{min {Θ_{1 k}, \dots, Θ_{s k}}} 〉, 〈 ł_{max {ρ_{1 k}, \dots, ρ_{s k}}}, ł_{min {σ_{1 k}, \dots, σ_{s k}}} 〉) \end{matrix}$

(24)
(b): The negative ideal solution (NIS) of alternatives is denoted and defined as

$\begin{matrix} S^{-} & = & (〈 ł_{Ψ_{n}}, ł_{Θ_{n}} 〉, 〈 ł_{ρ_{n}}, ł_{σ_{n}} 〉) \\ = & L L D F W A A_{ϖ} (\land c_{1}, \land c_{2}, \dots, \land c_{t}) \\ = & (〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{\land Ψ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{\land Θ_{k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{\land ρ_{k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{\land σ_{k}}{g})}^{ϖ_{k}}}〉) \end{matrix}$

(25)

where $ϖ_{k}$ is the weightage of criterion $c_{k}$ and $\land c_{k}$ is the same as

$\begin{matrix} \land c_{k} & = & (〈 ł_{\land Ψ_{k}}, ł_{\land Θ_{k}} 〉, 〈 ł_{\land ρ_{k}}, ł_{\land σ_{k}} 〉) \\ = & ⋂_{i = 1}^{s} (〈 ł_{Ψ_{i k}}, ł_{Θ_{i k}} 〉, 〈 ł_{ρ_{i k}}, ł_{σ_{i k}} 〉) \\ = & (〈 ł_{min {Ψ_{1 k}, \dots, Ψ_{s k}}}, ł_{max {Θ_{1 k}, \dots, Θ_{s k}}} 〉, 〈 ł_{min {ρ_{1 k}, \dots, ρ_{s k}}}, ł_{max {σ_{1 k}, \dots, σ_{s k}}} 〉) \end{matrix}$

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Example 12.

By considering the LLDF decision matrix Λ in Example 11, we obtain

\lor c_{1} = (〈 ł_{6}, ł_{1} 〉, 〈 ł_{4}, ł_{0} 〉)

,

\lor c_{2} = (〈 ł_{5}, ł_{2} 〉, 〈 ł_{5}, ł_{0} 〉)

,

\lor c_{3} = (〈 ł_{6}, ł_{2} 〉, 〈 ł_{4}, ł_{1} 〉)

,

\lor c_{4} = (〈 ł_{6}, ł_{2} 〉,

〈 ł_{5}, ł_{0} 〉)

,

\lor c_{5} = (〈 ł_{4}, ł_{1} 〉, 〈 ł_{6}, ł_{0} 〉)

, and

\land c_{1} = (〈 ł_{3}, ł_{6} 〉, 〈 ł_{2}, ł_{2} 〉)

,

\land c_{2} = (〈 ł_{2}, ł_{7} 〉, 〈 ł_{2}, ł_{4} 〉)

,

\land c_{3} = (〈 ł_{1}, ł_{8} 〉, 〈 ł_{2}, ł_{4} 〉)

,

\land c_{4} = (〈 ł_{1}, ł_{5} 〉,

〈 ł_{1}, ł_{5} 〉)

,

\land c_{5} = (〈 ł_{1}, ł_{6} 〉, 〈 ł_{0}, ł_{4} 〉)

. By using Equations (23) and (25), we calculate the PIS and NIS for the LLDF decision matrix Λ as follows:

S^{+}

\begin{matrix} = & L L D F W A A_{ϖ} (\lor c_{1}, \lor c_{2}, \lor c_{3}, \lor c_{4}, \lor c_{5}) \\ = & (〈 ł_{6 - 6 \prod_{k = 1}^{5} {(1 - \frac{\lor Ψ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{5} {(\frac{\lor Θ_{k}}{6})}^{ϖ_{k}}} 〉, 〈 ł_{6 - 6 \prod_{k = 1}^{5} {(1 - \frac{\lor ρ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{5} {(\frac{\lor σ_{k}}{6})}^{ϖ_{k}}} 〉) \\ = & (\begin{matrix} 〈 ł_{6 - 6 \times ({(1 - \frac{6}{6})}^{0.1} \times {(1 - \frac{5}{6})}^{0.2} \times {(1 - \frac{6}{6})}^{0.3} \times {(1 - \frac{6}{6})}^{0.3} \times {(1 - \frac{4}{6})}^{0.1})}, ł_{6 \times ({(\frac{1}{6})}^{0.1} \times {(\frac{2}{6})}^{0.2} \times {(\frac{2}{6})}^{0.3} \times {(\frac{2}{6})}^{0.3} \times {(\frac{1}{6})}^{0.1})} 〉, \\ 〈 ł_{6 - 6 \times ({(1 - \frac{4}{6})}^{0.1} \times {(1 - \frac{5}{6})}^{0.2} \times {(1 - \frac{4}{6})}^{0.3} \times {(1 - \frac{5}{6})}^{0.3} \times {(1 - \frac{6}{6})}^{0.1})}, ł_{6 \times ({(\frac{0}{6})}^{0.1} \times {(\frac{0}{6})}^{0.2} \times {(\frac{1}{6})}^{0.3} \times {(\frac{0}{6})}^{0.3} \times {(\frac{0}{6})}^{0.1})} 〉 \end{matrix}) \\ = & (〈 ł_{6}, ł_{1.7411011} 〉, 〈 ł_{6}, ł_{0} 〉), \end{matrix}

S^{-}

\begin{matrix} = & L L D F W A A_{ϖ} (\land c_{1}, \land c_{2}, \land c_{3}, \land c_{4}, \land c_{5}) \\ = & (〈 ł_{6 - 6 \prod_{k = 1}^{5} {(1 - \frac{\land Ψ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{5} {(\frac{\land Θ_{k}}{6})}^{ϖ_{k}}} 〉, 〈 ł_{6 - 6 \prod_{k = 1}^{5} {(1 - \frac{\land ρ_{k}}{6})}^{ϖ_{k}}}, ł_{6 \prod_{k = 1}^{5} {(\frac{\land σ_{k}}{6})}^{ϖ_{k}}} 〉) \\ = & (\begin{matrix} 〈 ł_{6 - 6 \times ({(1 - \frac{3}{6})}^{0.1} \times {(1 - \frac{2}{6})}^{0.2} \times {(1 - \frac{1}{6})}^{0.3} \times {(1 - \frac{1}{6})}^{0.3} \times {(1 - \frac{1}{6})}^{0.1})}, ł_{6 \times ({(\frac{6}{6})}^{0.1} \times {(\frac{7}{6})}^{0.2} \times {(\frac{8}{6})}^{0.3} \times {(\frac{5}{6})}^{0.3} \times {(\frac{6}{6})}^{0.1})} 〉, \\ 〈 ł_{6 - 6 \times ({(1 - \frac{2}{6})}^{0.1} \times {(1 - \frac{2}{6})}^{0.2} \times {(1 - \frac{2}{6})}^{0.3} \times {(1 - \frac{1}{6})}^{0.3} \times {(1 - \frac{0}{6})}^{0.1})}, ł_{6 \times ({(\frac{2}{6})}^{0.1} \times {(\frac{4}{6})}^{0.2} \times {(\frac{4}{6})}^{0.3} \times {(\frac{5}{6})}^{0.3} \times {(\frac{4}{6})}^{0.1})} 〉 \end{matrix}) \\ = & (〈 ł_{1.4563682}, ł_{6.3865726} 〉, 〈 ł_{1.546083}, ł_{3.9905246} 〉), \end{matrix}

Utilizing the TOPSIS model to rank the alternatives, the relative closeness degree of each alternative is calculated; theoretically, the relative closeness index is determined by distances between the uncertain assessment and the positive–negative ideal solutions. Originating from the TOPSIS model, the ranking of alternatives is based on the shortest distance from the PIS and the farthest distance from the NIS; formally, this is also satisfied by the relative closeness index of each alternative in existing TOPSIS models. Based on the Minkowski distance between the LLDF assessment and the positive–negative ideal solutions, we propose the following relative closeness degree

ℜ_{i}

of each alternative

ℏ_{i}

.

Definition 13.

The relative closeness degree of alternative

ℏ_{i}

concerning the LLDF-based Minkowski (especially Hamming, Euclidean, Chebyshev) distance can be defined by

\begin{matrix} ℜ_{i} = \frac{Δ_{℘}^{d i s t} (λ_{i}, S^{-})}{Δ_{℘}^{d i s t} (λ_{i}, S^{+}) + Δ_{℘}^{d i s t} (λ_{i}, S^{-})} \end{matrix}

(27)

where

\begin{matrix} λ_{i} & = & (〈 ł_{Ψ_{i}}, ł_{Θ_{i}} 〉, 〈 ł_{ρ_{i}}, ł_{σ_{i}} 〉) \\ = & L L D F W A A_{ϖ} (λ_{i 1}, λ_{i 2}, \dots, λ_{i t}) \\ = & (〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{Ψ_{i k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{Θ_{i k}}{g})}^{ϖ_{k}}}〉, 〈ł_{g - g \prod_{k = 1}^{t} {(1 - \frac{ρ_{i k}}{g})}^{ϖ_{k}}}, ł_{g \prod_{k = 1}^{t} {(\frac{σ_{i k}}{g})}^{ϖ_{k}}}〉) \end{matrix}

(28)

Note 1. In Definition 12, the PIS and NIS can be described as

S^{+} = L L D F W G A_{ϖ} (\lor c_{1}, \lor c_{2}, \dots, \lor c_{t})

and

S^{-} = L L D F W G A_{ϖ} (\land c_{1}, \land c_{2}, \dots, \land c_{t})

.

In such a case, we should consider

λ_{i} = L L D F W G A_{ϖ} (λ_{i 1}, λ_{i 2}, \dots, λ_{i t})

in Equation (28).

Definition 14.

Based on the relative closeness degrees of alternatives concerning the LLDF-based Minkowski distance, the ranking order of alternatives can be formed as follows:

$ℏ_{i} ≻ ℏ_{i^{*}}$ if $ℜ_{i} > ℜ_{i^{*}}$ ;
$ℏ_{i} = ℏ_{i^{*}}$ if $ℜ_{i} = ℜ_{i^{*}}$ .

Example 13.

For the LLDF decision matrix Λ, we obtain the following (by using Equation (28)):

\begin{matrix} λ_{1} & = & L L D F W A A_{ϖ} (λ_{11}, λ_{12}, λ_{13}, λ_{14}, λ_{15}) \\ = & L L D F W A A_{ϖ} ((〈 ł_{6}, ł_{1} 〉, 〈 ł_{4}, ł_{2} 〉), (〈 ł_{5}, ł_{2} 〉, 〈 ł_{5}, ł_{0} 〉), (〈 ł_{4}, ł_{2} 〉, 〈 ł_{4}, ł_{1} 〉), (〈 ł_{6}, ł_{3} 〉, 〈 ł_{5}, ł_{1} 〉), (〈 ł_{4}, ł_{1} 〉, 〈 ł_{6}, ł_{0} 〉)) \\ = & (〈 ł_{6}, ł_{1.9663072} 〉, 〈 ł_{6}, ł_{0} 〉), \end{matrix}

\begin{matrix} λ_{2} & = & L L D F W A A_{ϖ} (λ_{11}, λ_{12}, λ_{13}, λ_{14}, λ_{15}) \\ = & L L D F W A A_{ϖ} ((〈 ł_{4}, ł_{6} 〉, 〈 ł_{3}, ł_{2} 〉), (〈 ł_{2}, ł_{7} 〉, 〈 ł_{2}, ł_{4} 〉), (〈 ł_{1}, ł_{8} 〉, 〈 ł_{2}, ł_{4} 〉), (〈 ł_{1}, ł_{5} 〉, 〈 ł_{1}, ł_{5} 〉), (〈 ł_{3}, ł_{6} 〉, 〈 ł_{0}, ł_{4} 〉)) \\ = & (〈 ł_{1.8541926}, ł_{6.3865726} 〉, 〈 ł_{1.6723887}, ł_{3.9905246} 〉), \end{matrix}

\begin{matrix} λ_{3} & = & L L D F W A A_{ϖ} (λ_{11}, λ_{12}, λ_{13}, λ_{14}, λ_{15}) \\ = & L L D F W A A_{ϖ} ((〈 ł_{3}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉), (〈 ł_{2}, ł_{6} 〉, 〈 ł_{5}, ł_{1} 〉), (〈 ł_{3}, ł_{2} 〉, 〈 ł_{2}, ł_{3} 〉), (〈 ł_{1}, ł_{2} 〉, 〈 ł_{2}, ł_{4} 〉), (〈 ł_{1}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉)) \\ = & (〈 ł_{2.1019402}, ł_{2.3246161} 〉, 〈 ł_{3.1715729}, ł_{0} 〉), \end{matrix}

\begin{matrix} λ_{4} & = & L L D F W A A_{ϖ} (λ_{11}, λ_{12}, λ_{13}, λ_{14}, λ_{15}) \\ = & L L D F W A A_{ϖ} ((〈 ł_{6}, ł_{4} 〉, 〈 ł_{4}, ł_{1} 〉), (〈 ł_{3}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉), (〈 ł_{6}, ł_{3} 〉, 〈 ł_{2}, ł_{1} 〉), (〈 ł_{3}, ł_{4} 〉, 〈 ł_{3}, ł_{0} 〉), (〈 ł_{3}, ł_{2} 〉, 〈 ł_{1}, ł_{2} 〉)) \\ = & (〈 ł_{6}, ł_{2.9803644} 〉, 〈 ł_{2.9523831}, ł_{0} 〉), \end{matrix}

Then, by utilizing the PIS (

S^{+}

) and NIS (

S^{-}

) in Example 12 and the Minkowski distance (for

℘ = 3

) introduced in Definition 10, we calculate

Δ_{℘}^{d i s t} (λ_{1}, S_{A}^{+}) = {(\frac{{| 6 - 6 |}^{3} {+ | 1.9663072 - 1.7411011 |}^{3} {+ | 6 - 6 |}^{3} + {| 0 - 0 |}^{3}}{4})}^{\frac{1}{3}} = 0.0563015,

Δ_{℘}^{d i s t} (λ_{2}, S_{A}^{+}) = {(\frac{{| 1.8541926 - 6 |}^{3} {+ | 6.3865726 - 1.7411011 |}^{3} {+ | 1.6723887 - 6 |}^{3} + {| 3.9905246 - 0 |}^{3}}{4})}^{\frac{1}{3}} = 1.7030059,

Δ_{℘}^{d i s t} (λ_{3}, S_{A}^{+}) = {(\frac{{| 2.1019402 - 6 |}^{3} {+ | 2.3246161 - 1.7411011 |}^{3} {+ | 3.1715729 - 6 |}^{3} + {| 0 - 0 |}^{3}}{4})}^{\frac{1}{3}} = 1.0863703,

Δ_{℘}^{d i s t} (λ_{4}, S_{A}^{+}) = {(\frac{{| 6 - 6 |}^{3} {+ | 2.9803644 - 1.7411011 |}^{3} {+ | 2.9523831 - 6 |}^{3} + {| 0 - 0 |}^{3}}{4})}^{\frac{1}{3}} = 0.7786113,

Δ_{℘}^{d i s t} (λ_{1}, S_{A}^{-}) = {(\frac{{| 6 - 1.4563682 |}^{3} {+ | 1.9663072 - 6.3865726 |}^{3} {+ | 6 - 1.546083 |}^{3} + {| 0 - 3.9905246 |}^{3}}{4})}^{\frac{1}{3}} = 1.7312073,

Δ_{℘}^{d i s t} (λ_{2}, S_{A}^{-}) = {(\frac{{| 1.8541926 - 1.4563682 |}^{3} {+ | 6.3865726 - 6.3865726 |}^{3} {+ | 1.6723887 - 1.546083 |}^{3} + {| 3.9905246 - 3.9905246 |}^{3}}{4})}^{\frac{1}{3}} = 0.1005059,

Δ_{℘}^{d i s t} (λ_{3}, S_{A}^{-}) = {(\frac{{| 2.1019402 - 1.4563682 |}^{3} {+ | 2.3246161 - 6.3865726 |}^{3} {+ | 3.1715729 - 1.546083 |}^{3} + {| 0 - 3.9905246 |}^{3}}{4})}^{\frac{1}{3}} = 1.2828948,

Δ_{℘}^{d i s t} (λ_{4}, S_{A}^{-}) = {(\frac{{| 6 - 1.4563682 |}^{3} {+ | 2.9803644 - 6.3865726 |}^{3} {+ | 2.9523831 - 1.546083 |}^{3} + {| 0 - 3.9905246 |}^{3}}{4})}^{\frac{1}{3}} = 1.4611521 .

Hence, we compute the relative closeness degree for each alternative

ℏ_{i}

as

\begin{matrix} ℜ_{1} = 0.9685028, ℜ_{2} = 0.0557279, ℜ_{3} = 0.5414737, and ℜ_{4} = 0.6523689 . \end{matrix}

From Definition 14, the ranking order of alternatives

ℏ_{1}

,

ℏ_{2}

,

ℏ_{3}

, and

ℏ_{4}

is

ℏ_{1} ≻ ℏ_{4} ≻ ℏ_{3} ≻ ℏ_{2}

.

If we use the PIS and NIS as

S^{+} = L L D F W G A_{ϖ} (\lor c_{1}, \lor c_{2}, \dots, \lor c_{t})

and

S^{-} = L L D F W G A_{ϖ} (\land c_{1}, \land c_{2}, \dots, \land c_{t})

, respectively, in Definition 12 and

λ_{i} = L L D F W G A_{ϖ} (λ_{i 1}, λ_{i 2}, \dots, λ_{i t})

in Equation (28), we obtain the relative closeness degree for each alternative

ℏ_{i}

as

\begin{matrix} ℜ_{1} = 0.8919813, ℜ_{2} = 0.02759, ℜ_{3} = 0.3401567, and ℜ_{4} = 0.6407655 . \end{matrix}

From Definition 14, the ranking order of alternatives

ℏ_{1}

,

ℏ_{2}

,

ℏ_{3}

, and

ℏ_{4}

is

ℏ_{1} ≻ ℏ_{4} ≻ ℏ_{3} ≻ ℏ_{2}

.

Based on the above concepts, we elaborate the algorithm of LLDF-TOPSIS to deal with the LMCDMs as follows.

Algorithm (LLDF-TOPSIS)

Input:: The set of s alternatives $H = {ℏ_{0}, ℏ_{1}, \dots, ℏ_{s}}$ , the set of t criterions $C = {c_{0}, c_{1}, \dots, c_{s}}$ , and the linguistic term set $= {ł_{0}, ł_{1}, \dots, ł_{g}}$ .
Step 1:: According to the LLDF assessments, construct an LLDF decision matrix $Λ$ for the LMCDM problem.
Step 2:: For each column of the LLDF decision matrix $Λ$ , calculate $\lor c_{k}$ (Equation (24)) and $\land c_{k}$ (Equation (26)), and then determine the PIS $S^{+}$ (Equation (23)) and the NIS $S^{-}$ (Equation (25)) by using LLDFWAA or LLDFWGA operator.
Step 3:: For each row of the LLDF decision matrix $Λ$ , obtain the LLDF aggregated value $λ_{i}$ (Equation (28)) of each alternative $ℏ_{i}$ by using LLDFWAA or LLDFWGA operator.
Step 4:: For each alternative $ℏ_{i}$ , measure the distances $Δ_{℘}^{d i s t} (λ_{i}, S^{+})$ and $Δ_{℘}^{d i s t} (λ_{i}, S^{-})$ (by employing Equation (13)).
Step 5:: For each alternative $ℏ_{i}$ , calculate the relative closeness degree $ℜ_{i}$ (Equation (27)), and then rank all the alternatives.
Output:: The alternative having the highest relative closeness degree will be selected as a decision.

5.2. Application of Proposed LLDF-TOPSIS Method to Select the Best Software Consultants

Example 14.

To execute any online related services (online classes, exams, meetings, interviews, etc.), the interference of software consultants are most important. For instance, TCS (Tata Consultancy Services), consulting and business solutions, private limited, India, is supporting NTA (National Testing Agency), an autonomous and self-sustained testing organization in India to conduct the online examinations for JEE (Joint Entrance Examination), NEET (National Eligibility Cum Entrance Test), CMAT (Common Management Admission Test), GPAT (Graduate Pharmacy Aptitude Test), UGC-NET (University Grant Commission National Eligibility Test), and so on. To provide smooth and fair online services, the selection of the best software consultants is a tedious process for an organization. Suppose that there are five software consultants,

ℏ_{1}, ℏ_{2}, ℏ_{3}, ℏ_{4},

and

ℏ_{5}

. To select the best software consultants among them, we need to evaluate the criteria

c_{1}

—business and industry expertise,

c_{2}

—market knowledge,

c_{3}

—program/project management capabilities,

c_{4}

—methodology,

c_{5}

—communications, and

c_{6}

—independence, and objectivity against them, based on the linguistic terms

ł_{0} =

worst,

ł_{1} =

poor,

ł_{2} =

average,

ł_{3} =

good, and

ł_{4} =

excellent. Assume that

ϖ = {(0.1, 0.12, 0.22, 0.26, 0.13, 0.17)}^{T}

is a weight vector of criteria, respectively, and the decision-maker submitted the LLDF decision matrix as follows.

Λ =

[\begin{matrix} ℏ_{1} & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{4}, ł_{0} 〉) & (〈 ł_{3}, ł_{2} 〉, 〈 ł_{3}, ł_{0} 〉) & (〈 ł_{4}, ł_{2} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{4}, ł_{3} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉) & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{3}, ł_{0} 〉) \\ ℏ_{2} & (〈 ł_{4}, ł_{2} 〉, 〈 ł_{0}, ł_{2} 〉) & (〈 ł_{2}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{1} 〉, 〈 ł_{0}, ł_{2} 〉) & (〈 ł_{2}, ł_{2} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{3}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) \\ ℏ_{3} & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{0}, ł_{2} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{0}, ł_{4} 〉) \\ ℏ_{4} & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) \\ ℏ_{5} & (〈 ł_{2}, ł_{2} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{3}, ł_{0} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{3}, ł_{1} 〉, 〈 ł_{1}, ł_{0} 〉) & (〈 ł_{3}, ł_{3} 〉, 〈 ł_{1}, ł_{2} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{1}, ł_{0} 〉) \end{matrix}]

If we apply the proposed algorithm (LLDF-TOPSIS) by concerning the LLDFWAA operator for Hamming (

℘ = 1

), Euclidean (

℘ = 2

), and Chebyshev (

℘ = \infty

) distances, we obtain the relative closeness degree and the ranking order as per Table 4.

If we apply the proposed algorithm (LLDF-TOPSIS) by concerning the LLDFWGA operator for Hamming (

℘ = 1

), Euclidean (

℘ = 2

), and Chebyshev (

℘ = \infty

) distances, we obtain the relative closeness degree and the ranking order as per Table 5.

From Table 4 and Table 5, we observe that the ranking order of LLDF-TOPSIS by concerning both LLDFWAA and LLDFWGA operators for different distances, namely, Hamming, Euclidean, and Chebyshev, are the same as

ℏ_{1} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5} ≻ ℏ_{2}

. This leads to deciding that

ℏ_{1}

is the best software consultant among the other software consultants. The visual observation for ranking order of LLDF-TOPSIS by concerning both LLDFWAA and LLDFWGA operators for different distances Hamming, Euclidean, and Chebyshev are shown in Figure 4

5.3. Sensitivity Analysis of Proposed LLDF-TOPSIS Method

In this part, we perform a sensitivity analysis for the proposed LLDF-TOPSIS method by concerning both the operators LLDFWAA and LLDFWGA. To execute this, we consider Example 14. The results are displayed in Table 6 and Table 7. From Table 6 and Table 7, we observe that the proposed LLDF-TOPSIS method through both the operators LLDFWAA and LLDFWGA generates a consistent ranking order from

℘ = 1

to

℘ = 500

. It starts to generate inconsistent ranking order from

℘ = 500

to

℘ = 550

, and completely generates inconsistent ranking order at

℘ = 1000

and above.

5.4. Comparative Analysis to Show the Superiority of the Proposed LLDF-TOPSIS Method

In this section, we compare our proposed LLDF-TOPSIS method with some existing methods in Table 8 to show the superiority of our proposed one. The LDFS can be generalized into the LLDFS. To utilize the proposed LLDF-TOPSIS method to solve the decision-making (DM) problems in LDF, the DM problem (combined Tables 10–12) in the article (Riaz & Hashmi, 2019) under the environment of LDFS can be solved by the proposed LLDF-TOPSIS method through the LLDFWAA operator and

L L D F W G A

operator

(℘ = 1)

. The ranking exactly matches the existing Algorithm 2 (score function (SF), expectation score function (ESF)) (Riaz & Hashmi, 2019) in the LDFS. However, there is a little variation in the ranking of the proposed LLDF-TOPSIS method through the LLDFWAA operators

(℘ = 2, \infty)

and LLDFWGA operators

(℘ = 2, \infty)

with the ranking of Algorithm 2 (quadratic score function (QSF)) (Riaz, & Hashmi, 2019) in LDFS. The linguistic q-rung orthopair fuzzy number (Lq-ROFN) as well as the linguistic intuitionistic fuzzy number (LIFN) of the form

N = (〈 ł_{ρ}, ł_{σ} 〉)

can be viewed as an LLDFN,

N = (〈 0, 0 〉, 〈 ł_{ρ}, ł_{σ} 〉)

. It enables us to compare the proposed LLDF-TOPSIS method with the existing methods in the Lq-ROFS and LIFS. The ranking of Example 7.2 (Table 10) (Lin et al., 2020) for the existing method Lq-ROFWA (Lin et al., 2020) in Lq-ROFS is the same as the ranking of the proposed LLDF-TOPSIS method through the operators of LLDFWAA and LLDFWGA

(℘ = 1, 2, \infty)

. The ranking of Example 5.3 (Table 5) (Garg, & Kumar, 2019) for the existing methods (LIFWG (Zhang, 2014), LIFWPA, LIFWPG (Liu, & Qin, 2017), LCNWG (Garg, 2018b), LIFWA (Chen et al., 2015), LIFEWA (Garg, & Kumar, 2018), ILIFWA (Liu, & Wang, 2017), LCNWPG (Garg, & Kumar, 2019)) in LIFS coincides with the proposed LLDF-TOPSIS method through the LLDFWAA operator and LLDFWGA operator

(℘ = 1, 2, \infty)

. The ranking of the proposed LLDF-TOPSIS method through the operators of LLDFWAA

(℘ = 1, 2, \infty)

and LLDFWGA

(℘ = 1, 2)

matches the existing method (extended outranking approach (EOA)) (Zhang et al., 2017) in LIFS for the illustrative example (Zhang et al., 2017), but through the LLDFWGA operator

(℘ = \infty)

, the result is a little deviated. The ranking of the proposed LLDF-TOPSIS method through the LLDFWAA and LLDFWGA operators

(℘ = 1, 2, \infty)

deviates little from the ranking of methods ILIFWA (Liu, & Wang, 2017), ILIFWPA (Liu, & Wang, 2017), LIFWA (Chen et al., 2015), and LIFWPA (Liu, & Qin, 2017) for example (Table 6) (Liu, & Wang, 2017) in LIFS. The existing methods in the papers (Liu, & Qin, 2017) and (Chen et al., 2015) and the proposed LLDF-TOPSIS method through the LLDFWGA operator

(℘ = 1, 2, \infty)

for Example 5.5 (Garg, & Kumar, 2019) in LIFS fail to produce the ranking, but the proposed LLDF-TOPSIS method through the LLDFWAA operator

(℘ = 1, 2, \infty)

produces the feasible ranking. From the overall comparison, we conclude that our proposed LLDF-TOPSIS method through the LLDFWAA operator

(℘ = 1, 2, \infty)

is more convenient than, and superior to, the other methods.

5.5. Validity of Proposed LLDF-TOPSIS Method

In 2008, Wang and Triantaphyllou (2008) introduced some test criteria to check the validity of a decision-making (DM) method, as shown in Table 9. In this section, we verify Wang–Triantaphyllou’s test criteria by employing Example 14 to show the validity of our proposed LLDF-TOPSIS method.

5.5.1. Validity of Proposed LLDF-TOPSIS Method by Test Criterion

The nonoptimal alternatives

ℏ_{2}, ℏ_{3}, ℏ_{4}

, and

ℏ_{5}

in the decision matrix

Λ

of Example 14 are further worsening arbitrarily into

ℏ_{2}^{^{'}}, ℏ_{3}^{^{'}}, ℏ_{4}^{^{'}}

, and

ℏ_{5}^{^{'}}

, respectively, without interchanging the position of decision criteria, as follows.

ℏ_{2}^{^{'}} = (\begin{matrix} (〈 ł_{1}, ł_{4} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) \end{matrix})

ℏ_{3}^{^{'}} = (\begin{matrix} (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{0}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{0}, ł_{3} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) \end{matrix})

ℏ_{4}^{^{'}} = (\begin{matrix} (〈 ł_{1}, ł_{4} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{0}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{0}, ł_{3} 〉) & (〈 ł_{0}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) \end{matrix})

ℏ_{5}^{^{'}} = (\begin{matrix} (〈 ł_{0}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{0}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) \end{matrix})

For instance, the alternative

ℏ_{2}

in the decision matrix

Λ

of Example 14 is replaced by the worsened alternative

ℏ_{2}^{^{'}}

, then the original decision matrix

Λ

of Example 14 becomes a modified decision matrix

Λ_{1}^{^{'}}

, as follows.

Λ_{1}^{^{'}} = [\begin{matrix} ℏ_{1} & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{4}, ł_{0} 〉) & (〈 ł_{3}, ł_{2} 〉, 〈 ł_{3}, ł_{0} 〉) & (〈 ł_{4}, ł_{2} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{4}, ł_{3} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉) & (〈 ł_{4}, ł_{1} 〉, 〈 ł_{3}, ł_{0} 〉) \\ ℏ_{2}^{^{'}} & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) \\ ℏ_{3} & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{0}, ł_{2} 〉) & (〈 ł_{1}, ł_{2} 〉, 〈 ł_{0}, ł_{4} 〉) \\ ℏ_{4} & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{0}, ł_{4} 〉) & (〈 ł_{2}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{1}, ł_{4} 〉, 〈 ł_{1}, ł_{3} 〉) \\ ℏ_{5} & (〈 ł_{2}, ł_{2} 〉, 〈 ł_{1}, ł_{3} 〉) & (〈 ł_{3}, ł_{0} 〉, 〈 ł_{3}, ł_{1} 〉) & (〈 ł_{2}, ł_{3} 〉, 〈 ł_{2}, ł_{2} 〉) & (〈 ł_{3}, ł_{1} 〉, 〈 ł_{1}, ł_{0} 〉) & (〈 ł_{3}, ł_{3} 〉, 〈 ł_{1}, ł_{2} 〉) & (〈 ł_{1}, ł_{3} 〉, 〈 ł_{1}, ł_{0} 〉) \end{matrix}]

If the proposed LLDF-TOPSIS method concerning the LLDFWAA operator, Hamming (

℘ = 1

), Euclidean (

℘ = 2

), and Chebyshev (

℘ = \infty

) distances is utilized for the modified decision matrix

Λ_{1}^{^{'}}

of Example 14, we obtain the relative closeness degree and the modified ranking order as per Table 10.

Table 10. Ranking of LLDF-TOPSIS by concerning LLDFWAA operator for modified

Λ_{1}^{^{'}}

of Example 14.

Table 10. Ranking of LLDF-TOPSIS by concerning LLDFWAA operator for modified

Λ_{1}^{^{'}}

of Example 14.

℘	Relative Closeness Degree					Modified Ranking Order
1	0.8806164	0.0562014	0.2681607	0.1421125	0.722866	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$
2	0.7897406	0.0710804	0.2777813	0.1615761	0.6650673	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$
∞	0.6829091	0.1148618	0.3218475	0.176642	0.6156959	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$

If the proposed LLDF-TOPSIS method by concerning the LLDFWGA operator, Hamming (

℘ = 1

), Euclidean (

℘ = 2

), and Chebyshev (

℘ = \infty

) distances for the modified decision matrix

Λ^{^{'}}

of Example 14 is utilized, we obtain the relative closeness degree and the modified ranking order as per Table 11.

From Table 10 and Table 11, we observe that the modified ranking order of LLDF-TOPSIS method concerning both LLDFWAA and LLDFWGA operators, Hamming, Euclidean, and Chebyshev distances for modified

Λ_{1}^{^{'}}

of Example 14 is the same as

ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}

. This leads to deciding that

ℏ_{1}

is the best alternative. It coincides with the best alternative of original decision matrix

Λ

for Example 14. In the same way, other nonoptimal alternatives

ℏ_{3}, ℏ_{4}

, and

ℏ_{5}

of decision matrix

Λ

for Example 14 are further worsening into

ℏ_{3}^{^{'}}, ℏ_{4}^{^{'}}

, and

ℏ_{5}^{^{'}}

, respectively, without interchanging the decision criteria. We obtain the modified decision matrices

Λ_{3}^{^{'}}, Λ_{4}^{^{'}}

, and

Λ_{5}^{^{'}}

, respectively, for Example 14. If the proposed LLDF-TOPSIS method by concerning both LLDFWAA and LLDFWGA operators, Hamming, Euclidean, and Chebyshev distances is utilized for modified decision matrix

Λ_{i}^{^{'}}

(i = 3, 4, 5)

of Example 14, we obtain the modified ranking order as placed in Table 12. From Table 12, we observe that

ℏ_{1}

is the best alternative for all modified decision matrices

Λ_{3}^{^{'}}, Λ_{4}^{^{'}}

, and

Λ_{5}^{^{'}}

by utilizing the proposed LLDF-TOPSIS method by concerning both LLDFWAA and LLDFWGA operators, Hamming, Euclidean, and Chebyshev distances. It coincides with the original decision matrix

Λ

for Example 14. Therefore, the proposed LLDF-TOPSIS method is valid according to test criterion 1.

5.5.2. Validity of Proposed LLDF-TOPSIS Method by Test Criteria 2 and 3

The decision matrix

Λ

of Example 14 is further decomposed into sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

. The set of alternatives for sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

are

{ℏ_{1}, ℏ_{2}}

,

{ℏ_{1}, ℏ_{3}}

,

{ℏ_{2}, ℏ_{3}}

,

{ℏ_{1}, ℏ_{2}, ℏ_{3}}

,

{ℏ_{1}, ℏ_{2}, ℏ_{5}}

, and

{ℏ_{2}, ℏ_{3}, ℏ_{4}, ℏ_{5}}

respectively. The ranking of alternatives for decomposed sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

by concerning the proposed LLDF-TOPSIS method is displayed in Table 13. From Table 13, we observe that the decomposed ranking order for the decomposed sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

is

ℏ_{1} ≻ ℏ_{2}

,

ℏ_{1} ≻ ℏ_{3}

,

ℏ_{2} ≻ ℏ_{3}

,

ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}

,

ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}

, and

ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}

, respectively, by concerning the proposed LLDF-TOPSIS method through the operators LLDFWAA, LLDFWGA, and distance measures Hamming (

℘ = 1

), Euclidean (

℘ = 2

), and Chebyshev (

℘ = \infty

). Hence, the combined ranking order is

ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}

. It coincides with the original ranking order of the original decision matrix

Λ

of Example 14. Moreover, transitivity property is held for the decomposed ranking order of decomposed sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

. Therefore, the proposed LLDF-TOPSIS method is valid according to test criteria 2 and 3.

5.6. Advantages of the Proposed LLDF-TOPSIS Method

While the concepts of LIFS, LPyFS, and Lq-ROFS can classify objects by linguistic degrees of membership and nonmembership, they cannot allow these objects to be handled with reference/control parameters represented by linguistic variables. The idea of LLDFS proposed in this paper fills this research gap. It centralizes linguistic reference/control parameters in the process of evaluating objects and thus extends existing concepts of LIFS, LPyFS, and Lq-ROFS. On the other hand, the LDFSs have a few obstacles to explicit qualitative arguments on degrees of membership, nonmembership, and reference/control parameters with real numbers. The LLDFSs give a different perspective to existing LDFSs by expressing LDF information based on linguistic variables. This leads to a wider application area of LDFSs (IFSs, PyFSs, q-ROFSs) in practice. Considering all these, it can be said that there is a close relationship between the proposed LLDFSs and multicriteria decision-making problems. The linguistic membership and nonmembership grades, as well as linguistic grades of reference parameters, play an important role in the proposed LLDF-TOPSIS method.
The LLDF-TOPSIS approach is bendy, and without difficulty may be used for exceptional conditions of inputs and outputs. This technique is more bendy than others due to reference parameters and relaxation on degrees with real numbers. It will increase the space of grades and may be variedin step with the exceptional conditions in multicriteria decision-making methods. Consequently, the present techniques on the present notions of LIFSs, LPyFSs, Lq-ROFSs, and LDFSs come to be the unique case of our proposed LLDF-TOPSIS method. In other words, our proposed LLDF-TOPSIS approach is more well known than different current techniques. That is, it improves many decision-making methods based on the LIFS, LPyFS, Lq-ROFS, and LDFS (IFS, PyFS, q-ROFS).

5.7. Disadvantages of the Proposed LLDF-TOPSIS Method

From Table 6 and Table 7, we recognize that our proposed LLDF-TOPSIS method fails for the big parameter ℘ $(℘ \geq 550)$ . However, the use of big parameters ℘ is rare. Thus, we can forget about it.
Our proposed LLDF-TOPSIS approach cannot be carried out for the fuzzy multicriteria decision-making problems concerning impartial membership degrees, bipolarity, and hesitant types.

6. Conclusions

The proposed model and LMCDM issues are shown to be closely related. This link leads to the construction of a modified TOPSIS algorithm to handle uncertainty in multi-attribute data in a parametric way. LMCDM issues are satisfactorily solved by the linguistic linear Diophantine fuzzy TOPSIS (LLDF-TOPSIS) approach, which enhances the TOPSIS methods based on LIFSs, LPyFSs, and Lq-ROFSs. The parameters and special situations of Minkowski-type distances between two LLDFSs were also examined. In the work inspired by LLDFNs, LLDFSs expressed ambiguous evaluation information on linguistic terms specified in linguistic multicriteria decision-making. The LLDF-TOPSIS method was proposed and contrasted with well-known linguistic fuzzy TOPSIS methods for linguistic multicriteria decision-making situations.

The key contributions can be summarized in the following.

(1): The emergence of LLDFSs allows dealing with some special cases where the data collected in LDFS-based evaluations are linguistic terms rather than crisp numbers in the interval [0,1].
(2): Some linguistic linear Diophantine fuzzy aggregation operators discussed in this study conduct the improvement of LLDFSs in both theoretical and practical aspects.
(3): The proposed distance measures of LLDFSs allow coping with many issues such as medical diagnosis, clustering analysis, and pattern recognition in different fields.
(4): The developed LLDF-TOPSIS method enriches fuzzy decision-making theory and provides a new method for decision-makers in the surrounding of LLDFSs (and also LFSs, LIFSs, LPyFSs, and Lq-ROFSs).

In future research, we will investigate the contributions of the proposed aggregation operators and distance measures for problems in other domains, such as multiobjective programming, clustering, uncertain system, and supplier selection. Our efforts will aim to fill this research gap.

Author Contributions

H.K. and M.R. contibuted on methodology, investigation, and writing—original draft preparation. D.M. contributed on investigation, supervision, and funding acquisition. S.P. and S.A. contributed on resources, formal analysis, and data curation. All authors have read and agreed to the published version of the manuscript.

Funding

Support has been received from the German Research Foundation and the TU Berlin.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data used in this manuscript are hypothetical and can be used by anyone by citing this article.

Acknowledgments

The authors wish to acknowledge the support received from the German Re- search Foundation and the TU Berlin.

Conflicts of Interest

The authors declare that they have no conflict of interest regarding the publication of the research article.

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Figure 1. Symmetrical distribution of the eleven linguistic labels of Ł.

Figure 2. Nonsymmetrical distribution of the eleven linguistic labels of Ł.

Figure 3. Comparison view of LIFNs, LPyFNs, Lq-ROFNs, and LLDFNs.

Figure 4. LLDF-TOPSIS ranking for LLDFWAA and LLDFWGA operators via different distances.

Table 1. LDFS for medication.

Alternatives	LDFNs
$ℏ_{1}$	$((0.639, 0.573),$ $(0.671, 0.312))$
$ℏ_{2}$	$((0.867, 0.514),$ $(0.629, 0.234))$
$ℏ_{3}$	$((0.657, 0.867),$ $(0.364, 0.145))$
$ℏ_{4}$	$((0.678, 0.787),$ $(0.243, 0.215))$
$ℏ_{5}$	$((0.876, 0.767),$ $(0.4245, 0.342))$

Table 2. The distance measures of

N_{1}

,

N_{2}

, and

N_{3}

.

Table 2. The distance measures of

N_{1}

,

N_{2}

, and

N_{3}

.

℘	$Δ_{℘}^{dist} (N_{1}, N_{2})$	$Δ_{℘}^{dist} (N_{1}, N_{3})$	$Δ_{℘}^{dist} (N_{2}, N_{3})$
1	1.5	2.5	1
2	1.581138	2.915475	1.870828
3	1.650963	3.286569	2.080083
$3.2$	1.663324	3.351803	2.112964
5	1.751849	3.804925	2.332221
$7.5$	1.824784	4.157340	2.509367
15	1.909687	4.561113	2.735583
∞	2	5	3

Table 3. LLDF assessments of alternatives by provided DM concerning the criteria.

		$c_{1}$	$c_{2}$	$c_{3}$	$c_{4}$	$c_{5}$
d	$ℏ_{1}$	$(〈 ł_{6}, ł_{1} 〉, 〈 ł_{4}, ł_{2} 〉)$	$(〈 ł_{5}, ł_{2} 〉, 〈 ł_{5}, ł_{0} 〉)$	$(〈 ł_{4}, ł_{2} 〉, 〈 ł_{4}, ł_{1} 〉)$	$(〈 ł_{6}, ł_{3} 〉, 〈 ł_{5}, ł_{1} 〉)$	$(〈 ł_{4}, ł_{1} 〉, 〈 ł_{6}, ł_{0} 〉)$
	$ℏ_{2}$	$(〈 ł_{4}, ł_{6} 〉, 〈 ł_{3}, ł_{2} 〉)$	$(〈 ł_{2}, ł_{7} 〉, 〈 ł_{2}, ł_{4} 〉)$	$(〈 ł_{1}, ł_{8} 〉, 〈 ł_{2}, ł_{4} 〉)$	$(〈 ł_{1}, ł_{5} 〉, 〈 ł_{1}, ł_{5} 〉)$	$(〈 ł_{3}, ł_{6} 〉, 〈 ł_{0}, ł_{4} 〉)$
	$ℏ_{3}$	$(〈 ł_{3}, ł_{1} 〉, 〈 ł_{2}, ł_{0} 〉)$	$(〈 ł_{2}, ł_{6} 〉, 〈 ł_{5}, ł_{1} 〉)$	$(〈 ł_{3}, ł_{2} 〉, 〈 ł_{2}, ł_{3} 〉)$	$(〈 ł_{1}, ł_{2} 〉, 〈 ł_{2}, ł_{4} 〉)$	$(〈 ł_{1}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉)$
	$ℏ_{4}$	$(〈 ł_{6}, ł_{4} 〉, 〈 ł_{4}, ł_{1} 〉)$	$(〈 ł_{3}, ł_{2} 〉, 〈 ł_{4}, ł_{2} 〉)$	$(〈 ł_{6}, ł_{3} 〉, 〈 ł_{2}, ł_{1} 〉)$	$(〈 ł_{3}, ł_{4} 〉, 〈 ł_{3}, ł_{0} 〉)$	$(〈 ł_{3}, ł_{2} 〉, 〈 ł_{1}, ł_{2} 〉)$

Table 4. Ranking of LLDF-TOPSIS by concerning LLDFWAA operator for different distances.

℘	Relative Closeness Degree					Ranking Order
1	0.8770978	0.6079344	0.2465916	0.1168285	0.7146982	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
2	0.7839672	0.549701	0.2606163	0.1389751	0.656889	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
∞	0.6829091	0.493465	0.3218475	0.176642	0.6156959	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$

Table 5. Ranking of LLDF-TOPSIS by concerning LLDFWGA operator for different distances.

℘	Relative Closeness Degree					Ranking Order
1	0.9067847	0.0455072	0.0219377	0.00833	0.5488545	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
2	0.8610584	0.0857077	0.0424635	0.0163725	0.5589201	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
∞	0.7990677	0.1297514	0.0670557	0.0265668	0.6113077	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$

Table 6. Sensitivity analysis of proposed LLDF-TOPSIS method by concerning LLDFWAA operator.

℘	Relative Closeness Degree					Ranking Order
1	0.8770978	0.6079344	0.2465916	0.1168285	0.7146982	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
10	0.692612	0.4979212	0.3049491	0.1747861	0.6209107	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
50	0.6830108	0.4934664	0.3216701	0.176642	0.6157014	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
100	0.6829103	0.493465	0.3218461	0.176642	0.6156959	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
500	0.6829091	0.493465	0.3218475	0.176642	0.6156959	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
550	0.6829091	0.493465	0.3218475	0	NaN	Inconsistent
1000	NaN	NaN	0	0	NaN	Inconsistent

In the table, NaN = not a number.

Table 7. Sensitivity analysis of proposed LLDF-TOPSIS method by concerning LLDFWGA operator.

℘	Relative Closeness Degree					Ranking Order
1	0.9067847	0.0455072	0.0219377	0.00833	0.5488545	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
10	0.8030421	0.1281813	0.0661199	0.0261452	0.5994666	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
50	0.7990682	0.1297514	0.0670557	0.0265668	0.6108875	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
100	0.7990677	0.1297514	0.0670557	0.0265668	0.6112875	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
500	0.7990677	0.1297514	0.0670557	0	0.6113077	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
550	0.7990677	0	0	0	0.6113077	Inconsistent
1000	NaN	0	0	0	NaN	Inconsistent

In the table, NaN = not a number.

Table 8. Comparison of the proposed LLDF-TOPSIS method with existing methods.

Problem	Existing Methods	Ranking Order	Proposed LLDF-TOPSIS Method	Ranking Order
Combined Tables 10–12 ( $L D F S$ ) (Riaz, & Hashmi, 2019)	Algorithm 2 ( $S F, E S F$ ) (Riaz, & Hashmi, 2019)	$S_{2} ≻ S_{4} ≻ S_{3} ≻ S_{1}$	$L L D F W A A$ , $L L D F W G A$ $(℘ = 1)$	$S_{2} ≻ S_{4} ≻ S_{3} ≻ S_{1}$
	Algorithm 2 ( $Q S F$ ) (Riaz, & Hashmi, 2019)	$S_{4} ≻ S_{2} ≻ S_{3} ≻ S_{1}$	$L L D F W A A$ , $L L D F W G A$ $(℘ = 2$ , $\infty)$	$S_{2} ≻ S_{4} ≻ S_{1} ≻ S_{3}$
Example 7.2, Table 10 ( $L q - R O F S$ ) (Lin et al., 2020)	$L q R O F W A$ (Lin et al., 2020)	$A_{1} ≻ A_{2} ≻ A_{4} ≻ A_{3}$	$L L D F W A A$ , $L L D F W G A$ $(℘ = 1, 2, \infty)$	$A_{1} ≻ A_{2} ≻ A_{4} ≻ A_{3}$
Example 5.3, Table 5 ( $L I F S$ ) (Garg, & Kumar, 2019)	LIFWG (Zhang, 2014), LIFWPA, LIFWPG (Liu, & Qin, 2017), LCNWG (Garg, 2018b), LIFWA (Chen et al., 2015), LIFEWA (Garg, & Kumar, 2018), ILIFWA (Liu, & Wang, 2017), LCNWPG (Garg, & Kumar, 2019)	$ν_{2} ≻ ν_{3} ≻ ν_{4} ≻ ν_{5} ≻ ν_{1}$	$L L D F W A A$ , $L L D F W G A$ $(℘ = 1, 2, \infty)$	$ν_{2} ≻ ν_{3} ≻ ν_{4} ≻ ν_{5} ≻ ν_{1}$
Illustrative Example ( $L I F S$ ) (Zhang et al., 2017)	EOA (Zhang et al., 2017)	$a_{4} ≻ a_{1} ≻ a_{3} ≻ a_{2}$	$L L D F W A A$ $(℘ = 1, 2, \infty)$ , $L L D F W G A$ $(℘ = 1, 2)$	$a_{4} ≻ a_{1} ≻ a_{3} ≻ a_{2}$
			$L L D F W G A$ $(℘ = \infty)$	$a_{4} ≻ a_{3} ≻ a_{1} ≻ a_{2}$
Example, Table 6 ( $L I F S$ ) (Liu, & Wang, 2017)	ILIFWA (Liu, & Wang, 2017), ILIFWPA (Liu, & Wang, 2017), LIFWA (Chen et al., 2015), LIFWPA (Liu, & Qin, 2017)	$A_{2} ≻ A_{4} ≻ A_{3} ≻ A_{1}$	$L L D F W A A$ , $L L D F W G A$ $(℘ = 1, 2, \infty)$	$A_{2} ≻ A_{4} ≻ A_{1} ≻ A_{3}$
Example 5.5 ( $L I F S$ ) (Garg, & Kumar, 2019)	$G A O$ (Liu, & Qin, 2017), $G A O$ (Chen et al., 2015)	$ν_{1} = ν_{2}$	$L L D F W A A$ $(℘ = 1, 2, \infty)$	$ν_{2} ≻ ν_{1}$
			$L L D F W G A$ $(℘ = 1, 2, \infty)$	$ν_{1} = ν_{2}$

Table 9. Wang–Triantaphyllou’s test criteria to check the validity of decision-making method.

Test Criteria	Description
1	The best alternative should not be changed if any nonoptimal alternative is worsening further without
	interchanging the position of decision-making criteria.
2	Transitive properties should be satisfied by the DM method.
3	If a DM problem is decomposed further, the combined ranking order of the decomposed DM problem
	should be matching with the original DM problem.

Table 11. Ranking of LLDF-TOPSIS by concerning LLDFWGA operator for modified

Λ_{1}^{^{'}}

of Example 14.

Table 11. Ranking of LLDF-TOPSIS by concerning LLDFWGA operator for modified

Λ_{1}^{^{'}}

of Example 14.

℘	Relative Closeness Degree				Modified Ranking Order
1	0.9074373	0.0287855	0.015273	0.5520131	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$
2	0.8619556	0.0553555	0.0298173	0.5608168	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$
∞	0.7990677	0.0867378	0.0479747	0.6113077	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{2}^{^{'}}$

Table 12. Ranking of LLDF-TOPSIS by concerning the different worsened alternatives of Example 14.

Operator	Worsened	℘	Relative Closeness Degree					Modified
	Alternative							Ranking Order
		1	0.8805384	0.6189101	0.0981113	0.1415523	0.722685	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
	$ℏ_{3}^{^{'}}$	2	0.7886395	0.5602136	0.1035499	0.1498834	0.6638354	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
		∞	0.6829091	0.493465	0.1364624	0.176642	0.6245059	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
		1	0.8844572	0.6314113	0.2917056	0.070326	0.731782	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
$L L D F W A A$	$ℏ_{4}^{^{'}}$	2	0.7953105	0.5681692	0.2971628	0.0884888	0.6689092	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
		∞	0.6964529	0.493465	0.3455232	0.1256798	0.6245059	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
		1	0.9607239	0.6818531	0.3074783	0.1730353	0.1228976	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$
	$ℏ_{5}^{^{'}}$	2	0.9258151	0.5919224	0.3090222	0.1976132	0.1319819	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$
		∞	0.8814951	0.5092861	0.3218475	0.2691846	0.1729335	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$
		1	0.914351	0.1229836	0	0.0888241	0.5854741	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
	$ℏ_{3}^{^{'}}$	2	0.8726924	0.2161282	0	0.1618951	0.5890372	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
		∞	0.8151825	0.3048466	0	0.2405407	0.6113077	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{4} ≻ ℏ_{3}^{^{'}}$
		1	0.914351	0.1229836	0.1013273	0	0.5854741	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
$L L D F W G A$	$ℏ_{4}^{^{'}}$	2	0.8726924	0.2161282	0.1822886	0	0.5890372	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
		∞	0.8151825	0.3048466	0.2654133	0	0.6113077	$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}^{^{'}}$
		1	0.9401197	0.1264496	0.1041829	0.0913274	0	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$
	$ℏ_{5}^{^{'}}$	2	0.8896411	0.2223404	0.1875491	0.1665722	0	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$
		∞	0.8321007	0.3209245	0.2802499	0.2544685	0	$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4} ≻ ℏ_{5}^{^{'}}$

Table 13. Ranking of LLDF-TOPSIS for decomposed sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

in Example 14.

Table 13. Ranking of LLDF-TOPSIS for decomposed sub-decision matrices

Λ_{i}

(i = 1 \dots 5)

in Example 14.

Operator	Alternatives of Sub Decision Matrix	℘	Relative Closeness Degree				Decomposed Ranking Order
$L L D F W A A$		1	0.8974024	0.1689318			$ℏ_{1} ≻ ℏ_{2}$
	${ℏ_{1}, ℏ_{2}}$	2	0.8745796	0.1947799			$ℏ_{1} ≻ ℏ_{2}$
		∞	0.8692927	0.1984454			$ℏ_{1} ≻ ℏ_{2}$
		1	0.9814656	0.0311427			$ℏ_{1} ≻ ℏ_{3}$
	${ℏ_{1}, ℏ_{3}}$	2	0.964944	0.0578486			$ℏ_{1} ≻ ℏ_{3}$
		∞	0.942311	0.0932726			$ℏ_{1} ≻ ℏ_{3}$
		1	0.8734156	0.2065581			$ℏ_{2} ≻ ℏ_{3}$
	${ℏ_{2}, ℏ_{3}}$	2	0.8439595	0.189799			$ℏ_{2} ≻ ℏ_{3}$
		∞	0.7966899	0.218296			$ℏ_{2} ≻ ℏ_{3}$
		1	0.9528451	0.6180329	0.1685587		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
	${ℏ_{1}, ℏ_{2}, ℏ_{3}}$	2	0.9126114	0.5370542	0.1803958		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
		∞	0.8692927	0.4434209	0.2033101		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
		1	0.8543184	0.5352665	0.6618184		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
	${ℏ_{1}, ℏ_{2}, ℏ_{5}}$	2	0.7548802	0.4902375	0.5959521		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
		∞	0.6722805	0.4296873	0.5486267		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
		1	0.7311555	0.2965727	0.1405082	0.859559	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
	${ℏ_{2}, ℏ_{3}, ℏ_{4}, ℏ_{5}}$	2	0.6834884	0.2929871	0.1534108	0.7827239	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
		∞	0.6370337	0.3390346	0.176642	0.7191652	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
$L L D F W G A$		1	0.9314519	0			$ℏ_{1} ≻ ℏ_{2}$
	${ℏ_{1}, ℏ_{2}}$	2	0.8744534	0			$ℏ_{1} ≻ ℏ_{2}$
		∞	0.8171302	0			$ℏ_{1} ≻ ℏ_{2}$
		1	0.9655902	0			$ℏ_{1} ≻ ℏ_{3}$
	${ℏ_{1}, ℏ_{3}}$	2	0.9347356	0			$ℏ_{1} ≻ ℏ_{3}$
		∞	0.8998191	0			$ℏ_{1} ≻ ℏ_{3}$
		1	0.1748091	0.0696136			$ℏ_{2} ≻ ℏ_{3}$
	${ℏ_{2}, ℏ_{3}}$	2	0.192474	0.084444			$ℏ_{2} ≻ ℏ_{3}$
		∞	0.1938899	0.087411			$ℏ_{2} ≻ ℏ_{3}$
		1	0.9342374	0.0406366	0.0161826		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
	${ℏ_{1}, ℏ_{2}, ℏ_{3}}$	2	0.8786336	0.0772039	0.031617		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
		∞	0.8171302	0.1214889	0.0521961		$ℏ_{1} ≻ ℏ_{2} ≻ ℏ_{3}$
		1	0.9053393	0.0307077	0.5418594		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
	${ℏ_{1}, ℏ_{2}, ℏ_{5}}$	2	0.8591502	0.0586376	0.5552184		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
		∞	0.7990677	0.090142	0.6113077		$ℏ_{1} ≻ ℏ_{5} ≻ ℏ_{2}$
		1	0.0685769	0.033059	0.0125528	0.8270932	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
	${ℏ_{2}, ℏ_{3}, ℏ_{4}, ℏ_{5}}$	2	0.121811	0.0613379	0.02386	0.8158337	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$
		∞	0.1604973	0.0843859	0.033812	0.8053293	$ℏ_{5} ≻ ℏ_{2} ≻ ℏ_{3} ≻ ℏ_{4}$

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Kamacı, H.; Marinkovic, D.; Petchimuthu, S.; Riaz, M.; Ashraf, S. Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information. Symmetry 2022, 14, 2140. https://doi.org/10.3390/sym14102140

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Kamacı H, Marinkovic D, Petchimuthu S, Riaz M, Ashraf S. Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information. Symmetry. 2022; 14(10):2140. https://doi.org/10.3390/sym14102140

Chicago/Turabian Style

Kamacı, Hüseyin, Dragan Marinkovic, Subramanian Petchimuthu, Muhammad Riaz, and Shahzaib Ashraf. 2022. "Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information" Symmetry 14, no. 10: 2140. https://doi.org/10.3390/sym14102140

APA Style

Kamacı, H., Marinkovic, D., Petchimuthu, S., Riaz, M., & Ashraf, S. (2022). Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information. Symmetry, 14(10), 2140. https://doi.org/10.3390/sym14102140

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Novel Distance-Measures-Based Extended TOPSIS Method under Linguistic Linear Diophantine Fuzzy Information

Abstract

1. Introduction

2. Preliminaries

2.1. Linguistic Term Set

2.2. Linear Diophantine Fuzzy Set

3. Linguistic Linear Diophantine Fuzzy Sets

3.1. Construction of Linguistic Linear Diophantine Fuzzy Set

3.2. Operational Laws for Linguistic Linear Diophantine Fuzzy Sets

3.3. Weighted Aggregation Operators for Linguistic Linear Diophantine Fuzzy Sets

4. Some Distance Measures for Linguistic Linear Diophantine Fuzzy Numbers

5. LLDF-TOPSIS Method with Application in Linguistic Multicriteria Decision-Making

5.1. Linguistic Linear Diophantine Fuzzy TOPSIS Method

5.2. Application of Proposed LLDF-TOPSIS Method to Select the Best Software Consultants

5.3. Sensitivity Analysis of Proposed LLDF-TOPSIS Method

5.4. Comparative Analysis to Show the Superiority of the Proposed LLDF-TOPSIS Method

5.5. Validity of Proposed LLDF-TOPSIS Method

5.5.1. Validity of Proposed LLDF-TOPSIS Method by Test Criterion

5.5.2. Validity of Proposed LLDF-TOPSIS Method by Test Criteria 2 and 3

5.6. Advantages of the Proposed LLDF-TOPSIS Method

5.7. Disadvantages of the Proposed LLDF-TOPSIS Method

6. Conclusions

Author Contributions

Funding

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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