In this paper, we focus on the hesitant fuzzy decision-making method based on correlation coefficient under confidence levels. Firstly, we propose several correlation coefficients based on confidence levels, and based on the correlation coefficient between attribute-evaluated values and the ideal values, several optimal attribute weights models are constructed. Secondly, we have defined the concepts of module, weight module, projection, and weighted projection in hesitant fuzzy sets on account of the projection theory. Finally, on the strength of our research results above, we construct a hesitant fuzzy multiattribute decision-making method and apply it to the multiattribute decision-making problem in multisensor electronic reconnaissance. Comparative analyses are made via simulation to test the rationality and validity of the proposed method.
National Statistical Science Foundation of China2019LY29Guangdong Soft Science Project2019A101002062Foundation of Philosophy and Social Sciences in Guangzhou2018GZQN37Characteristic and Innovative Foundation for Humanities and Social Sciences of Education Department of Guangdong Province2018WTSCX0411. Introduction
In the field of multiattribute decision-making, the decision-making process is complex and confuses researchers. Due to different knowledge backgrounds and thinking patterns of decision makers, the degree of membership may vary for the same elements and collections. For example, some people give 0.5, other people give 0.6 or 0.7. Especially, all decision makers insist on their own opinions, and they are deadlocked. To deal with this complex situation, the concept of hesitant fuzzy sets was proposed by Torra et al. [1, 2], which allowed the membership of an element in a given set to be different values. Xu and Xia [3, 4] proposed multiple distance measures for hesitant fuzzy sets. Farhadinia [5] studied the relationship between entropy, similarity measure and distance measure of hesitant fuzzy sets (HFSs), and interval-valued hesitant fuzzy sets (IVHFSs). Zhu et al. [6] and Yu et al. [7] proposed dual hesitant fuzzy sets (DHFSs) and researched the basic operation and characteristics of DHFs. The problem of fuzzy multiattribute group decision-making (MAGDM) with different priorities of attribute and expert was studied by Wei [8]. Yu [9] proposed a hesitant fuzzy multicriteria group decision-making method for performance and development review (PADR) evaluation. Farhadinia [10, 11] presents a series of scoring functions for hesitant fuzzy sets (HFSs) and extended the hesitant fuzzy set (HFS) to its higher order type. Rodriguez et al. [12] present a marvellous overview on hesitant fuzzy sets.
Many classic decision-making methods have been extended to uncertain environments, and some fuzzy multiattribute decision-making methods have been obtained; attribute weights play an important role in summarizing expert assessments in the decision-making process and attracts many researchers’ attention. For example, Xu [13] studied some of the group decision-making problems concerning attribute weight information. Park [14] investigated the group decision-making problems, in which all the information provided by the decision makers is presented in the form of interval-valued intuitionistic fuzzy decision matrices. And fuzzy TOPSIS method under incomplete weight information [15–17], fuzzy ELECTRE II methods [18], fuzzy PROMETHEE method [19], fuzzy VIKOR method [20, 21], fuzzy QUALIFLEX method [22], fuzzy TWO-SIDED MATCHING model [23], etc. It can be said that the research on fuzzy decision-making methods has formed a relatively complete system, which can basically cover decision-making problems in fuzzy environments. However, among these methods, the research on the hesitant fuzzy decision-making method under confidence levels has just started, and the content is less.
In many practical decision-making problems, the evaluation experts are required to provide two types of information such as the performance of the evaluation objects and the familiarity with the evaluation fields (called confidence levels). In this paper, we propose several correlation coefficients based on confidence levels. Then, we have defined the concepts of module, weight module, projection, and weighted projection in hesitant fuzzy sets under confidence levels on account of the projection theory. Finally, we construct a hesitant fuzzy multiattribute decision-making method and apply it to the multiattribute decision-making problem in multisensor electronic reconnaissance.
2. Preliminaries
Zadeh [24] first attempted to use membership function for uncertain information. However, in the decision-making process, because there is a lot of uncertain information, experts usually hesitate for one thing or another, and it is difficult to reach a final consensus, while hesitant fuzzy sets can effectively solve such problems.
Definition 1 (see [1, 2]).
Let X=x1,x2,…,xn be a fixed set; then, a hesitant fuzzy set (HFS) on X is in terms of a function that when applied to X returns a sunset of [0, 1].
For ease of understanding, Xia and Xu [25] represent the HFS with a mathematical symbol:(1)E=<x,hEx>x∈X,where hEx is a set of some values in [0, 1], denoting the possible membership degrees of the element x∈X to the set E. For convenience, Xia and Xu [25] call h=hEx a hesitant fuzzy element (HFE) and H the set of all the HFEs.
In many practical decision-making problems, most existing hesitant fuzzy aggregation operators do not take into account the confidence level of aggregation parameters provided by information providers. Xia and Xu [26] propose a hesitant fuzzy aggregation operator considering absolute confidence levels.
Definition 2 (see [26]).
Let h1,h2,…,hn be a collection of HFSs, li be the confidence levels of HFS hi, and li∈0,1, w=w1,w2,…,wnT be the weight vector of them, such that wi∈0,1,∑i=1nwi=1. If(2)CIHFWAh1,h2,…,hn=⊕i=1nwilihi=∪γ1∈h1,γ2∈h2,…,γn∈hn1−∏i=1n1−liγiwi,then CIHFWA is referred to as confidence-induced hesitant fuzzy weighted averaging (CIHFWA) operator. Peculiarly, if l1=l2=⋯=ln=1, then the CIHFWA operator reduces to the hesitant fuzzy weighted averaging (HFWA) operator:(3)HFWAh1,h2,…,hn=⊕j=1nwjhj=∪γ1∈h1,γ2∈h2,…,γn∈hn1−∏j=1n1−γjwj.
Definition 3 (see [25]).
Suppose h1,h2,…,hn be a collection of hesitant fuzzy sets (HFSs), and let HFOWA be Ωn⟶Ω. The hesitant fuzzy ordered weighted averaging (HFOWA) operator:(4)HFOWAh1,h2,…,hn=⊕j=1nwjhσj=∪γσ1∈hσ1,γσ2∈hσ2,…,γσn∈hσn1−∏j=1n1−γσjwj,where hσj is the jth largest element of hjj=1,2,…,n and w=w1,w2,…,wnT is the aggregation-associated vector such that wj∈0,1,∑j=1nwj=1.
3. Models and Method for Determining the Attribute Weights
In a multiattribute decision-making, the expert group is sometimes asked to provide the weights for selected attributes. At all events, the attribute weights are always incomplete because of the short of knowledge and data and the limitation of decision makers’ expertise and time. Therefore, how to carry out the alternatives sorting by the known information is an interesting and important question. In this section, we propose a method based on the correlation coefficients of HFEs.
3.1. Correlation Coefficients of HFEs
We first introduce the concept of correlation coefficient, then give several correlation coefficient formulas, and discuss their properties.
Definition 4 (see [25]).
For two HFEs h1 and h2, the correlation coefficient of h1 and h2, denoted as Ch1,h2, should satisfy the following properties:(5)1Ch1,h2≤1,2Ch1,h2=1,3Ch1,h2=Ch2,h1.
In most cases, kh1≠kh2, and for convenience, let k=maxkh1,kh2. For proper operation, when comparing them, extend the shorter one to the point where both have the same length. The best way to extend the shorter one is to add a value to it. In fact, we can extend shorter values by adding shorter ones, depending on the DM’s risk appetite. The optimists expect the desired outcome and may increase the maximum, while the pessimists expect the adverse outcome and may increase the minimum.
Based on Definition 4, in [4], the following correlation coefficients for HFEs are given:(6)C1h1,h2=∑j=1kh1σj⋅h2σjmax∑j=1kh1σj2,∑j=1kh2σj2,C2h1,h2=∑j=1kh1σj⋅h2σj∑j=1kh1σj2⋅∑j=1kh2σj21/2,where h1σj and h2σj are the jth largest values in h1 and h2.
We give another correlation coefficient for HFEs:(7)C3h1,h2=∑j=1kh1σj⋅h2σj∑j=1kh1σj2+∑j=1kh2σj2/2.
Although all three formulas satisfy the properties of Definition 4, they each have their own characteristics. We will discuss this issue below.
Theorem 1.
Let h1 and h2 be two HFEs; then,(8)C2h1,h2≤C3h1,h2≤C1h1,h2.
Proof.
Because ab≤a+b/2≤maxa,b,a,b≥0, we can obtain(9)∑j=1kh1σj2⋅∑j=1kh2σj21/2≤∑j=1kh1σj2+∑j=1kh2σj22≤max∑j=1kh1σj2,∑j=1kh2σj2,then(10)∑j=1kh1σj⋅h2σj∑j=1kh1σj2⋅∑j=1kh2σj21/2≤∑j=1kh1σj⋅h2σj∑j=1kh1σj2+∑j=1kh2σj2/2≤∑j=1kh1σj⋅h2σjmax∑j=1kh1σj2,∑j=1kh2σj2.
This completes the proof of Theorem 1.
Considering the importance of the confidence levels, we propose several hesitant fuzzy correlation coefficients based on relative confidence levels and absolute confidence levels and discuss their relationship.
Definition 5.
Let h1 and h2 be two HFEs, k=maxkh1,kh2, and kh1 and kh2 be the length in h1 and h2. Then, we can construct several correlation coefficients under confidence levels for HFEs:(11)Cl1=∑j=1kl1τjh1τjl2τjh2τjmax∑j=1kl1τjh1τj2,∑j=1kl2τjh2τj2,Cl2=∑j=1kl1τjh1τjl2τjh2τj∑j=1kl1τjh1τj2⋅∑j=1kl2τjh2τj21/2,Cl3=∑j=1kl1τjh1τjl2τjh2τj∑j=1kl1τjh1τj2+∑j=1kl2τjh2τj2/2,Cl4=∑j=1kl1τjh1τjl2τjh2τjmax∑j=1kl1τjh1τj2,∑j=1kl2τjh2τj2,Cl5=∑j=1kl1τjh1τjl2τjh2τj∑j=1kl1τjh1τj2⋅∑j=1kl2τjh2τj21/2,Cl6=∑j=1kl1τjh1τjl2τjh2τj∑j=1kl1τjh1τj2+∑j=1kl2τjh2τj2/2,where h1σj and h2σj are the jth largest values in h1 and h2. liτj be the confidence levels of hiτj and liτj∈0,1, and lij=n×liτj/∑i=1kliτj be the relative confidence levels of hiτj and lij∈0,1.
Theorem 2.
Let h1 and h2 be two HFEs, then(12)Cl2h1,h2≤Cl3h1,h2≤Cl1h1,h2,Cl5h1,h2≤Cl6h1,h2≤Cl4h1,h2.
3.2. Models for Determining the Attribute Weights
In real life, there are always some differences between the ideal point of attribute values and the attribute values’ vector corresponding to the alternative Aii=1,2,…,m. We call A∗=a1∗,a2∗,…,an∗ is an ideal selection for attribute values, where aj∗=maxiaij,j=1,2,…,n. We define the correlation C1Ai,A∗. Obviously, the bigger C1Ai,A∗ is, the better the alternative Ai will be. Therefore, a reasonable weight vector w∗=w1∗,w2∗,…,wn∗ should be determined so that all the correlations are as bigger as possible, which means maximizing the following correlation vector [27–29].
under the condition w∈H, where H is the set of the known weight information.
To this end, we set up the following multiobjective optimization model.
Model 2:
(14)max∑i=1m∑j=1nwjC1aij,aj∗s.t.w∈H.
Model 2 can be easily solved by the single-objective programming model; then, we can get the optimal solution w∗=w1∗,w2∗,…,wn∗, which can be used as the weight vector of attributes.
If the information about attribute weights is completely unknown, the following multiobjective programming model can be established.
To solve this model, we construct the Lagrange function:(16)Lw,λ=∑i=1m∑j=1nwjC1aij,aj∗+λ2∑j=1nwj2−1,where λ is the Lagrange multiplier.
Differentiating equation (16) with respect to wjj=1,2,…,n and λ, set these partial derivatives to zero, which gives the following equation:(17)δLwj,λδwj=∑i=1mC1aij,aj∗+λwj=0,δLwj,λδλ=∑j=1nwj2−1=0.
By solving equation (17), we obtain a simple and precise formula to determine the attribute weights as shown below:(18)wj∗=∑i=1mC1aij,aj∗∑j=1n∑i=1mC1aij,aj∗,which can be used as the weight vector of attributes. Apparently, wj∗≥0, for all j.
If C1aij,aj∗ is replaced with formula (4), then we have(19)wj∗=∑i=1m∑j=1kaij⋅aj∗/max∑j=1kaij2,∑j=1kaj∗2∑j=1n∑i=1m∑j=1kaij⋅aj∗/max∑j=1kaij2,∑j=1kaj∗2,j=1,2,…,n.
Through the above analysis, we know that, under the hesitant fuzzy information, both Model 2 and Model 3 can be used to determine attribute weights with incomplete weight information. Model 2 can be used when the weight information is incomplete, and the model can be constructed in various forms. Model 3 can be used when the information about attribute weights is completely unknown, which can be solved easily and obtained as a simple and accurate formula for determining the weight of an attribute [29].
4. Projection Method under Hesitant Fuzzy Environment
Wang [30] proposed a projection method for multiattribute group decision-making, the projection values of evaluation alternatives, and ideal alternatives are used to get the ideal sort. As an excellent measuring tool, the projection method not only reflects the closeness degree between the two objects but also reflects the intrinsic nature of the objects. Now, it is being applied to the decision-making method [31–33]. In this section, we focus on the projection method under hesitant fuzzy environment.
Definition 6 (see [30–33]).
Suppose x=x1,x2,…,xn and y=y1,y2,…,yn are two vectors, then cosine of included angle between vectors x and y can be defined as follows:(20)cosx,y=∑i=1nxiyi∑i=1nxi2∑i=1nyi2.
Evidently, cosine of included angle is in this range: 0<cosx,y≤1, and the larger the value of cosx,y is, the more the direction of vector x and y is consistent.
Definition 7 (see [30–33]).
Suppose x=x1,x2,…,xn, then x=∑i=1nxi2 is a norm of vector x.
A vector consists of two parts, the direction and the norm. The cosine of the angle cosx,y can only measure whether the direction is consistent, but it cannot reflect the magnitude of norm. In order to consider the norm magnitude and cosine of included angle together, the proximity of two vectors can be measured by the projection value, and the definition of projection is given as follows:
Definition 8 (see [30–33]).
Suppose x=x2,x2,…,xn and y=y1,y2,…yn are two vectors, and the projection of vector x onto vector y can be defined:(21)Prjyx=∑i=1nxiyi∑i=1nxi2∑i=1nyi2∑i=1nxi2=∑i=1nxiyi∑i=1nyi2.
Apparently, the larger the value of Prjyx is, the closer the vector x is to the vector y. For the MADM problem, if the vector y obtains a positive ideal solution and the vector x is used for each alternative, we can obtain the projection of each alternative on the positive ideal solution. The larger the projection value is, the better the alternative is.
Now, we extend the projection theory to the hesitant fuzzy sets and give the concepts of the hesitant fuzzy module, weighted module, projection, and weighted projection.
Definition 9 (see [34]).
Suppose H=h1,h2,…,hn be a vector of HFSs; then,(22)H=∑j=1nhj2,is called the module of vector H.
In many cases, the weight of hj should be considered. For example, in the multiple attribute decision-making, sometimes the evaluation experts are asked to provide the weight of every attribute, so we should define the hesitant fuzzy weighted module.
Definition 10 (see [34]).
Let H=h1,h2,…,hn be a vector of HFSs and w=w1,w2,…,wn be the weight vector of hjj=1,2,…,n, such that wj∈0,1,∑j=1nwj=1. Then,(23)Hw=∑i=1nwihi2.is called the weighted module of vector H.
Definition 11 (see [34]).
Suppose H=h1,h2,…,hn and E=e1,e2,…,en be two vectors of HFSs; then, the projection of vector H onto vector E can be defined:(24)PrjEH=∑i=1nhieiE.
Evidently, the larger the value of PrjEH is, the closer the vector H is to the vector E.
Definition 12.
Suppose H=h1,h2,…,hn and E=e1,e2,…,en be two vectors of HFSs. Ew is the weighted module of vector E. Let wi and ti be the weight of hi and ei, such that wi∈0,1,∑i=1nwi=1, ti∈0,1,∑i=1nti=1. Then, the weighted projection of vector H onto vector E can be defined:(25)PrjEwHw=∑i=1nwihitieiEw.
5. An Approach to Multiple Attribute Decision-Making with Hesitant Fuzzy Information under Confidence Levels
Based on the above models, we develop a practical approach to solve the group decision-making problems, where the information about attribute weights is not completely known or completely unknown, and the attribute values take the form of hesitant fuzzy information. The approach includes the following steps:
Step 1: we construct the decision matrix Ak=aijm×nk with confidence levels, where all the arguments aiji=1,2,…,m;j=1,2,…,n are HFSs, given by the decision makers, for the alternative Ai∈A with respect to the attribute Gj∈G, and the decision makers need to give out the confidence levels lk0≤lk≤1k=1,2,…,p.
Step 2: we apply summary operators to aggregate decision makers’ assessments into collective evaluation aiji=1,2,…,m;j=1,2,…,n on each alternative Aii=1,2,…,m.
Step 3: we can get the ideal of attribute values A∗=a1∗,a2∗,…,an∗. If the information about the attribute weights is entirely unknown, then we can get the attribute weights w=w1,w2,…,wnT by using Model 3. If the information about the attribute weights is partly known, then we solve model 2 to obtain the attribute weights w=w1,w2,…,wnT.
Step 4: apply formula (25) to calculate the relative weighted projection PrjAw∗Ai of each alternative Ai:
(26)PrjAw∗Ai=∑j=1nwj2aij⋅aj∗A∗w.
Step 5: rank the alternatives Aii=1,2,…,m according to the relative weighted projection PrjAw∗Ai. The larger the PrjAw∗Ai is, the better the alternative Ai is.
6. Numerical Example
In this section, we apply the proposed hesitant fuzzy multiattribute decision-making method based on signed correlation to multisensor electronic reconnaissance decision problems. In these problems, multiattribute information about the enemy, such as pulse repetition frequency, carrier frequency, power, and pulse width, are detected using various sensors such as Radar, Electronic Support Measures (ESMs), and Infrared, and multiattribute decisions must be made regarding the kind of airborne platform the enemy is using based on these pieces of attribute information. However, in the actual measurement process under a complex electromagnetic environment, the electronic reconnaissance equipment is often interfered by air clutter and enemy signals, which causes a certain degree of information uncertainty that is in line with the characteristics of HFEs. Thus, it is more appropriate to describe these attribute decisions using HFE [35].
Assume that four types of airborne platform (i.e., Aii=1,2,3,4) are present based on the information transmitted by each electronic reconnaissance sensor to the fusion center and that each type of airborne platform has four types of attribute, i.e., pulse repetition frequency (G1), carrier frequency (G2), power (G3), and pulse width (G4). The fusion center must perform multiattribute fusion judgment on the four types of airborne platform with uncertainty based on the four attribute types. The electronic reconnaissance equipment measures the value of each attribute Gj∈G of each scheme Ai∈A, which forms a matrix based on hesitant fuzzy information. (H=hijm×n).
To obtain the type of airborne platform, the specific multiattribute decision-making steps are as follows:
Step 1: decision makers assess the alternatives Aii=1,2,3,4 with respect to the attributes Gjj=1,2,3,4, and the decision makers give the confidence levels lp0≤lp≤1. Then, we set up the following hesitant fuzzy decision matrix Ap=aij4×4p, andd the first components in the two types of information are the confidence levels (see Table 1).
Step 2: apply the CIHFHA operator to aggregate all the hesitant fuzzy decision matrix Ap=aij4×4p into the aggregate hesitant fuzzy decision matrix A=aiji=1,2,3,4;j=1,2,3,4 (see Table 2).
Step 3: we can obtain the ideal of attribute values A∗=0.36,0.39,0.38,0.39. Because the information about the attribute weights is entirely unknown, we can get the attribute weights t=0.24,0.23,0.27,0.26T by using Model 3.
Step 4: use formula (25) to calculate the relative weighted projection PrjAw∗Ai of each alternative Ai:
Step 5: rank the alternatives Aii=1,2,3,4 according to the relative weighted projection PrjAw∗Ai:
(28)PrjAw∗A1≻PrjAw∗A3≻PrjAw∗A2≻PrjAw∗A4,so the airborne platform type is A1.
Hesitant fuzzy decision matrix under confidence levels.
G1
G2
G3
G4
A1
{(0.7,0.5),(0.3,0.7)}
{(0.7,0.6),(0.5,0.7)}
{(0.6,0.5),(0.7,0.6),(0.5,0.8)}
{(0.8,0.4),(0.7,0.5)}
A2
{(0.8,0.3),(0.6,0.4)}
{(0.6,0.4),(0.4,0.7)}
{(0.7,0.4),(0.6,0.6)}
{(0.9,0.4),(0.7,0.5),(0.6,0.6)}
A3
{(0.7,0.6),(0.5,0.7),(0.4,0.8)}
{(0.7,0.4),(0.4,0.6)}
{(0.5,0.8),(0.3,0.9)}
{(0.4,0.8),(0.5,0.9)}
A4
{(0.7,0.4),(0.5,0.6)}
{(0.6,0.5),(0.4,0.7),(0.3,0.9)}
{(0.5,0.4),(0.6,0.7)}
{(0.6,0.5),(0.4,0.6)}
Comprehensive hesitant fuzzy decision matrix A.
G1
G2
G3
G4
A1
0.28
0.39
0.38
0.34
A2
0.24
0.26
0.32
0.36
A3
0.36
0.26
0.34
0.39
A4
0.29
0.28
0.32
0.27
If we do with the HFWA operator to aggregate the hesitant fuzzy decision matrix without considering the confidence levels, the main steps are as follows:
Step 1’: decision makers evaluate the alternatives Aj′i=1,2,3,4 with respect to the attributes Gj′j=1,2,3,4 without considering the confidence levels. Then, we construct the following hesitant fuzzy decision matrix A′=aij4×4′ (see Table 3).
Step 2’: employ the HFWA operator to aggregate all the hesitant fuzzy decision matrices A′=aij4×4′ into the collective hesitant fuzzy decision matrix A′=aij′i=1,2,3,4;j=1,2,3,4 (see Table 4).
Step 3’: we can obtain the ideal of attribute values A′∗=0.71,0.75,0.86,0.86. Because the information about the attribute weights is entirely unknown, we can get the attribute weights t′=0.25,0.27,0.25,0.23T by using Model 3.
Step 4’: use formula (25) to calculate the relative weighted projection PrjAw′∗Ai′ of each alternative Ai':
Step 5’: rank the alternatives Ai′i=1,2,3,4 according to the relative weighted projection PrjAw′∗Ai′:
(30)PrjAw′∗A3′≻PrjAw′∗A1′=PrjAw′∗A4′≻PrjAw′∗A2′,so the airborne platform type is A3.
Hesitant fuzzy decision matrix A (‘).
G1
G2
G3
G4
A1
{0.5,0.7}
{0.6,0.7}
{0.5,0.6,0.8}
{0.4,0.5}
A2
{0.3,0.4}
{0.4,0.7}
{0.4,0.6}
{0.4,0.5,0.6}
A3
{0.6,0.7,0.8}
{0.4,0.6}
{0.8,0.9}
{0.8,0.9}
A4
{0.4,0.6}
{0.5,0.7,0.9}
{0.4,0.7}
{0.5,0.6}
Comprehensive hesitant fuzzy decision matrix A’.
G1
G2
G3
G4
A1
0.61
0.65
0.66
0.45
A2
0.35
0.58
0.51
0.51
A3
0.71
0.51
0.86
0.86
A4
0.51
0.75
0.58
0.55
If we do with the HFGA operator to aggregate the hesitant fuzzy decision matrix without considering the confidence levels, the main steps are as follows:
Step 1”: decision makers evaluate the alternatives Ai′i=1,2,3,4 with respect to the attributes Gj′j=1,2,3,4 without considering the confidence levels. Then, we construct the following hesitant fuzzy decision matrix A′=aij4×4′(see Table 3).
Step 2”: employ the HFGA operator to aggregate all the hesitant fuzzy decision matrices A′=aij4×4′ into the collective hesitant fuzzy decision matrix A″=aij″i=1,2,3,4;j=1,2,3,4 (see Table 5).
Step 3”: we can obtain the ideal of attribute values A″∗=0.70,0.68,0.85,0.85. Because the information about the attribute weights is entirely unknown, we can get the attribute weights t′=0.25,0.28,0.24,0.23T by using Model 3.
Step 4”: use formula (25) to calculate the relative weighted projection PrjAw″∗Ai″ of each alternative Ai″:
Step 5”: rank the alternatives Ai″i=1,2,3,4 according to the relative weighted projection PrjAw″∗Ai″:
(32)PrjAw″∗A3″≻PrjAw″∗A1″=PrjAw″∗A4″≻PrjAw″∗A2″,so the airborne platform type is A3.
Comprehensive hesitant fuzzy decision matrix A”.
G1
G2
G3
G4
A1
0.59
0.65
0.62
0.45
A2
0.35
0.53
0.49
0.49
A3
0.70
0.49
0.85
0.85
A4
0.49
0.68
0.53
0.55
If we do not consider the factor of confidence levels, our proposed operators are simplified to the existing hesitant fuzzy aggregation operators. Nevertheless, the experts’ group is completely unaware of the alternatives so that the results are different. In view of these situations, the hesitant fuzzy aggregation operators at the confidence levels proposed in this paper are useful tools. As can be seen from the above analysis, compared with the traditional hesitant fuzzy decision-making methods, the main advantages of our methods are not only that they can adapt to the hesitant fuzzy environment but also that they take into account the confidence levels between decision makers, which makes more feasibility and practicality.
7. Conclusion
In this paper, a new decision analysis method under confidence levels is proposed for decision-making (MADM) problems where attribute values are in the form of hesitant fuzzy numbers and unknown attribute weights. Firstly, several hesitant fuzzy correlation coefficient based on confidence levels are proposed. Secondly, some simple optimization models based on the correlation coefficients under confidence levels for HFEs are used to determine the attribute weight, and the projection method for HFEs is proposed. Finally, a numerical example is used to illustrate the practicability and effectiveness of the method. The results show that the main advantages of the decision analysis methods under confidence levels are not only that they can adapt to the hesitant fuzzy environment but also that they take into account the confidence levels between decision makers, which makes the results more feasibility and practicality. However, expert credibility needs expert’s subjective judgment, and there will be some errors in decision-making problems. In the future work, we will try our best to correct expert credibility and study probabilistic hesitant fuzzy environment under confidence levels [36, 37].
Data Availability
All data included in this study are available from the corresponding author upon request. Most of the data are already in the article.
Conflicts of Interest
The authors declare that there are no conflicts of interest regarding the publication of this paper.
Acknowledgments
This research was supported by the National Statistical Science Foundation of China (no. 2019LY29), the Guangdong Soft Science Project (no. 2019A101002062), the Foundation of Philosophy and Social Sciences in Guangzhou (no. 2018GZQN37), and the Characteristic and Innovative Foundation for Humanities and Social Sciences of Education Department of Guangdong Province (no. 2018WTSCX041).
TorraV.Hesitant fuzzy sets2010256529539TorraV.NarukawaY.On hesitant fuzzy sets and decisionProceedings of the 18th IEEE International Conference on Fuzzy SystemsAugust 2009Jeju Island, South Korea1378138210.1109/fuzzy.2009.52768842-s2.0-71249127154XuZ.XiaM.Distance and similarity measures for hesitant fuzzy sets2011181112128213810.1016/j.ins.2011.01.0282-s2.0-79952823793XuZ.XiaM.On distance and correlation measures of hesitant fuzzy information201126541042510.1002/int.204742-s2.0-79952846411FarhadiniaB.Information measures for hesitant fuzzy sets and interval-valued hesitant fuzzy sets20132401012914410.1016/j.ins.2013.03.0342-s2.0-84877716864ZhuB.XuZ.XiaM.Dual hesitant fuzzy sets201220121387962910.1155/2012/8796292-s2.0-84862291231YuD.LiD.-F.MerigóJ. M.Dual hesitant fuzzy group decision making method and its application to supplier selection20167581983110.1007/s13042-015-0400-32-s2.0-84988416280WeiG.Hesitant fuzzy prioritized operators and their application to multiple attribute decision making20123117618210.1016/j.knosys.2012.03.0112-s2.0-84859891688YuD.Some hesitant fuzzy information aggregation operators based on einstein operational laws201429432034010.1002/int.216362-s2.0-84894492365FarhadiniaB.A series of score functions for hesitant fuzzy sets201427710211010.1016/j.ins.2014.02.0092-s2.0-84901780993FarhadiniaB.Distance and similarity measures for higher order hesitant fuzzy sets201455434810.1016/j.knosys.2013.10.0082-s2.0-84888306319RodríguezR. M.MartínezL.TorraV.XuZ. S.HerreraF.Hesitant fuzzy sets: state of the art and future directions201429649552410.1002/int.216542-s2.0-84898947675XuZ.Multi-person multi-attribute decision making models under intuitionistic fuzzy environment20076322123610.1007/s10700-007-9009-72-s2.0-34848833546ParkD. G.KwunY. C.ParkJ. H.Correlation coefficient of interval-valued intuitionistic fuzzy sets and its application to multiple attribute group decision making problems2009509-101279129310.1016/j.mcm.2009.06.0102-s2.0-70349472932XuZ.ZhangX.Hesitant fuzzy multi-attribute decision making based on TOPSIS with incomplete weight information201352536410.1016/j.knosys.2013.05.0112-s2.0-84883855065ZengS.ChenS.-M.FanK.-Y.Interval-valued intuitionistic fuzzy multiple attribute decision making based on nonlinear programming methodology and TOPSIS method202050642444210.1016/j.ins.2019.08.027ZengS.LuoD.ZhangC.LiX.A correlation-based TOPSIS method for multiple attribute decision making with single-valued neutrosophic information202019134335810.1142/s0219622019500512ChenN.XuZ.Hesitant fuzzy ELECTRE II approach: a new way to handle multi-criteria decision making problems201529217519710.1016/j.ins.2014.08.0542-s2.0-84922639654MahmoudiA.Sadi-NezhadS.MakuiA.VakiliM. R.An extension on PROMETHEE based on the typical hesitant fuzzy sets to solve multi-attribute decision-making problem20164581213123110.1108/k-10-2015-02712-s2.0-84991628237ZengS.ChenS.-M.KuoL.-W.Multiattribute decision making based on novel score function of intuitionistic fuzzy values and modified VIKOR method2019488769210.1016/j.ins.2019.03.0182-s2.0-85062878830LiaoH.XuZ.A VIKOR-based method for hesitant fuzzy multi-criteria decision making201312437339210.1007/s10700-013-9162-02-s2.0-84888199005ZhangX.XuZ.Hesitant fuzzy QUALIFLEX approach with a signed distance-based comparison method for multiple criteria decision analysis201542287388410.1016/j.eswa.2014.08.0562-s2.0-84907483680YuD.XuZ.Intuitionistic fuzzy two-sided matching model and its application to personnel-position matching problems202071231232110.1080/01605682.2018.15466622-s2.0-85061455917ZadehL. A.Fuzzy sets19658333835310.1016/s0019-9958(65)90241-x2-s2.0-34248666540XiaM.XuZ.Hesitant fuzzy information aggregation in decision making201152339540710.1016/j.ijar.2010.09.0022-s2.0-79551684086XiaM.XuZ.ChenN.Induced aggregation under confidence levels201119220122710.1142/s02184885110069762-s2.0-79953713678LiuX. D.ZuJ. J.ZhangS. T.Hesitant fuzzy decision making method with confidence levels and preference information on alternatives201436713681373FrenchS.1983New York, NY, USAAcademic PressXuZ.A method for multiple attribute decision making with incomplete weight information in linguistic setting200720871972510.1016/j.knosys.2006.10.0022-s2.0-35848935621WangY. M.A new method for multindicies decision and evaluation—a projection method199921314WeiW. G.Project method for multiple attribute group decision making in two-tuple linguistic setting20091855963YueZ. L.Approach to group decision making based on determining the weights of experts by using projection method20123862900291010.1016/j.apm.2011.09.0682-s2.0-84856951403ZhangX.JinF.LiuP.A grey relational projection method for multi-attribute decision making based on intuitionistic trapezoidal fuzzy number20133753467347710.1016/j.apm.2012.08.0122-s2.0-84872492424RuanC. Y.2016Guangzhou, ChinaSouth China University of TechnologyXuJ. Y.SunG. D.ZhaoJ.Novel correlation coefficients between hesitant fuzzy sets and their applications in multi-attribute decision making201846613271335LiJ.WangZ.-x.Multi-attribute decision making based on prioritized operators under probabilistic hesitant fuzzy environments201923113853386810.1007/s00500-018-3047-72-s2.0-85042129353RuanC. Y.YangJ. H.HanL. N.LiuR. B.Hesitant fuzzy decision making method with confidence levels and preference relations on attributes2016253125131