A Multiple Attribute Decision Making Method Based on Uncertain Linguistic Heronian Mean

The Heronian mean is a useful aggregation operator which can capture the interrelationship of the input arguments. In this paper, we develop some Heronian means based on uncertain linguistic variables, such as the generalized uncertain linguistic Heronian mean (GULHM) and uncertain linguistic geometric Heronian mean (ULGHM), and some of their desirable properties are also investigated. Considering the different importance of the input arguments, we define the generalized uncertain linguistic weighted Heronian mean (GULWHM) and uncertain linguistic weighted geometric Heronian mean (ULWGHM). Then, a method of multiple attribute decisionmaking under uncertain linguistic environment is presented based on the GULWHMor theULWGHM. In the end, an example is given to demonstrate the effectiveness and feasibility of the proposed method.


Introduction
Multiple attribute decision making exists here and there, and a multiple attribute decision making problem is to find the most desirable candidate from some feasible alternatives.In real life, decision-makers often provide their preferences on alternatives using linguistic term sets instead of numerical values owing to the fuzziness of human thinking process, and multiple attribute decision making under linguistic environment is a focus in recent years [1][2][3][4][5][6][7][8][9][10][11][12].In the process of decision making, the input arguments need to be aggregated by some proper approaches so that the decision makers can select the most desirable alternative.Among these approaches, the operators are widely used.Yager [13] introduced the ordered weighted averaging (OWA) operator, which has only been used in situations in which the input arguments are the exact numerical values.But now, it has been extended to accommodate linguistic environment [2,[14][15][16][17], uncertain linguistic environment [18][19][20][21][22], and some other preference representation structures [23,24].Uncertain linguistic variable, as a generalization form of linguistic variable, is more powerful in dealing with uncertainty than linguistic variable since it is characterized by a linguistic interval rather than a linguistic value.Since its appearance, the uncertain linguistic variable has received much attention from researchers.Based on the weighted arithmetic averaging (WAA) operator [25] and the ordered weighted averaging (OWA) operator [13], Xu [18] introduced some uncertain linguistic aggregation operators called uncertain linguistic weighted averaging (ULWA) operator, uncertain linguistic ordered weighted averaging (ULOWA) operator, and uncertain linguistic hybrid aggregation (ULHA) operator.The ULWA operator only weights the uncertain linguistic arguments while the ULOWA operator only weights the ordered positions of the uncertain linguistic arguments.The ULHA operator combines the advantages of the ULWA and the ULOWA operator and weights not only the given arguments but also their ordered positions.From a geometric point of view, Xu [20] proposed some uncertain linguistic aggregation operators, such as the uncertain linguistic geometric mean (ULGM), uncertain linguistic weighted geometric mean (ULWGM), and uncertain linguistic ordered weighted geometric (ULOWG) operator.In order to solve the drawbacks of the ULWGM and the ULOWG operator, Wei [21] developed Mathematical Problems in Engineering the uncertain linguistic hybrid geometric mean (ULHGM) operator and proposed an approach to multiple attribute group decision making with uncertain linguistic information based on the ULWGM and ULHGM operators.In [22], Park et al. proposed the uncertain linguistic weighted harmonic mean (ULWHM) operator, uncertain linguistic ordered weighted harmonic mean (ULOWHM) operator, and uncertain linguistic hybrid harmonic mean (ULHHM) operator, and an illustrative example about determining the airconditioning system is also given to demonstrate the effectiveness and feasibility of the proposed method.Motivated by Yager and Filev [26], Xu [27] proposed some induced uncertain linguistic aggregation operators which can aggregate the decision making information in environments of mixing numeric and linguistic variables, such as the induced uncertain linguistic ordered weighted averaging (IULOWA) operator and the induced uncertain linguistic ordered weighted geometric (IULOWG) operator [20].In [28], Xu generalized the IULOWA and the IULOWG operator and developed some generalized induced uncertain linguistic aggregation operators, including the generalized induced uncertain linguistic ordered weighted averaging (GIULOWA) operator and the generalized induced uncertain linguistic ordered weighted geometric (GIULOWG) operator.
However, the above uncertain linguistic aggregation approaches designed for solving multiple attribute decision making problems only consider the importance of the given arguments but ignore the correlation of them.Up to now, we are only aware of one paper on uncertain linguistic decision making that pays attention to the correlation of the input arguments [29].In [29], Wei et al. utilized the uncertain linguistic Bonferroni mean (ULBM) operator and the uncertain linguistic geometric Bonferroni mean (ULGBM) operator which are an extension of the Bonferroni mean (BM) [30] to aggregate the uncertain linguistic arguments.The main advantage of the ULBM and ULGBM is that they can reflect the interrelationship of the input uncertain linguistic arguments.Nevertheless, these two means have their own disadvantages.For example, given a set of attributes   ( = 1, 2, . . ., ), the BM can reflect the correlation between any pair of attributes   and   ( ̸ = ) but neglect the relationship between the attribute   and itself.Moreover, the BM considers the correlation between   and   ( ̸ = ) and the correlation between   and   ( ̸ = ) simultaneously, which results in potential redundancy.In order to solve these issues, we introduce the Heronian mean (HM) [31], the generalized Heronian mean (GHM 1 ) [32], and the geometric Heronian mean (GHM 2 ) [33] and extend them to accommodate uncertain linguistic environment.
To do so, the remainder of this paper is organized as follows.In Section 2, we briefly review some basic concepts, such as the uncertain linguistic variable, HM, GHM 1 , and GHM 2 .In Section 3, we extend these means to accommodate the situation in which the input arguments are uncertain linguistic variables and develop some uncertain linguistic Heronian means, such as generalized uncertain linguistic Heronian mean (GULHM), generalized uncertain linguistic weighted Heronian mean (GULWHM), uncertain linguistic geometric Heronian mean (ULGHM), and uncertain linguistic weighted geometric Heronian mean (ULWGHM).In Section 4, we propose a method for multiple attribute decision making with uncertain linguistic information based on GULWHM or ULWGHM.In Section 5, an example is given to verify the effectiveness and feasibility of the proposed method.Section 6 ends the paper with some concluding remarks.

Uncertain Linguistic Variables and
Heronian Mean It is usually required that there exist the following [7,17,21].
(1) The set is ordered as   ≥   if  ≥ .
To preserve all the given information, the discrete term set  should be extended to a continuous term set  = {  |  1 ≤   ≤   ,  ∈ [1, ]}, where  is a sufficiently large positive integer; if   ∈ , then we call   the original term; otherwise, we call   the virtual term [17,21].The decision maker, in general, uses the original linguistic terms to evaluate alternatives, and the virtual linguistic terms can only appear in operations.
Definition 1 (see [18-22, 27, 28]).Let s = [  ,   ], where   ,   ∈ ,   , and   are the lower and the upper limits, respectively, and then we call s the uncertain linguistic variable.Suppose that  is the set of all uncertain linguistic variables.

Heronian Mean.
Heronian mean (HM), which is one of the aggregation methods, has the desirable characteristic that it can reflect the interrelationship of the input arguments.The definition of HM is as follows.
It is noted that the GHM 1 has the following properties: Example 5. Let  1 ,  2 ,  3 be three nonnegative numbers and  =  = 2; then If we use Bonferroni mean (BM) [30] to aggregate the above three nonnegative numbers, then From the above analysis, we can find that the BM computes Hence, it results in potential redundancy.Moreover, the BM has not paid attention to , and  2 3  2 3 .Nevertheless, the GHM 1 can solve the two problems effectively.Definition 6 (see [33]).Let ,  ≥ 0 and ,  do not take the value 0 simultaneously.Let   ( = 1, 2, . . ., ) be a collection of nonnegative numbers.If then GHM 2 is called the geometric Heronian mean (GHM 2 ).
It is noted that the GHM 2 has the following properties: (1) GHM If we use geometric Bonferroni mean (GBM) proposed by Xia et al. [35] to aggregate the above three nonnegative numbers, then Similar to BM, the GBM also results in potential redundancy.Furthermore, it has not paid attention to ( 1 +  1 ), ( 2 +  2 ), and ( 3 +  3 ).However, the GHM 2 can solve the two problems effectively.

Uncertain Linguistic Heronian Means
3.1.The GULHM and the GULWHM.The GHM 1 has the desirable characteristic capturing the interrelationship of the input arguments.However, the arguments suitable to be aggregated by the GHM 1 usually take the forms of nonnegative real numbers.In this section, we will extend the GHM 1 to accommodate the situations in which the input arguments are uncertain linguistic variables.Based on the operational rules on uncertain linguistic variables and Definition 4, we give the generalized uncertain linguistic Heronian mean (GULWHM) in the following.
In the following, we investigate the desirable properties of the GULHM.
In most cases, the input arguments have their own importance.Each argument should be assigned a weight.Hence, it is necessary to consider the weighted form of the GULHM.In the following, we define the generalized uncertain linguistic weighted Heronian mean (GULWHM).)) then GULWHM is called the generalized uncertain linguistic weighted Heronian mean (GULWHM).If  =  = 1/2; then the GULWHM reduces to )) , which we call the uncertain linguistic weighted Heronian mean (ULWHM).

The ULGHM and the ULWGHM.
The geometric Heronian mean (GHM 2 ) proposed by Yu [33] has the capability to capture the interrelationship among the input arguments.
In this section, we will extend the GHM 2 to accommodate the situations in which the input arguments are uncertain linguistic variables.Based on the operational rules on uncertain linguistic variables and Definition 6, we give the uncertain linguistic geometric Heronian mean (ULGHM) as follows.
In the following, we investigate the desirable properties of the ULGHM, and they can be derived easily.
It is noted that the uncertain linguistic geometric Heronian mean (ULGHM) does not consider the importance of each argument.In the following, we introduce the uncertain linguistic weighted geometric Heronian mean (ULWGHM).
then ULWGHM is called the uncertain linguistic weighted geometric Heronian mean (ULWGHM).If  = , then the ULWGHM reduces to which we call the uncertain linguistic weighted evolution Heronian mean (ULWGHM).

A Method for Multiple Attribute Decision Making Based on Heronian Means under Uncertain Linguistic Environment
In this section, we consider a multiple attribute decision making problem with uncertain linguistic information.The generalized uncertain linguistic weighted Heronian mean (GULWHM) or the uncertain linguistic weighted geometric Heronian mean (ULWGHM) proposed in Section 3 will be used to solve the multiple attribute decision making problem.
Let  = { 1 ,  2 , . . .,   } be the set of alternatives and  = { 1 ,  2 , . . .,   } the set of attributes, whose weight vector is  = ( 1 ,  2 , . . .,   )  such that   ∈ [0, 1], ∑  =1   = 1.The decision makers use the uncertain linguistic variable to provide the linguistic expression under the attribute   for the alternative   and construct the uncertain linguistic decision matrix  = ( d ) × .In the following, based on the GULWHM or the ULWGHM, we develop an approach to multiple attribute decision making with uncertain linguistic information.
Step 1. Utilize the GULWHM as or the ULWGHM as to get the overall attribute value d of the alternative   ( = 1, 2, . . ., ).
Step 3. Rank all the alternatives   and select the desirable one in accordance with the values of d ( = 1, 2, . . ., ).

Example Illustration and Discussion
In this section, an example adapted from [29] is given to illustrate the application of the methods proposed in this paper.

Example Illustration
Example 20 (see [29]).Suppose an organization plans to implement ERP system.The first step is to form a project team that consists of CIO and two senior representatives from user departments.By collecting all possible information about ERP vendors and systems, project team chooses four potential ERP systems   ( = 1, 2, 3, 4) as candidates.The company employs some external professional organizations (or experts) to aid this decision making.The project team selects four attributes to evaluate the alternatives: (1) function and technology  1 , (2) strategic fitness  2 , (3) vendor's ability  3 , and (4) vendor's reputation  4 .Decision makers use the uncertain linguistic variables to evaluate the four possible alternatives   ( = 1, 2, 3, 4) under the above four attributes (whose weight vector is  = (0.2, 0.1, 0.3, 0.4)  ) and construct the uncertain linguistic decision matrix  = ( d ) 4×4 listed in Table 1.
In the following, we use the proposed methods to get the most desirable system.
If we use the ULWGHM to solve the above multiple attribute decision making problem and let  = , then the overall attribute values d of the alternative   ( = 1, 2, 3, 4) can be obtained as follows: d1 = [ 1.30 , To rank these overall attribute values d ( = 1, 2, 3, 4), we first compare each d with all the d ( = 1, 2, 3, 4) by using (2).Then a complementary matrix  = (  ) 4×4 is developed as Summing all the elements in each line of matrix  = (  ) 4×4 , we have Then we rank the overall attribute values d in descending order according to the values of   ( = 1, 2, 3, 4) as d3 ≻ d4 ≻ d2 ≻ d1 .
(47) Rank all the alternatives   in accordance with the values of d ( = 1, 2, 3, 4) as Thus, the most desirable system is  3 and the ranking is the same as obtained by the GULWHM.Here, we will list some of them.From Table 2, we can find that the overall attribute values obtained by the GULWHM become bigger as the parameters  and  increase simultaneously for the same aggregation arguments.If the parameter  is fixed (without loss of generality,  takes the value 1) and the parameter  increases, the overall attribute values obtained by the GULWHM and shown in Table 3 become bigger for the same aggregation arguments.Similarly, if the parameter  is fixed ( = 1), the aggregated results in Table 4 show that the overall attribute values obtained by the GULWHM for the same aggregation arguments firstly experience a decrease and then become bigger as the parameter  increases.The different parameters play an important part in decision making.The decision makers who take a pessimistic view for prospect can choose the smaller values of the parameters  and , while the decision makers who take an optimistic view for prospect can choose the bigger values of the parameters  or .
If we utilize the ULWGHM to aggregate the arguments, some different overall attribute values d of the alternatives   ( = 1, 2, 3, 4) are listed in Tables 5 and 6.If the parameter  is fixed ( = 1), the overall attribute values obtained by the ULWGHM become bigger as the parameter  increases for the same aggregation arguments.If the parameter  is fixed ( = 1), the overall attribute values obtained by the ULWGHM become smaller as the parameter  increases for the same aggregation arguments.Therefore, the decision makers who take a pessimistic view for prospect can choose the smaller values of the parameter  or the bigger values of the parameter , while the decision makers who take an optimistic view for prospect can choose the bigger values of the parameter  or the smaller values of the parameter .From Tables 2 to 6, we can find that the overall attribute values of each alternative derived by the GULWHM or ULWGHM depend on the choice of the parameters  and , but the ranking is kept unchanged.

Concluding Remarks
The Heronian mean can reflect the correlation of the aggregated arguments and is usually used to aggregate the information taken the form of numerical numbers.In this paper, we extend the Heronian mean to accommodate the situation where the input arguments are uncertain linguistic variables and develop some uncertain linguistic Heronian means such as the generalized uncertain linguistic Heronian mean (GULHM) and uncertain linguistic geometric Heronian mean (ULGHM).Some desirable properties of these means such as idempotency, permutation, monotonicity, and boundedness are also discussed.Moreover, to aggregate uncertain linguistic variables and embody different importance of the input arguments, we then define the generalized uncertain linguistic weighted Heronian mean (GULWHM) and uncertain linguistic weighted geometric Heronian mean (ULWGHM).The proposed means take the interrelationship of the input arguments into account, and it is a flexible multiple attribute decision making method in that the decision makers can choose different values of the parameters  and  according to their actual needs.To demonstrate the effectiveness and feasibility of the developed uncertain linguistic Heronian means, an example about ERP system is given.In future research, we will continue to study the Heronian mean, and some other types of Heronian mean will also be investigated.

Table 4 :
Overall attribute values by the GULWHM ,1  and the rankings of the alternatives.

Table 5 :
Overall attribute values by the ULWGHM 1,  and the rankings of the alternatives.If the parameter  or  takes the value of zero, then the GULWHM and ULWGHM cannot capture the interrelationship of the input arguments.Moreover, different overall attribute values d of the alternatives   ( = 1, 2, 3, 4) can be obtained, and it needs much more calculation effort as the parameters  and  change.