Research Article Enhanced Fuzzy Delphi Method in Forecasting and Decision-Making

The Delphi method is a process where subjective data are transformed into quasi-objective data using statistical analysis and are converged to stable points. The Delphi method was developed by the RAND Corporation at Santa Monica, California, and is widely used for long-range forecasting in management science. It is a method by which the subjective data of experts are made to converge using some statistical analyses. This article proposes a variation of the Delphi method using triangular fuzzy numbers, where the communication method with the experts is the same, but the estimation procedure is diﬀerent. The utility of the method is illustrated by a numerical example.


Introduction
In the Delphi method, experts with high qualifications are first requested to give their opinions separately, without any intercommunication, regarding predicting and realizing certain events in science and technology. en, a statistical analysis is conducted to assess these subjective data, and their first, second, and third quartiles are computed. is statistical information is transmitted to the experts. Furthermore, these new estimates are then analyzed, and the first, second, and third quartiles are recalculated. e new information is sent out to the experts once again, and this process of restoration is continued until the process converges to a reasonable stable solution. Grisham [1] provided project management students with an example of the Delphi research approach applied to a recent doctoral research thesis, reviewed the literature on the Delphi approach, and explained the research method tool. Many authors have dealt with the Delphi method such as Story et al. [2], Kauko and Palmroos [3], Skinner et al. [4], and Beiderbeck et al. and Lawnik and Banasik [5,6]. Piecyk and McKinnon [7] reviewed applications of the method to the field of freight transport and logistics, assessed the usualness of Delphi-derived predictions of long-term freight, and associated environmental trends. ey introduced a case study, the experience of a large two-round Delphi survey undertaken in the UK to elicit projections of long-term trends in a number of road freight and logistics variables. Revez et al. [8] demonstrated the transformative potential of combining participatory action research approaches with a modified Delphi method to understand energy transition issues, particularly beyond forecasting instruments.
In the literature, first of all, Zadeh [9] proposed the philosophy of fuzzy sets. Decision-making in a fuzzy environment, developed by Bellman and Zadeh [10], has been improved, enhancing the management of decision problems. Zimmermann [11] introduced fuzzy programming and linear programming with multiple objective functions. en, several researchers have worked on fuzzy set theory. e theory and applications of fuzzy sets, systems, and fuzzy mathematical models were studied by many authors [12][13][14][15][16][17][18][19]. Cheng et al. [20] investigated a new fuzzy Delphi method (FDM) to fit membership functions and examined the stability of the process of the technique. Roy and Garai [21] used a triangular intuitionistic fuzzy number to introduce a new and improved version of the FDM. Moreover, Habibi et al. [22] applied the FDM to the single round for screening criteria. Hsu et al. [23] summarized the key courses in the education of construction engineers, where the evaluation aspects and index are established using the FDM. Ciptono et al. [24] classified and identified scientific research and analyzed the current literature on the FDM to gain a broad and detailed understanding of education.
Furthermore, He et al. [25] proposed a method to select the proper green supplier successfully. Huang et al. [26] used the FDM to identify the key input variables with the deepest influence on the prediction of peak particle velocity (PPV) based on the expert's opinions and applied the effective parameters on PPV in hybrid artificial neural network-based models, i.e., genetic algorithm, particle swarm optimization, imperialism competitive algorithm, artificial bee colony, and firefly algorithm, for the PPV prediction. Kabir and Sumi [27] proposed a new forecasting mechanism modeled by integrating the FDM with an artificial neural network technique to manage the demand with incomplete information. Many researchers have used the FDM in their works [28][29][30].
is article proposed a variation of the Delphi method using triangular fuzzy numbers, where the communication method with experts is the same, but the estimation procedure is different.
Having motivation from the above literature, in this study, a variation of the Delphi method using triangular fuzzy numbers, where the communication method with the experts is the same, but the estimation procedure is different, is studied. e rest of the paper is outlined as shown in Figure 1.

Preliminaries
In order to easily discuss the problem, the basic rules and findings related to fuzzy sets, fuzzy numbers, triangular fuzzy numbers, and arithmetic operations are recalled.
Definition 1 (see [31]). Let M � X 1 × X 2 × . . . × X n be the Cartesian product, μ i be the fuzzy set in X i , and f: X ⟶ Y be the mapping. en, the fuzzy set A in Y can be defined using the extension principle as follows: Definition 2 (see [31]). Let A and B be two fuzzy sets; the algebraic operations are defined as follows: (1) Addition: A(+)B: (2) (2) Subtraction: A(− )B: Definition 3 (see [9]; fuzzy number). Fuzzy number F is a fuzzy set with a membership function defined as follows.
, satisfying the following: Definition 4 (see [32]). Fuzzy number F � (a, b, c) is called a triangular fuzzy number (TFN) if its membership function is given by and illustrated by Figure 2 [15]. a, b, c) and G � (e, f, g) be two triangular fuzzy numbers. e arithmetic operations on F and G are as follows: (1) Addition:

Notations and Remarks
3.1. Notations. In the FDM, the following notations may be used:

Remarks.
e following important remarks should be noted [15]: (i) A long-range forecasting problem must be considered an uncertain problem but not random. e direct use of the probabilistic methods is not suitable. e use of fuzzy numbers and fuzzy methods seems to be more compatible and well suited.
(ii) e experts use their individual competency and subjectivity, which is why we propose the concepts of fuzzy. (iii) If an expert was asked the following question, Consider the realization of a scientific or technological fact in the near future. What type of dates for its realization would you give? e expert will certainly be more comfortable answering this question using three types of dates: the earliest date, the maximum presumption date, and the latest date, rather than giving an answer regarding the probability of realization. (iv) Using TFNs, it is easy for an expert to study the realization dates, which are nested within each other. (v) e sheaf of fuzzy numbers concept is an aggregation process that appears to be very convenient for the objectification of various subjective opinions.
(vi) Comparisons between expert answers using TFNs are simple, and the distance matrices can be easily computed. is matrix is a dissemblance relation decomposable into similarity relations. Using this approach, finding a nondisjunction subgroup of experts, who are favorable to studies in public opinion, is very convenient. (vii) Many forecasts need multistage processes. By considering the partial and necessary realization, the critical path method can be applied to obtain the composite extremal dates.

Fuzzy Delphi Method
In this section, the steps of the application of the FDM can be explained as follows.
Step 1. e expert i ∈ (1, n) is requested to give a possible realization date (the earliest date, the maximum presumption date, and the latest date) of the project using a TFN: where i indicates the index attached to the expert and 1 indicates that this is the first phase of the forecasting process.
Step 2. e responses from n experts from a sheaf are as follows: e mean of this TFN sheaf is then computed: Moreover, for each expert, the divergence is computed as follows: Section 2 Introduces some preliminaries related to the traingular fuzzy numbers, and its arithematic operarions.

Section 3
Notation and remarks. Section 4 FDMs steps in forecasting and decision-making problems. Section 5 Presented the stability set of the second kind. Section 6 a numerical example is given for illustration. Section 7 Paper is summarized with future directions. where these divergence numbers can be positive, null, or negative in sign. is information is then sent to each individual expert.
Step 3. Each expert now gives a new TFN: Furthermore, the process, starting with phase 2, is repeated.
Step 4. If necessary, a study of partial group opinions is realized using the distance between the TFN and the decomposition of the dissemblance relations in the maximal subrelation of similarity. e information about these results (nonnominative) can be sent to interested experts.
Step 5. When the mean TFN becomes sufficiently stable (i.e., the mean TFN that fixed the solution and decision maker is satisfactory), the process is stopped. Of course, later, if necessary, or if important discoveries or realizations take place, the forecasting can be reevaluated by repeating the process outlined above.

Numerical Example
Consider a technological realization problem of a cognitive information processing computer in the near future. Let us request a group of 12 computer experts to give us a subjective estimation using TFNs to realize this new computing technology. e experts' estimations are listed in Table 1. e computation from this sheaf gives the mean TFN:

(12)
In Figure 3, by comparing (P 1 , Q 1 , R 1 ) with the sheaf (P 1 1 , Q 1 1 , R 1 1 ), the divergence yields is information is given to each expert, and each reconsiders his/her previous forecast and gives a new TFN, thus obtaining a new sheaf. is process is continued until a stable solution according to certain criteria is reached. Of course, the number of such iteration phases can be limited a priori. Many variations of this procedure are possible. For instance, the experts can be advised not to increase the divergence, but this is only a suggestion because an expert must give their own unbiased opinion.

Definition 6.
e normalized distance between two TFNs is defined as follows: where M i and M j are the TFNs given by experts i and j; Δ l and Δ r are the left and right distances, respectively; and c 2 and c 1 are arbitrary values at the right and left, respectively, chosen with the condition δ ∈ [0, 1]. Using formula (14), the results of the computation are inserted in Table 2 for the arbitrary values of c 1 � 2021 and c 2 � 2049.
Let us assume that we are interested in a pair of experts for whom the distance δ(M i , M j ) ≤ 0.15. e matrix in Table 3 gives these pairs. e corresponding pairs are shown in Figure 4.

Discussion of the Results
If we consider δ ≤ 0.20, we find this aggregation directly. In fact, using a convenient algorithm, the problem can be studied with various values of δ, that is, δ ≤ 0.2, 0.25, . . .. If we wish to consider the similarity problem, then a value smaller than (1 − δ) gives the level of similarity, which is an important point in any a posteriori discussion between experts.
e maximal subrelations of similarity in a resemblance relation play the same role as classes in a similarity relation. e second one is always disjointed, but this is not the case for the first one.

Conclusions and Future Works
A variation of the Delphi method using TFNs has been proposed, in which the method of communication with experts is the same, but the estimation procedure is different. Of note, in many cases, a forecasted success requires various steps of operations; therefore, using the critical path method for forecasting is more efficient in such cases. In fact, many other ways can be used for forecasting using fuzzy numbers, which we may investigate in the future. Future work may include the further extension of this study to other fuzzy-like structures, i. e., interval-valued fuzzy set, intuitionistic fuzzy set, Pythagorean fuzzy set, spherical fuzzy set, picture fuzzy set, neutrosophic set, etc., with more discussion on realworld problems.

Data Availability
No data were used to support this study.    Advances in Fuzzy Systems 5