This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

A man makes numerous decisions in his daily life courses where he has multiple choices having various features, no doubt such circumstances hinder the certainty of his accurate decisions. To make the decisions worthy and acceptable, there was a need for some decision-making techniques that enable a man to pass through all the hurdles in the path of making the accurate decisions. There are many types of decision-making techniques, like multicriteria group decision making (MCGDM) technique where we have multiple attributes of the alternatives and a panel of experts is being selected to analyze the alternatives. Several scholars, including [1–4] have developed numerous MCGDM techniques and methods to account for the multiplicity of sources of information, but there are some deficiencies in these methods as some are useful in dealing with multipolarity and some with two-dimensional data. The widespread utilization of MCGDM techniques in medical, engineering, social sciences, robotics and many other areas of science and technology have made these techniques notable and admirable [5–8]. To manipulate the unambiguous consequences of the human commitments, complexity and the multipolarity of the modern era, we put forward a novel MCGDM technique, namely, CmPFNS-TOPSIS that embraces the complex two-dimensional data and the multipolar information, shares the burden of making the apt decisions in the daily routine tasks.

The classical MCGDM techniques integrate the evaluations and the data in a crisp form, including TOPSIS [9], VIKOR [7], ELECTRE [10], analytic hierarchy process (AHP) [11] and PROMETHEE [12]. All these techniques deal with the membership values 0 and 1. Since there are no such words like exact or certain in the daily routine tasks, the scientists looked forward towards the vagueness and uncertainty of human nature. In this scenario, Zadeh’s fuzzy set [13] proved as a hallmark in characterizing the ambiguous nature of human obligations. Chen [4] extended the classical TOPSIS technique to the fuzzy TOPSIS to operate in the uncertain and ambiguous environment. It revolutionized the decision-making abilities by considering the fuzziness of the present time. Torlak et al. [8] employed the fuzzy TOPSIS method to rank the domestic airlines in Turkey. Lately, Chu and Kysely [5] implemented the fuzzy TOPSIS in ranking the objectives in the advertisements in Facebook. Furthermore, Li et al. [6] implemented the fuzzy TOPSIS method to investigate the service quality of Beijing metro system by using trapezoidal fuzzy numbers. Chen et al. [1] developed the concept of the m-polar fuzzy set to highlight the prominence of the multipolarity of the modern world. The world is getting complex day-by-day, Ramot et al. [14] put forward the notion of complex fuzzy set in order to tackle the complex two-dimensional data.

In a different vein, soft set theory [15] is concerned with a setup where the subsets of a universal set are described by their fulfilment of various attributes. It is said that soft sets produce a parameterized family of subsets, indexed by the required parameters. Because the parameters that describe the alternatives often have an intrinsically fuzzy nature (like expensive, beautiful, famous, et cetera), natural extensions of soft set theory for this case have been formalized by Maji et al. [16] or Alcantud et al. [17], who also produced an application to the valuation of assets. However, the widespread utilization of rating systems regarding games, hotels, rental rooms, movies, et cetera, called for an updated version of soft sets, independent of a fuzzy description of the attributes. Fatimah et al. [4] thus initiated the concept of N-soft set as a generalization of the primitive soft set model. It soon became a trendy topic due to its applicability, and also because it was successfully merged with the idea of fuzziness and vagueness from multiple perspectives. Let us give a short sample of recent extensions. Akram et al. [8] combined fuzzy set and N-soft set theory and put forward the concept of fuzzy N-soft set. Fuzzy N-soft sets were further extended by Akram et al. [5] who put forward the theory of m-polar fuzzy N-soft sets (mFNSS). They proved their versatility by quoting applications in routine tasks like the selection of a hotel, resort, restaurant and laptop. Fatimah and Alcantud [18] insisted on the multifuzzy abilities of N-soft sets and their applications. Many other extensions exist that incorporate for example, the traits of hesitancy [19]. Eraslan and Karaaslan [3] extended the TOPSIS method under fuzzy soft information and illustrated its application for house selection. By adding up the N ordered grades in the fuzzy soft set theory, Akram et al. [1,20] put forward the concept of fuzzy N soft set and m-polar fuzzy N soft set (mFNSS), proved their credibility by quoting the examples of daily routine tasks, like selection of a hotel, resort, restaurant and laptop. Fatimah and Alcantud [18] insisted on the multifuzzy abilities of N-soft sets and their applications. Many other extensions exist that incorporate for example, the traits of hesitancy [21] or roughness [22].

As the world is evolving day-by-day, becoming more complex by embracing the multipolarity, so in order to face the multipolarity and the complexity of the two-dimensional data at the same time, Akram [23] and Sultan [14,24,25] come up with a novel hybrid model, namely, complex m-polar fuzzy N soft set (CmPFNSS) that indexed the m-polar information as well as the complex two-dimensional data. The very general structure of (CmPFNSS) is benefited with both the multipolarity of mFNS) and the ability of dealing with complex two-dimensional data of the complex fuzzy set simultaneously. Therefore, there is a dire need of some MCGDM technique that enhances our decision-making abilities while facing the multipolar information and the complex two-dimensional data all together. To meet this imperative demand, a very general MCGDM technique, namely, CmPFNS-TOPSIS is introduced in this article along with the flow-chart of its algorithm, a case study of selecting the suitable surgical equipment for the oncology department of the Shaukhat Khanum Hospital, Lahore and a comparative analysis of CmPFNS-TOPSIS with the m-polar fuzzy N-soft TOPSIS representing by a bar-chart to prove its credibility and validity. The main factors that encourage us to come up with the novel CmPFNS-TOPSIS are as follows:

(i) The mFNS-TOPSIS excels in dealing with multipolarity of the modern era, but as the world is getting more and more complex so this technique impedes in tackling with the complex two-dimensional data and proved to be in sufficient in making the right decisions while facing with the complexity of the present time.

Encouraged by all these facts, we manifest a novel hybrid decision-making strategy, namely, CmPFNS-TOPSIS that assimilates the astonishing features of CmPFNS and spectacular aspects of the fuzzy TOPSIS. This impressive technique is manifested with the principle of finding the optimal solution nearest to the positive ideal solution (PIS) and farthest from the negative ideal solution (NIS) by calculating the Euclidean distance between the alternatives and the ideal solutions. This technique is quite helpful in the ordered grading of the alternatives and considering the benefit-type as well as cost-type criteria. We illustrated its methodology by considering a case study of the selection of the surgical equipment in the oncology department of the Shaukat Khanum Hospital, Lahore. A very comprehensive comparative analysis between CmPFNS-TOPSIS and mFNS-TOPSIS is being pictured with the help of a bar-chart to depict its credibility.

The most notable contributions made in this research article are as follows:

(i) This research article depicts the hybrid extension of the TOPSIS under the CmPFNS environment that can easily take care of the multipolar information and the complex two-dimensional data, enabling us to make the most accurate decisions in the daily routine tasks

This research article is organized as follows: Section 2 comprises of the preliminaries to remind our previous knowledge. Section 3 includes the algorithm of the working mechanism of the novel hybrid decision-making strategy, CmPFNS-TOPSIS. Section 4 is composed of the case study of the selection of the best surgical equipment for the oncology department in Shaukhat Khanum Hospital, Lahore. Section 5 covers a very comprehensive algorithm of the working principle of the mFNS-TOPSIS. Section 6 provides a detailed comparison between CmPFNS-TOPSIS and Mfns-TOPSIS to prove the credibility of the CmPFNS-TOPSIS. Section 7 concludes the research article.

2. Complex M-polar Fuzzy N-Soft Sets

In this section, some basic concepts of complex m-polar fuzzy N-soft sets CmPFNS are presented for the better understanding of the concepts.

3. Why Do We Need a Novel Hybrid Model CmPFNSS?

This section facilitates us with the answer to the question that why do we need a novel hybrid model, CmPFNSS? A detailed discussion is entailed in this section, by considering the natural phenomena occur on earth called volcanic eruption, that how our proposed set can be beneficial in studying and predicting these eruptions so that a lot of damage can be prevented timely as a result of the volcanic explosions.

3.1. Factors on Which Volcanic Eruption Depends

The dynamical nature of the earth is a result of the natural phenomenon occurring inside the earth’s crust called “volcanic eruption.” When the magmastatic pressure crosses a certain level inside the earth’s crust the lava erupts from the volcanoes, causes a huge loss of lives and becomes a major source of destruction. Therefore, it is imperative to predict the occurrence of this phenomenon timely so that millions of lives could be saved.

The volcanic eruption depends on various factors or attributes like level of atmospheric pressure, geological factors, change in climatic conditions, pressure inside the earth’s crust that further depends on the $m$-poles giving multipolar information including density of ocean, margins between tectonic plates, density of magma, lithostatic pressure, land sliding on mountains, melting of glaciers, presence of acidic gases and dissolved components like sulphur and water inside the earth’s crust. The major factors cause the volcanic eruption are pictured in Figure 1, (https://kidspressmagazine.com/science-for-kids/misc/misc/volcanic-eruptions-2.html).

[figure(s) omitted; refer to PDF]

3.2. Role of CmPFNSS in Volcanic Eruption

The question arises that how our proposed hybrid model CmPFNSS is beneficial in studying and predicting this natural phenomenon? The very dual nature of CmPFNSS of dealing with multipolar information, complex two-dimensional data and the $N$-grading enables us to be benefitted in this scenario. All the aforementioned multipolar information exhibits not only the amplitude term but also depends on the phase (time) term. For example, melting of glaciers is one of the $m$-poles responsible for the volcanic eruption and this melting definitely depends on time. Similarly, pressure density, landsliding, ocean density of ocean etc all varies with respect to time. To deal with all these multipolar complex two-dimensional data, CmPFNSS is proved to be a helping hand where $N$-grading shows the relative importance of the $m$-poles. Consider a C3PFNSS as $B=j,\mathrm{5,0.9}{e}^{2\pi \iota 0.3},0.72e^{2\pi \iota 0.45},0.19e^{2\pi \iota 0.82}$, where $j$ represents the atmospheric pressure, grade 5 shows its relative importance, and the complex membership degrees $0.9e^{2\pi \iota 0.3},0.72e^{2\pi \iota 0.45},0.19e^{2\pi \iota 0.82}$ show the amplitude and phase term of the lithostatic pressure, magmastatic pressure and density of magma. Hence, this natural phenomenon can be thoroughly examined by utilizing the proposed hybrid model CmPFNSS.

3.3. Superiority of CmPFNSS over the Existing Ones

No doubt, the fuzzy sets system is equipped with numerous worthy sets or models that are proved to be of great assistance with their remarkable features but our proposed hybrid model excelled from them in all aspects. As $m$-polar fuzzy set [29] deals only with multipolar information, but not with complex two-dimensional data and $N$-grading. Akram et al. [20] introduced the fuzzy $N$-soft set that handles the $N$-grading but fails to tackle multipolar complex two-dimensional data. The notion of $m$-polar fuzzy $N$-soft set was put forward by Akram et al. [1] that addresses the multipolar information with $N$-grading but collapses when we have complex two-dimensional data. To overcome this hurdle, Ramot et al. [14] gave the concept of a complex fuzzy set that can easily handle the complex two dimensional data but fails to deal with multipolarity with $N$-grading. Hence, in order to occupy the complexity of multipolar information with $N$-grading, Akram and Sultan introduced the concept of CmPFNSS that covers all the aspects of multipolar complex two-dimensional data with $N$-grading. In the phenomenon of volcanic eruption, CmPFNSS provides us with the most useful, realistic and practical information.

4. CmPFNS-TOPSIS Technique for MCGDM

In this section, each and every step of CmPFNS-TOPSIS technique has been explained in detail, so that we have a better on-look upon the strategy being used in performing this technique. The motive of this technique is to calculate the Euclidean distance of each alternative from the positive ideal solution $PIS$ and the negative ideal solution $NIS$ with respect to each alternative, where $PIS$ deals with benefit-type criteria and $NIS$ deals with cost-type criteria. At the end, by computing the relative closeness index, the best alternative along with the rankings of all alternatives has been selected. The algorithm of CmPFNS-TOPSIS technique can be su $m$-up in the following steps:

4.1. Construction of Independent Decision Matrices of Each Expert

Since the technique under consideration is CmPFNS-TOPSIS technique, where each decision-making expert $\mathrm{\Psi }={\psi }_h,h=\mathrm{1,2},\dots ,l$ allots the N-grades and membership degrees to each alternative $\mathrm{\Omega }={\omega }_p,p=\mathrm{1,2},\dots ,r$ with respect to the decision attributes $\mathrm{\Phi }={\varphi }_t,t=\mathrm{1,2},\dots ,q$ that depend on the complex $m$-polar decision criteria ${\rho }_i°\mu e^{2\pi \iota {\alpha }_i},i=\mathrm{1,2},\dots ,m$. The result is evaluated in the form of a complex $m$-polar fuzzy N-soft decision matrix ${\Im }^{h^i}={{\xi }_{pt}^h}_{r\times q}$, where ${\xi }_{pt}^h=d_{pt},{\xi }_{pt}^{h^1},{\xi }_{pt}^{h^2},\dots ,{\xi }_{pt}^{h^m}$, and ${\xi }_{pt}^{h^i}={\rho }_{pt}^{h^1}°\mu e^{2\pi \iota {\alpha }_{pt}^{h^1}},{\rho }_{pt}^{h^2}°\mu e^{2\pi \iota {\alpha }_{pt}^{h^2}},\dots ,{\rho }_{pt}^{h^m}°\mu e^{2\pi \iota {\alpha }_{pt}^{h^m}},i=\mathrm{1,2},\dots ,m$.$$\begin{array}{}\text{(3)}& {\Im }^{h^i}=\begin{array}{cccc}{d}_{11}^h,{\xi }_{11}^{h^1},{\xi }_{11}^{h^2},\dots ,{\xi }_{11}^{h^m}& d_{12}^h,{\xi }_{12}^{h^1},{\xi }_{12}^{h^2},\dots ,{\xi }_{12}^{h^m}& \dots & d_{1q}^h,{\xi }_{1q}^{h^1},{\xi }_{1q}^{h^2},\dots ,{\xi }_{1q}^{h^m}\\ d_{21}^h,{\xi }_{21}^{h^1},{\xi }_{21}^{h^2},\dots ,{\xi }_{21}^{h^m}& d_{22}^h,{\xi }_{22}^{h^1},{\xi }_{22}^{h^2},\dots ,{\xi }_{22}^{h^m}& \dots & d_{2q}^h,{\xi }_{2q}^{h^1},{\xi }_{2q}^{h^2},\dots ,{\xi }_{2q}^{h^m}\\ ⋮& ⋮& ⋮& ⋮\\ d_{r1}^h,{\xi }_{r1}^{h^1},{\xi }_{r1}^{h^2},\dots ,{\xi }_{r1}^{h^m}& d_{r2}^h,{\xi }_{r2}^{h^1},{\xi }_{r2}^{h^2},\dots ,{\xi }_{r2}^{h^m}& \dots & d_{rq}^h,{\xi }_{rq}^{h^1},{\xi }_{rq}^{h^2},\dots ,{\xi }_{rq}^{h^m}\end{array}.\end{array}$$

4.2. Construction of Aggregated Complex $m$-Polar Fuzzy N-Soft Decision Matrix

The gradings and membership degrees of the individual expert is of no use because there is a panel of experts who are analyzing each and every attribute of the alternatives so their assessments must be accumulated into a collective grade and membership degree in a matrix called $\mathrm{Aggregated}\mathrm{Complex}$ m $\mathrm{-Polar}\mathrm{Fuzzy}\mathrm{N-Soft}\mathrm{Decision}\mathrm{Matrix}\mathrm{ACmPFNSDM}$ [30, 31]. The entries of this matrix $\mathrm{ACmPFNSDM}\Im ={{\xi }_{pt}}_{r\times q}$ are evaluated by using the following complex $m$-polar fuzzy N-soft weightage averaging $\mathrm{CmPFNSWA}$ operator:$$\begin{array}{c}\text{(4)}& {\Im }_{pt}=CmPFNSW{A}_{\epsilon }{\xi }_{pt}^1,{\xi }_{pt}^2,\dots ,{\xi }_{pt}^l={\epsilon }_1{\xi }_{pt}^1\oplus {\epsilon }_2{\xi }_{pt}^2\oplus \dots \oplus {\epsilon }_l{\xi }_{pt}^l\\ =d_{pt}^{\ast },,\end{array}$$where $△={△}^1,{△}^2,\dots ,{△}^m$,$$\begin{array}{c}\text{(5)}& △{}^i=1-{\displaystyle \prod _{h=1}^l{1-{\rho }_{pt}^{h^i}°\mu }^{{\epsilon }_h}}{e}^{2\pi \iota 1-{\displaystyle {\prod }_{h=1}^l{1-{\alpha }_{pt}^{h^i}}^{{\epsilon }_h}}},i=\mathrm{1,2},\dots ,m,d_{pt}^{\ast }=\max d_{pt}^1,d_{pt}^2,\dots ,d_{pt}^l.\end{array}$$

The constructed $\mathrm{ACmPFNSDM}$ can be framed as$$\begin{array}{}\text{(6)}& \Im =\begin{array}{cccc}{d}_{11}^{\ast },{\xi }_{11}^1,{\xi }_{11}^2,\dots ,{\xi }_{11}^m& d_{12}^{\ast },{\xi }_{12}^1,{\xi }_{12}^2,\dots ,{\xi }_{12}^m& \dots & d_{1q}^{\ast },{\xi }_{1q}^1,{\xi }_{1q}^2,\dots ,{\xi }_{1q}^m\\ d_{21}^{\ast },{\xi }_{21}^1,{\xi }_{21}^2,\dots ,{\xi }_{21}^m& d_{22}^{\ast },{\xi }_{22}^1,{\xi }_{22}^2,\dots ,{\xi }_{22}^m& \dots & d_{2q}^{\ast },{\xi }_{2q}^1,{\xi }_{2q}^2,\dots ,{\xi }_{2q}^m\\ ⋮& ⋮& ⋮& ⋮\\ d_{r1}^{\ast },{\xi }_{r1}^1,{\xi }_{r1}^2,\dots ,{\xi }_{r1}^m& d_{r2}^{\ast },{\xi }_{r2}^1,{\xi }_{r2}^2,\dots ,{\xi }_{r2}^m& \dots & d_{rq}^{\ast },{\xi }_{rq}^1,{\xi }_{rq}^2,\dots ,{\xi }_{rq}^m\end{array},\end{array}$$where ${\xi }_{pt}^i={\rho }_{pt}^i°\mu e^{2\pi \iota {\alpha }_{pt}^i},i=\mathrm{1,2},\dots ,m$.

4.3. Allocation of Weightage to Decision Criteria by Each Expert

In any project or the real-world scenario, the criteria or alternatives do not have the same relative importance. Each criterium has its own benefit, importance and credibility. And to consider one of them or to make a decision, it is mandatory for the decision makers to consider the fact of relative importance of each and every criterion. On the same lines, in a MCGDM techniques, each expert allots the weights to each criterion according to their reliability. In a CmPFNS-TOPSIS technique, not only the membership grades, as weights, but also the ordered grades, as weights, are assigned to each attribute by each expert. The individual weights assigned to each criteria is in the form of ${\chi }_t^h=d_t^h,{\mho }_t^{h^1},{\mho }_t^{h^2},\dots ,{\mho }_t^{h^m}$ where $d_t^h$ is the weightage grade given to the criterion ${\varphi }_t$ by the expert ${\psi }_h,\hspace{0.17em}{\mho }_t^{h^i}={\rho }_t^{h^i}°\mu e^{2\pi \iota {\alpha }_{pt}^{h^i}},i=\mathrm{1,2},\dots ,m$ is the weightage membership degree given to each criterion ${\varphi }_t$ by the expert ${\psi }_h$ with respect to the $i-th$ pole. These individual assessments of the decision makers to the criteria are assembled to construct a weightage vector $\chi ={{\chi }_1,{\chi }_2,\dots ,{\chi }_q}^T$ of the decision criteria, by utilizing the following CmPFNSWA operator:$$\begin{array}{c}\text{(7)}& {\chi }_t=\mathrm{CmPFNSW}{\mathrm{A}}_{\mathrm{\epsilon }}{\mho }_t^1,{\mho }_t^2,\dots ,{\mho }_t^l={\mathrm{\epsilon }}_1{\mho }_t^1\oplus {\mathrm{\epsilon }}_2{\mho }_t^2\oplus \dots \oplus {\mathrm{\epsilon }}_l{\mho }_t^l\\ =d_t^{\mathrm{\star }},△,\end{array}$$where $△={△}^1,{△}^2,\dots ,{△}^m$.$$\begin{array}{}\text{(8)}& {△}^i=1-{\displaystyle \prod _{h=1}^l{1-{\rho }_t^{h^i}°\mu }^{{\epsilon }_h}}{e}^{2\pi \iota 1-{\displaystyle {\prod }_{h=1}^l{1-{\alpha }_t^{h^i}}^{{\epsilon }_h}}},\hspace{1em}i=\mathrm{1,2},\dots ,m,\text{(9)}& d_t^{\mathrm{\star }}=\max d_t^1,d_t^2,\dots ,d_t^l.\end{array}$$

After performing these calculations, the entries of ${\chi }_t$ are formulated in the form of ${\chi }_t=d_t^{\mathrm{\star }},{\mathrm{▽}}_l^1,{\mathrm{▽}}_l^2,\dots ,{\mathrm{▽}}_l^m$ where ${\mathrm{▽}}_l^i={\rho }_l^i°\mu e^{2\pi \iota {\alpha }_l^i}$.

4.4. Construction of Aggregated Weighted Complex $m$-Polar Fuzzy N-Soft Decision Matrix

After the formation of $\mathrm{ACmPFNSDM}$ and the weight vector of decision-criteria, the mutual decision of decision-making experts and the weights of the decision-criteria are merged to construct the aggregated weighted complex $m$-polar fuzzy N-soft decision matrix $AWCmPFNSDM{\Im }^{\prime }={{\xi }_{pt}^{\prime }}_{r\times q}$ can be determined as follows:$$\begin{array}{c}\text{(10)}& {\xi }_{pt}^{\prime }={\xi }_{pt}\otimes {\chi }_t=d_{pt}^{\prime },B,\end{array}$$where $B=B^1,B^2,\dots ,B^m$,$$\begin{array}{}\text{(11)}& B^i={\rho }_{pt}^i°\mu {\rho }_t^i°\mu e^{2\pi \iota {\alpha }_{pt}^i{\alpha }_t^i},i=\mathrm{1,2},\dots ,m,\text{(12)}& d_{pt}^{\prime }=\min d_{pt},d_t.\end{array}$$

The constructed $\mathrm{AWCmPFNSDM}$ can be presented as follows:$$\begin{array}{}\text{(13)}& {\Im }^{\prime }=\begin{array}{cccc}{d}_{11}^{\prime },B_{11}^1,B_{11}^2,\dots ,B_{11}^m& d_{12}^{\prime },B_{12}^1,B_{12}^2,\dots ,B_{12}^m& \dots & d_{1q}^{\prime },B_{1q}^1,B_{1q}^2,\dots ,B_{1q}^m\\ d_{21}^{\prime },B_{21}^1,B_{21}^2,\dots ,B_{21}^m& d_{22}^{\prime },B_{22}^1,B_{22}^2,\dots ,B_{22}^m& \dots & d_{2q}^{\prime },B_{2q}^1,B_{2q}^2,\dots ,B_{2q}^m\\ ⋮& ⋮& \dots & ⋮\\ d_{r1}^{\prime },B_{r1}^1,B_{r1}^2,\dots ,B_{r1}^m& d_{r2}^{\prime },B_{r2}^1,B_{r2}^2,\dots ,B_{r2}^m& \dots & d_{rq}^{\prime },B_{rq}^1,B_{rq}^2,\dots ,B_{rq}^m\end{array},\end{array}$$where $B_{pt}^i={\tilde{\rho }}_{pt}^i°\mu e^{2\pi \iota {\tilde{\alpha }}_{pt}^i},i=\mathrm{1,2},\dots ,m$.

4.5. Construction of Score Matrix for Designation of Ideal Solutions

Since the considered environment is a complex $m$-polar system having complex $m$-polar values which are very complicated, having no specific order and incomparable. That is why it is very tricky to calculate positive and negative ideal solutions from the $\mathrm{AWCmPFNSDM}$. To overcome this hurdle, score function helps us to convert all the complex $m$-polar values into the crisp ones, which are easy to handle. The score value of each entry of $\mathrm{AWCmPFNSDM}$ can be calculated by using the following formula:$$\begin{array}{}\text{(14)}& R_{pt}=\frac{d_{pt}^{\prime }}{N-1}+\frac{{\rho }_{pt}^1°\mu +{\rho }_{pt}^2°\mu +\dots +{\rho }_{pt}^m°\mu }{m}+\frac{{\alpha }_{pt}^1+{\alpha }_{pt}^2+\dots +{\alpha }_{pt}^m}{m},\end{array}$$where $p=\mathrm{1,2},\dots ,r\mathrm{and}t=\mathrm{1,2},\dots ,q$. The assembled score matrix can be represented as$$\begin{array}{}\text{(15)}& \pounds =\begin{array}{cccc}{R}_{11}& R_{12}& \dots & R_{1q}\\ R_{21}& R_{22}& \dots & R_{2q}\\ ⋮& ⋮& ⋮& ⋮\\ R_{r1}& R_{r2}& \dots & R_{rq}\end{array}.\end{array}$$

4.6. Formulation of Complex $m$-Polar Fuzzy N-Soft Positive Ideal Solution CmPFNS-PIS and Negative Ideal Solution CmPFNS-NIS

Let ${\mathrm{\daleth }}_b$ and ${\mathrm{\daleth }}_c$ represents the benefit-type criteria and cost-type criteria respectively. Now, calculate the CmPFNS-PIS $P$ and CmPFNS-NIS $N$ for the maximization of all benefit-type criteria and the maximization of all cost-type criteria respectively. The estimated CmPFNS-PIS $P$ and CmPFNS-NIS $N$ with respect to each criterion are given as follows:$$\begin{array}{c}\text{(16)}& P=P_t^{+}=d_t^{+},D_t^{+},t=\mathrm{1,2},\dots ,q,N=N_t^{-}=d_t^{-},D_t^{-},t=\mathrm{1,2},\dots ,q,\end{array}$$where$$\begin{array}{c}\text{(17)}& D_t^{+}=D_t^{{+}^1},D_t^{{+}^2},\mathrm{...},D_t^{{+}^m},D_t^{-}=D_t^{{-}^1},D_t^{{-}^2},\mathrm{...},D_t^{{-}^m},\end{array}$$and$$\begin{array}{c}\text{(18)}& D_t^{{+}^i}={\rho }_t^{i^{+}}°\mu e^{2\pi \iota {\alpha }_t^{i^{+}}},i=\mathrm{1,2},\dots ,m,D_t^{{-}^i}={\rho }_t^{i^{-}}°\mu e^{2\pi \iota {\alpha }_t^{i^{-}}},i=\mathrm{1,2},\dots ,m.\end{array}$$

Now, $P_t^{+}$ and $N_t^{-}$ can be formulated as$$\begin{array}{}\text{(19)}& P_t^{+}=\begin{array}{cc}{\Im }_{jk}^{\prime }:R{\Im }_{jk}^{\prime }=\underset{1\le p\le r}{\max }R{\Im }_{pt}^{\prime },\hfill & i\mathrm{f}{\varphi }_t\in {\mathrm{\daleth }}_b,\hfill \\ {\Im }_{jk}^{\prime }:R{\Im }_{jk}^{\prime }=\underset{1\le p\le r}{\min }R{\Im }_{pt}^{\prime },\hfill & i\mathrm{f}{\varphi }_t\in {\mathrm{\daleth }}_c.\hfill \end{array}\text{(20)}& N_t^{-}=\begin{array}{cc}{\Im }_{jk}^{\prime }:R{\Im }_{jk}^{\prime }=\underset{1\le p\le r}{\min }R{\Im }_{pt}^{\prime },\hfill & \text{if}{\varphi }_{\text{t}}\in {\mathrm{\daleth }}_{\text{b}},\hfill \\ {\Im }_{jk}^{\prime }:R{\Im }_{jk}^{\prime }=\underset{1\le p\le r}{\max }R{\Im }_{pt}^{\prime },\hfill & \text{if}{\varphi }_{\text{t}}\in {\mathrm{\daleth }}_{\text{c}}.\hfill \end{array}\end{array}$$

4.7. Calculation of Distance Measures between Alternatives and Ideal Solutions

It is quite tricky to determine the actual $\mathrm{CmPFNS-PIS}$ and $\mathrm{CmPFNS-NIS}$ in the real-world problems related to complex two-dimensional data. To overcome this hurdle, we calculate the normalized Euclidean distance of each alternative from the $\mathrm{CmPFNS-PIS}$ and $\mathrm{CmPFNS-NIS}$ to determine the best alternative which is nearest to the $\mathrm{CmPFNS-PIS}$ and farthest from the $\mathrm{CmPFNS-NIS}$. The normalized Euclidean distance of the alternative ${\omega }_p$ from the ideal solutions can be evaluated as follows:$$\begin{array}{}\text{(21)}& d{\omega }_p,P=\sqrt{\frac{{\displaystyle {\sum }_{t=1}^q{1/N-1}^2{d}_{pt}^{\prime }-d_t^{+}+{{\displaystyle {\sum }_{i=1}^m{\tilde{\rho }}_{pt}^i°\mu -{\rho }_t^{i^{+}}°\mu }}^2+{\displaystyle {\sum }_{i=1}^m{{\tilde{\alpha }}_{pt}^i-{\alpha }_t^{i^{+}}}^2}}}{rm}},\text{(22)}& d{\omega }_p,N=\sqrt{\frac{{\displaystyle {\sum }_{t=1}^q{1/N-1}^2{d}_{pt}^{\prime }-d_t^{-}+{{\displaystyle {\sum }_{i=1}^m{\tilde{\rho }}_{pt}^i°\mu -{\rho }_t^{i^{-}}°\mu }}^2+{{\displaystyle {\sum }_{i=1}^m{\tilde{\alpha }}_{pt}^i-{\alpha }_t^{i^{-}}}}^2}}{rm}},\end{array}$$where $r$ is the number of criteria and $m$ is the number of poles.

4.8. Evaluation of Revised Closeness Index

The revised closeness index is used to determine the extent of closeness of the alternative from the positive ideal solution and the extent of the fairness of the alternative from the negative ideal solution. The alternative with least revised closeness index will be considered as the most suitable one. To calculate the revised closeness index, we use the formula introduced by Gundogdu and Kahraman (2019) as follows:$$\begin{array}{}\text{(23)}& I{\omega }_p=\frac{\mathrm{d}{\omega }_p,P}{{\mathrm{d}}_{\min }{\omega }_p,P}-\frac{\mathrm{d}{\omega }_p,N}{{\mathrm{d}}_{\max }{\omega }_p,N},\hspace{1em}p=\mathrm{1,2},\dots ,r,\end{array}$$where$$\begin{array}{c}\text{(24)}& {\mathrm{d}}_{\min }{\omega }_p,P=\underset{p}{\min }\mathrm{d}{\omega }_p,P,{\mathrm{d}}_{\max }{\omega }_p,P=\underset{p}{\max }\mathrm{d}{\omega }_p,N.\end{array}$$

4.9. Determination of the Ranking of the Alternatives

After calculating the revised closeness index, the last step is to organize the alternatives in the descending order, that is, the alternative with the least index will come at the first place, most preferable, and the alternative having largest index will come at the last, least preferable, that is,$$\begin{array}{}\text{(25)}& {\omega }^{\cdot }={\omega }_n:I{\omega }_n=\underset{p}{\min }I{\omega }_p.\end{array}$$

5. Selection of Surgical Equipment in the Shaukhat Khanum Hospital, Lahore: A Case Study

In this section, the reliability and credibility of the proposed CmPFNS-TOPSIS is illustrated with the help of a real-life example, named as selection of the suitable equipment for the surgical oncology department of the Shaukhat Khanum Hospital, so that we have a better on-look on the practicability of our veracious technique [32].

One of the world’s most well-known cancer hospitals is Shaukhat Khanum Memorial Cancer Hospital, where the patients suffering from cancer and tumor like chronic diseases are being treated with the help of the modern machinery. Since the hospital is run by the donations of the public and the government support, this is its foremost duty to maintain its standards of machines, staff and treatment. Because only this way it will remain trustworthy for its patients as ever before. To upgrade the system and keep up the level of quality of the machines, used in diagnosis and medication, the higher authority of the hospital always in endeavor to choose the finest quality of machines, trained staff for the prime treatment of their respected patients. In this scenario, the selection of such type of machines and devices is quite a hectic task to be performed because even a single machine has multiple attributes of its own and not every attribute is of equal importance. This complication can be handled with our sensational proposed CmPFNS-TOPSIS technique that can elegantly share this burden of the hospital. The data has been gathered from the website (https://shaukatkhanum.org.pk), where a surgical oncology department in Shaukat Khanum Hospital wants to import some medical equipment for the department. The higher authorities put forward the universe five medical equipments $\mathrm{\Omega }={\omega }_1,{\omega }_2,{\omega }_3,{\omega }_4,{\omega }_5$, after analyzing the department’s requirements. The detailed information of the chosen alternatives is enlightened in Table 1:

Table 1

Information related to the selected alternatives.

To select the most suitable medical equipment for the surgery oncology department, the department has hired a panel of four decision making experts $\mathrm{\Psi }={\psi }_1,{\psi }_2,{\psi }_3,{\psi }_4$ who shall thoroughly examine all the attributes of the given devices, where ${\psi }_1=\mathrm{Project}\mathrm{Supervisor}$, ${\psi }_2=\mathrm{Finance}\mathrm{Supervisor}$, ${\psi }_3=\mathrm{Health}\mathrm{Supervisor}$, ${\psi }_4=\mathrm{Technical}\mathrm{Supervisor}$.

The attributes of the alternatives $\mathrm{\Phi }={\varphi }_1,{\varphi }_2,{\varphi }_3,{\varphi }_4$, being evaluated by the decision making experts for their comprehensive mutual decision, further depend upon three parameters, discussed in detail:

5.1. ${\varphi }_1$: Cost

In any type of project, the criterion “cost” always plays a vital role in accomplishing the given task of the project. Maintenance cost, the expenses of upgrading the machines, electricity cost and the cost of import are those parameters upon which the cost attribute depend upon.

5.2. ${\varphi }_2$: Accessibility

Whenever there is a need for a machine or a device, one question always arises in our mind whether that device is in our access or not. By the accessibility of an equipment, we mean the availability of a machine, access of spare parts, and the availability of the required area or space being occupied by the machine.

5.3. ${\varphi }_3$: Quality

One of the salient features of the medical devices is their quality because the sub-standard medical equipment not only disturbs the diagnosis but also has the pernicious effects on the health of the patients. This feature occupies the durability of the equipment, long lasting-not easily replaceable, viscosity of the devices and ease of sterilization.

5.4. ${\varphi }_4$: Health Risks

Since the equipment under consideration are used for the medical treatment purposes, there must be very low health risks, not only for the patients but also for the doctors and surgeons using them. This attribute incorporates effects on user’s health, emission of radiations and potential to deal with health sensitivity. The main intention behind this procedure is to allocate the best medical equipment, in the surgery oncology department, that will serve the patients in its best way, that is, the accuracy of the diagnosis of the ailment, minimum health risks and having the finest quality in a reasonable price of cost. The description of the alternatives, attributes, $m$-polar criteria and decision-making experts is synchronized in Figure 2. The graphical representation of the attributes with their parameters is in Figure 2.

[figure(s) omitted; refer to PDF]

The step-by-step solution for the selection of the most valuable medical equipment using recommended CmPFNS-TOPSIS method is elucidated as follows:

(1) The administration of the oncology department assigns weights to each decision-making expert with respect to their capability and competency. The weights granted to each expert is arranged in Table 2.

Table 2

Weightage of experts.

Table 3

C3PF6S DM of the project supervisor ${\psi }_1$.

Table 4

C3PF6S DM of the finance supervisor ${\psi }_2$.

Table 5

$\mathrm{C3F6SDM}$ of the health supervisor ${\psi }_3$.