Research article

Topological approach for decision-making of COVID-19 infection via a nano-topology model

  • Received: 21 December 2020 Accepted: 11 May 2021 Published: 18 May 2021
  • MSC : 54H30, 68T30, 68T37, 68U01, 68U35, 68W01, 68W25

  • The conditions of the equivalence relation limit the application fields of the methodology of Pawlak's rough sets. So, to expand the application areas of this theory, it is generalized to any binary relation. Neighborhoods induced from the relations represent a core bridge between rough sets and application since it represents easy tools for dealing with daily-life problems. Accordingly, the first core objective of the current research is to propose a novel neighborhood (so-called an initial-neighborhood) generated from any binary relation. Based on this neighborhood, we suggest a new generalization to Pawlak rough sets and some of their extensions. The proposed approaches satisfy all properties of classical rough sets without adding any extra restrictions and hence we can apply them in any real-life problem. The second aim is to generalize the notion of nano-topology into any binary relation to extend the applications of this concept. Properties of the suggested methods are introduced with many counter-examples. Comparisons between the suggested techniques and the others studies published in the literature are examined. We proved that the proposed techniques are extra precise than the earlier approaches. Finally, the medical application of COVID-19 is provided to illustrate the significance of our approaches in deciding the impact factors for COVID-19 infection. The proposed application is based on a reflexive relation, so Pawlak rough sets and some of its generalizations couldn't be applied to solve this problem. Accordingly, we have successes in solving this problem using the suggested techniques. Hence, we write an algorithm to be a useful tool that may help the doctor in diagnosing the infection of COVID-19.

    Citation: M. El Sayed, M. A. El Safty, M. K. El-Bably. Topological approach for decision-making of COVID-19 infection via a nano-topology model[J]. AIMS Mathematics, 2021, 6(7): 7872-7894. doi: 10.3934/math.2021457

    Related Papers:

  • The conditions of the equivalence relation limit the application fields of the methodology of Pawlak's rough sets. So, to expand the application areas of this theory, it is generalized to any binary relation. Neighborhoods induced from the relations represent a core bridge between rough sets and application since it represents easy tools for dealing with daily-life problems. Accordingly, the first core objective of the current research is to propose a novel neighborhood (so-called an initial-neighborhood) generated from any binary relation. Based on this neighborhood, we suggest a new generalization to Pawlak rough sets and some of their extensions. The proposed approaches satisfy all properties of classical rough sets without adding any extra restrictions and hence we can apply them in any real-life problem. The second aim is to generalize the notion of nano-topology into any binary relation to extend the applications of this concept. Properties of the suggested methods are introduced with many counter-examples. Comparisons between the suggested techniques and the others studies published in the literature are examined. We proved that the proposed techniques are extra precise than the earlier approaches. Finally, the medical application of COVID-19 is provided to illustrate the significance of our approaches in deciding the impact factors for COVID-19 infection. The proposed application is based on a reflexive relation, so Pawlak rough sets and some of its generalizations couldn't be applied to solve this problem. Accordingly, we have successes in solving this problem using the suggested techniques. Hence, we write an algorithm to be a useful tool that may help the doctor in diagnosing the infection of COVID-19.



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    [1] G. G. Kampf, D. Todt, S. Pfaender, E. Steinmann, Persistence of coronaviruses on inanimate surfaces and their inactivation with biocidal agents, J. Hosp. Infect, 104 (2020), 246-251. doi: 10.1016/j.jhin.2020.01.022
    [2] J. J. Tian, J. B. Wu, Y. T. Bao, X. Y. Weng, L. Shi, B. B. Liu, et al., Modeling analysis of COVID-19 based on morbidity data in Anhui, China, Math. Biosci. Eng., 17 (2020), 2842-2852.
    [3] L. P. Wang, J. Wang, H. Y. Zhao, Y. Y. Shi, K. Wang, P. Wang, et al, Modelling and assessing the effects of medical resources on transmission of novel coronavirus (COVID-19) in Wuhan, China, Math. Biosci. Eng., 17 (2020), 2936-2949.
    [4] K. Wang, Z. Z. Lu, X. M. Wang, H. Li, H. L. Li, D. D. Lin, et al., Current trends and future prediction of novel coronavirus disease (COVID-19) epidemic in China: a dynamical modeling analysis, Math. Biosci. Eng., 17 (2020), 3052-3061.
    [5] M. T. Li, G. Q. Sun, J. Zhang, Y. Zhao, X Pei, L. Li, et al., Analysis of COVID-19 transmission in Shanxi Province with discrete time imported cases, Math. Biosci. Eng., 17 (2020), 3710-3720.
    [6] L. X. Feng, S. L. Jing, S. K. Hu, D. F. Wang, H. F. Huo, Modelling the effects of media coverage and quarantine on the COVID-19 infections in the UK, Math. Biosci. Eng., 17 (2020), 3618-3636. doi: 10.3934/mbe.2020204
    [7] X. Feng, J. Chen, K. W, L. Wang, F. Q. Zhang, Z. Jin, et al., Phase-adjusted estimation of the COVID-19 outbreak in South Korea under multi-source data and adjustment measures: a modelling study, Math. Biosci. Eng., 17 (2020), 3637-3648.
    [8] N. Ghorui, A. Ghosh, S. P. Mondal, M. Y. Bajuri, A. Ahmadian, S. Salahshour, et al., Identification of dominant risk factor involved in spread of COVID-19 using hesitant fuzzy MCDM methodology, Results Phys., 21 (2021), 103811.
    [9] O. E. Deeb, M. Jalloul, The dynamics of COVID-19 spread: evidence from Lebanon, Math. Biosci. Eng., 17 (2020), 5618-5632. doi: 10.3934/mbe.2020302
    [10] M. K. El-Bably, A. El F. A. El Atik, Soft β-rough sets and its application to determine COVID-19, Turk. J. Math., 45 (2021), 1133–1148.
    [11] M. R. Hashmi, M. Riaz, F. Smarandache, M-polar neutrosophic generalized weighted and m-polar neutrosophic generalized einstein weighted aggregation operators to diagnose Coronavirus (COVID-19), J. Intell. Fuzzy Syst., 39 (2020), 183-191.
    [12] M. A. El Safty, S. AlZahrani, Topological modeling for symptom reduction of Corona virus, Punjab Uni. J. Math., 53 (2021), 47-59.
    [13] Z. Pawlak, Rough sets, Int. J. Inform. Comput. Sci., 11 (1982), 341-356.
    [14] E. A. Abo-Tabl, A comparison of two kinds of definitions of rough approximations based on a similarity relation, Inform. Sci., 181 (2011), 2587-2596.
    [15] K. Y. Qin, J. L. Yang, Z. Pei, Generalized rough sets based on reflexive and transitive relations, Inform. Sci., 178 (2008), 4138-4141. doi: 10.1016/j.ins.2008.07.002
    [16] M. Kondo, On the structure of generalized rough sets, Inform. Sci., 176 (2006), 589-600. doi: 10.1016/j.ins.2005.01.001
    [17] Y. Y. Yao, Two views of the theory of rough sets in finite universes. Int. J. Approx. Reason., 15 (1996), 291-317.
    [18] A. A. Allam, M. Y. Bakeir, E. A. Abo-Tabl, New approach for basic rough set concepts. In: International workshop on rough sets, fuzzy sets, data mining, and granular computing, Springer, Berlin, Heidelberg, 2005, 64-73.
    [19] M. I. Ali, B. Davvaz, M. Shabir, Some properties of generalized rough sets, Inform. Sci., 224 (2013), 170-179. doi: 10.1016/j.ins.2012.10.026
    [20] A. A. Abo Khadra; B. M. Taher, M. K. El-Bably, Generalization of Pawlak approximation space, In: The second international conference on mathematics: Trends and developments, Egyptian Math. Soc., 3 (2007), 335-346.
    [21] M. E. Abd El-Monsef, O. A. Embaby, M. K. El-Bably, Comparison between rough set approximations based on different topologies, Int. J. Granular Comput, Rough Sets Intell. Syst., 3 (2014), 292-305.
    [22] M. El Sayed, Applications on simply alpha-approximation space based on simply alpha open sets, European J. Sci. Res., 120 (2014), 7-14.
    [23] M. El Sayed, Generating simply approximation spaces by using decision tables, J. Comput. Theor. Nanos., 13 (2016), 7726-7730.
    [24] W. H. Xu, W. X. Zhang, Measuring roughness of generalized rough sets induced by a covering, Fuzzy Sets Syst., 158 (2007), 2443-2455. doi: 10.1016/j.fss.2007.03.018
    [25] M. E. Abd El-Monsef, A. M. Kozae, M. K. El-Bably, On generalizing covering approximation space, J. Egyptian Math. Soc., 23 (2015), 535-545.
    [26] A. S. Nawar, M. K. El-Bably, A. E. F. El-Atik, Certain types of coverings based rough sets with application, J. Intell. Fuzzy Syst., 39 (2020), 3085-3098.
    [27] J. H. Dai, S. C. Gao, G. J. Zheng, Generalized rough set models determined by multiple neighborhoods generated from a similarity relation, Soft Comput., 22 (2018), 2081-2094. doi: 10.1007/s00500-017-2672-x
    [28] K. Zhang; J. M. Zhan; W. Z. Wu, On multi-criteria decision-making method based on a fuzzy rough set model with fuzzy α-neighborhoods, IEEE T. Fuzzy Syst., 2020, DOI: 10.1109/TFUZZ.2020.3001670.
    [29] J. M. Zhan; H. B. Jiang; Y. Y. Yao, Three-way multi-attribute decision-making based on outranking relations, IEEE T. Fuzzy Syst., 2020, DOI: 10.1109/TFUZZ.2020.3007423.
    [30] W. Sierpinski, C. Krieger, General Topology, University of Toronto press, 1956.
    [31] M. K. El-Bably, K. K. Fleifel, Some topological structures by relations, J. Comput. Theor. Nanos., 14 (2017), 4100-4103. doi: 10.1166/jctn.2017.6792
    [32] M. K. El-Bably, K. K. Fleifel, O. A. Embaby, Topological approaches to rough approximations based on closure operators, Granul. Comput., 2021, DOI: 10.1007/s41066-020-00247-x.
    [33] M. El-Sayed, A. G. A. Q. Al Qubati, M. K. El-Bably, Soft pre-rough sets and its applications in decision making, Math. Biosci. Eng., 17 (2020), 6045-6063.
    [34] C. Largeron, S. Bonnevay, A Pretopological approach for structural analysis, Inform. Sci., 144 (2002), 169-185. doi: 10.1016/S0020-0255(02)00189-5
    [35] A. A. Q. Al Qubati, M. El Sayed, H. F. Al Qubati, Small and large inductive dimensions of intuitionistic fuzzy topological spaces, Nanosci. Nanotech. Let., 12 (2020), 413-417.
    [36] M. Lellis Thivagar and C. Richard, On nano forms of weakly open sets, IJMSI, 1 (2013), 31-37.
    [37] B. De Baets, E. Kerre, A revision of Bandler-Kohout Compositions of relations, Math. Pannonica, 4 (1993), 59-78.
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