Passive network evolution promotes group welfare in complex networks

Ye, Ye; Hang, Xiao Rong; Koh, Jin; Miszczak, Jarosław Adam; Cheong, Kang Hao; Xie, Nenggang

doi:10.1016/j.chaos.2019.109464

Cited by 47 publications

(9 citation statements)

References 34 publications

(39 reference statements)

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“…It has since been applied across a wide range of disciplines in the physical sciences and engineering-related fields, [34,35] such as diffusive and granular flow dynamics, [36,37] information thermodynamics, [38][39][40] chaos theory, [41][42][43][44][45][46][47] switching problems, [48][49][50] and quantum phenomena. [51][52][53][54][55][56][57] The paradox has also found numerous applications in life science, [58][59][60][61][62] ecology and evolutionary biology, [63][64][65] social dynamics, [66][67][68][69][70] and interdisciplinary work. [71] In this paper, we propose a compartmental population model, which we call the SIADE model, that takes into account the health and well-being of the population, as well as economic impacts.…”

Section: Introductionmentioning

confidence: 99%

Relieving Cost of Epidemic by Parrondo's Paradox: A COVID‐19 Case Study

2020

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COVID‐19, also known as SARS‐CoV‐2, is a coronavirus that is highly pathogenic and virulent. It spreads very quickly through close contact, and so in response to growing numbers of cases, many countries have imposed lockdown measures to slow its spread around the globe. The purpose of a lockdown is to reduce reproduction, that is, the number of people each confirmed case infects. Lockdown measures have worked to varying extents but they come with a massive price. Nearly every individual, community, business, and economy has been affected. In this paper, switching strategies that take into account the total “cost” borne by a community in response to COVID‐19 are proposed. The proposed cost function takes into account the health and well‐being of the population, as well as the economic impact due to the lockdown. The model allows for a comparative study to investigate the effectiveness of various COVID‐19 suppression strategies. It reveals that both the strategy to implement a lockdown and the strategy to maintain an open community are individually losing in terms of the total “cost” per day. However, switching between these two strategies in a certain manner can paradoxically lead to a winning outcome—a phenomenon attributed to Parrondo's paradox.

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Section: Introductionmentioning

confidence: 99%

Relieving Cost of Epidemic by Parrondo's Paradox: A COVID‐19 Case Study

2020

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“…All these factors contribute Communicated by Leonardo Tomazeli Duarte. to the uncertainty of information to some extent. There are many powerful mathematical frameworks are established to handle uncertain information, Such as the extended probability theory , fuzzy sets (Zadeh 1965(Zadeh , 2008, Dempster-Shafer evidence theory (DS evidence theory) (Dempster 1967;Shafer 1976), D numbers (Chatterjee et al 2018b;Liu and Deng 2019), rough sets (Chatterjee et al 2018a;Fujita et al 2019), granular computing (Fujita et al 2018a, b), Quantum decision-making (Tan et al 2020; and complex network (Fan et al 2020;Wen et al 2020;Ye et al 2020). Due to the unavoidability of uncertainty in real world, many methods have been presented and applied in various fields, such as classification (Xiao 2019;Maldonado et al 2019), medical diagnosis (Cao et al 2019a, b), decision making (Garg and Chen 2020;Song et al 2019), information fusion Tan and Cheong 2018;Song et al 2020), industrial alarm system (Xu et al 2018), and reliability evaluation (Song et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Generate two-dimensional belief function based on an improved similarity measure of trapezoidal fuzzy numbers

Pelusi

Deng

2020

Comp. Appl. Math.

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“…[15,16] Quantum paradoxical systems have also been studied, some suggesting implications on quantum information processing, [17] and algorithms exploiting the paradox have been devised for engineering optimization. [18,19] In biophysics, evolutionary processes, [20][21][22][23][24][25] population biology, [26] ecological dynamics, [27][28][29] cellular machinery, [30][31][32] and social behavior [33][34][35] have all been linked to the paradox, and a degree of universality across scales is suspected. [36] The seminal results in genetics include the possibility of proliferation and fixation of lower-fitness autosomal alleles amidst antagonistic selection and epistasis, [37] and selection for random phase variation [23,38] and phenotypic switching [24,25] in microorganisms, despite the strategy being likely locally maladaptive; in ecological systems, environmental fluctuations have been shown to enable the persistence of rare species in invaded habitats.…”

Section: Introductionmentioning

confidence: 99%

Generalized Solutions of Parrondo's Games

Koh

Cheong

2020

Advanced Science

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In game theory, Parrondo's paradox describes the possibility of achieving winning outcomes by alternating between losing strategies. The framework had been conceptualized from a physical phenomenon termed flashing Brownian ratchets, but has since been useful in understanding a broad range of phenomena in the physical and life sciences, including the behavior of ecological systems and evolutionary trends. A minimal representation of the paradox is that of a pair of games played in random order; unfortunately, closed‐form solutions general in all parameters remain elusive. Here, we present explicit solutions for capital statistics and outcome conditions for a generalized game pair. The methodology is general and can be applied to the development of analytical methods across ratchet‐type models, and of Parrondo's paradox in general, which have wide‐ranging applications across physical and biological systems.

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Passive network evolution promotes group welfare in complex networks

Cited by 47 publications

References 34 publications

Relieving Cost of Epidemic by Parrondo's Paradox: A COVID‐19 Case Study

Relieving Cost of Epidemic by Parrondo's Paradox: A COVID‐19 Case Study

Generate two-dimensional belief function based on an improved similarity measure of trapezoidal fuzzy numbers

Generalized Solutions of Parrondo's Games

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