The Janus face of Darwinian competition

Hintze, Arend; Phillips, Nathaniel D.; Hertwig, Ralph

doi:10.1038/srep13662

Cited by 8 publications

(5 citation statements)

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“…Darwinism argues that living creatures cannot evolve useful physiological structures and cognitive abilities without competition [ 41 ]. Modern education is characterized by a large scale.…”

Section: Literature Reviewmentioning

confidence: 99%

How School Climate Affects the Development of the Social and Emotional Skills of Underprivileged-Background Students—An Empirical Study Based on the SSES2019 Data

Wang

Xiao

et al. 2022

Children

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Background: Promoting the development of the social and emotional skills of underprivileged-background students is an integral part of educational and social equity. To date, there has been a lack of relevant research in this field. Aims: This study investigated the impacts of cooperative school climate and competitive school climate on the development of the social and emotional skills of underprivileged-background students. Sample: This study used the data of Chinese underprivileged-background students (N = 1739) from the Study on Social and Emotional Skills conducted by the Organisation for Economic Cooperation and Development (OECD-SSES2019). Methods: This study selected the ordinary least squares (OLS) analysis method and the quantile regression (QR) analysis method. Results: The ordinary least squares (OLS) analysis results showed that cooperative school climates promoted the development of various dimensions of the social and emotional skills of underprivileged-background students, while competitive school climates had significant negative impacts on the collaboration and emotional regulation of underprivileged-background students and had no significant impact on the other three major domains, namely engagement with others, open-mindedness, and task performance. A quantile regression analysis further explored the heterogeneity in the impacts of cooperative school climate and competitive school climate on the development of the social and emotional skills of underprivileged-background students through quantile regression and found that the impacts of a competitive school climate on underprivileged-background students with different levels of social and emotional skills were homogeneous, while the impacts of a competitive school climate on underprivileged-background students with different levels of social and emotional skills were heterogeneous. Conclusions: These findings provide a greater insight into the roles of school cooperative climate and school competitive climate in the development process of the social and emotional skills of underprivileged-background students.

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Section: Literature Reviewmentioning

confidence: 99%

How School Climate Affects the Development of the Social and Emotional Skills of Underprivileged-Background Students—An Empirical Study Based on the SSES2019 Data

Wang

Xiao

et al. 2022

Children

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“…This type of adaptation has also been found in strategic games in which groups of competitors converge to stable strategies as a result of experience, both over individual and evolutionary time-scales (Avrahami, Güth, Hertwig, Kareev, & Otsubo, 2013;Camerer, 2003;Rapoport, Stein, Parco, & Nicholas, 2003). A recent study by Hintze, Phillips, and Hertwig (2015) illustrates how a minimal exploration strategy emerges when extreme competition is a stable and recurrent property of the ecology. They conducted evolutionary simulations using tasks of a similar nature to the rivals-in-the-dark game, with varying levels of competitive pressure.…”

Section: Discussionmentioning

confidence: 67%

To act fast or to bide time? Adaptive exploration under competitive pressure

Markant¹,

Phillips²,

Kareev³

et al. 2018

Preprint

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Competitive pressure affects a wide spectrum of decisions under uncertainty. It forces the individual to balance the value of gathering more information about the quality of potential choice alternatives against the risk that competitors will act first and claim the best options. Although this tradeoff between competition and exploration has long been recognized, little is known about how people adapt their exploration of uncertain options when facing competitive pressure. We examined how competitive pressure affects exploration in the “rivals-in-the-dark” game. Two players simultaneously learn about a set of choice options and compete to claim the best one. Across three studies, we show that people adapt their exploration in response to the structure of the choice environment (including the option set size and the relative number of gains and losses) and in response to repeated competition with the same opponent. Furthermore, we present a model-based analysis showing that their behavior is best described by a compensatory strategy under which the value of further exploration is weighed against the cost of being beaten to the punch by an opponent. The results point to a process of local adaptation whereby people learn to “act fast” based on their experience in a novel competitive environment.

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“…For instance, 563 increasingly challenging environments favor large brains up to a point, so that 564 exceedingly challenging environments disfavor large brains. Thus, on the low end of 565 environmental difficulty, the prediction that increasingly challenging environments favor 566 large brains is consistent with ecological challenge hypotheses [21,38]; yet, on the high 567 end of environmental difficulty, the prediction that increasingly challenging 568 environments disfavor large brains is consistent with constraint hypotheses according to 569 which facilitation of environmental challenge favors larger brains [21,[83][84][85].…”

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confidence: 73%

“…To analyze how selection affects the evolution of the allocation 81 strategy, we carry out an evolutionary invasion analysis (e.g., [31,[47][48][49]), and thus 82 consider that only two strategies can occur in the population, a mutant u and a resident 83 (wild-type) v allocation strategies. We thus seek to establish which strategy is resistant 84 to invasion by any alternative strategy taken from the set U of feasible allocation 85 strategies, and which thus provides a likely final point of evolution. From demographic 86 assumptions we make below, it is well established [43,[50][51][52] that an uninvadable 87 strategy u * satisfies 88 u * ∈ arg max u∈U R 0 (u, u * ),…”

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confidence: 99%

A Model for Brain Life History Evolution

González-Forero

Faulwasser

Lehmann

2016

Preprint

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Complex cognition and relatively large brains are distributed across various taxa, and many primarily verbal hypotheses exist to explain such diversity. Yet, mathematical approaches formalizing verbal hypotheses would help deepen the understanding of brain and cognition evolution. With this aim, we combine elements of life history and metabolic theories to formulate a metabolically explicit mathematical model for brain life history evolution. We assume that some of the brain's energetic expense is due to production (learning) and maintenance (memory) of energy-extraction skills (or cognitive abilities, knowledge, information, etc.). We also assume that individuals use such skills to extract energy from the environment, and can allocate this energy to grow and maintain the body, including brain and reproductive tissues. The model can be used to ask what fraction of growth energy should be allocated at each age, given natural selection, to growing brain and other tissues under various biological settings. We apply the model to find uninvadable allocation strategies under a baseline setting ("me vs nature"), namely when energy-extraction challenges are environmentally determined and are overcome individually but possibly with maternal help, and use modern-human data to estimate model's parameter values. The resulting uninvadable strategies yield predictions for brain and body mass throughout ontogeny and for the ages at maturity, adulthood, and brain growth arrest. We find that: (1) a me-vs-nature setting is enough to generate adult brain and body mass of ancient human scale and a sequence of childhood, adolescence, and adulthood stages; (2) large brains are favored by intermediately challenging environments, moderately effective skills, and metabolically expensive memory; and (3) adult skill is proportional to brain mass when metabolic costs of memory saturate the brain metabolic rate allocated to skills. Author summaryComplex cognition and relatively large brains occur in a diversity of mammal, bird, and fish species among others, and there is a large number of mostly verbal hypotheses to explain what causes their evolution in certain species but not others. However, these hypotheses have scarcely exploited the power of formulating them in mathematical terms, Funding: This work was funded by Swiss NSF grant PP00P3-146340 to LL http://www.snf.ch/en/ Pages/default.aspx. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Competing interests:The authors have declared that no competing interests exist.which has been very useful to understand the evolution of other traits. To address this issue, we formulate a mathematical model that allows incorporating many of those hypotheses and that can be used to obtain predictions for how much and how fast the brain should grow depending on the hypothesis assumed. We apply the model to humans in a setting where each individual must extract energy from the environment alone (e.g., by hunting or coo...

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The Janus face of Darwinian competition

Cited by 8 publications

References 15 publications

How School Climate Affects the Development of the Social and Emotional Skills of Underprivileged-Background Students—An Empirical Study Based on the SSES2019 Data

How School Climate Affects the Development of the Social and Emotional Skills of Underprivileged-Background Students—An Empirical Study Based on the SSES2019 Data

To act fast or to bide time? Adaptive exploration under competitive pressure

A Model for Brain Life History Evolution

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