Switch to: References

Add citations

You must login to add citations.
  1. Ecology.Sahotra Sarkar - 2008 - Stanford Encyclopedia of Philosophy.
    Download  
     
    Export citation  
     
    Bookmark   8 citations  
  • Going big by going small: Trade-offs in microbiome explanations of cancer.Emily C. Parke & Anya Plutynski - 2023 - Studies in History and Philosophy of Science Part A 97 (C):101-110.
    Download  
     
    Export citation  
     
    Bookmark   1 citation  
  • Meaning and Purpose: Using Phylogenies to Investigate Human History and Cultural Evolution.Lindell Bromham - 2023 - Biological Theory 18 (4):284-302.
    Phylogenies are increasingly being used to investigate human history, diversification and cultural evolution. While using phylogenies in this way is not new, new modes of analysis are being applied to inferring history, reconstructing past states, and examining processes of change. Phylogenies have the advantage of providing a way of creating a continuous history of all current populations, and they make a large number of analyses and hypothesis tests possible even when other forms of historical information are patchy or nonexistent. In (...)
    Download  
     
    Export citation  
     
    Bookmark  
  • Stepping Forwards by Looking Back: Underdetermination, Epistemic Scarcity and Legacy Data.Adrian Currie - 2021 - Perspectives on Science 29 (1):104-132.
    Debate about the epistemic prowess of historical science has focused on local underdetermination problems generated by a lack of historical data; the prevalence of information loss over geological time, and the capacities of scientists to mitigate it. Drawing on Leonelli’s recent distinction between ‘phenomena-time’ and ‘data-time’ I argue that factors like data generation, curation and management significantly complexifies and undermines this: underdetermination is a bad way of framing the challenges historical scientists face. In doing so, I identify circumstances of epistemic (...)
    Download  
     
    Export citation  
     
    Bookmark   4 citations  
  • Multiple-Models Juxtaposition and Trade-Offs among Modeling Desiderata.Yoshinari Yoshida - 2021 - Philosophy of Science 88 (1):103-123.
    This article offers a characterization of what I call multiple-models juxtaposition, a strategy for managing trade-offs among modeling desiderata. MMJ displays models of distinct phenomena to...
    Download  
     
    Export citation  
     
    Bookmark   2 citations  
  • Method Pluralism, Method Mismatch, & Method Bias.Adrian Currie & Shahar Avin - 2019 - Philosophers' Imprint 19.
    Pluralism about scientific method is more-or-less accepted, but the consequences have yet to be drawn out. Scientists adopt different methods in response to different epistemic situations: depending on the system they are interested in, the resources at their disposal, and so forth. If it is right that different methods are appropriate in different situations, then mismatches between methods and situations are possible. This is most likely to occur due to method bias: when we prefer a particular kind of method, despite (...)
    Download  
     
    Export citation  
     
    Bookmark   9 citations  
  • Generality and Causal Interdependence in Ecology.Alkistis Elliott-Graves - 2018 - Philosophy of Science 85 (5):1102-1114.
    A hallmark of ecological research is dealing with complexity in the systems under investigation. One strategy is to diminish this complexity by constructing models and theories that are general. Alternatively, ecologists can constrain the scope of their generalizations to particular phenomena or types of systems. However, research employing the second strategy is often met with scathing criticism. I offer a theoretical argument in support of moderate generalizations in ecological research, based on the notions of interdependence and causal heterogeneity and their (...)
    Download  
     
    Export citation  
     
    Bookmark   11 citations  
  • Indexically Structured Ecological Communities.Christopher Hunter Lean - 2018 - Philosophy of Science 85 (3):501-522.
    Ecological communities are seldom, if ever, biological individuals. They lack causal boundaries as the populations that constitute communities are not congruent and rarely have persistent functional roles regulating the communities’ higher-level properties. Instead we should represent ecological communities indexically, by identifying ecological communities via the network of weak causal interactions between populations that unfurl from a starting set of populations. This precisification of ecological communities helps identify how community properties remain invariant, and why they have robust characteristics. This respects the (...)
    Download  
     
    Export citation  
     
    Bookmark   10 citations  
  • Strategies of model-building in condensed matter physics: trade-offs as a demarcation criterion between physics and biology?Axel Gelfert - 2013 - Synthese 190 (2):253-272.
    This paper contrasts and compares strategies of model-building in condensed matter physics and biology, with respect to their alleged unequal susceptibility to trade-offs between different theoretical desiderata. It challenges the view, often expressed in the philosophical literature on trade-offs in population biology, that the existence of systematic trade-offs is a feature that is specific to biological models, since unlike physics, biology studies evolved systems that exhibit considerable natural variability. By contrast, I argue that the development of ever more sophisticated experimental, (...)
    Download  
     
    Export citation  
     
    Bookmark   2 citations  
  • A strategy to what end? “The strategy of model building in population biology” in its programmatic context.Zvi Hasnes-Beninson - 2024 - History and Philosophy of the Life Sciences 46 (4):1-33.
    “The Strategy of Model Building in Population Biology” published by Richard Levins in 1966 has been cited over 2500 times. For a paper concerned with modeling approaches in population biology a surprisingly large part of the attention. The Strategy received comes from history and philosophy of biology, and specifically from accounts on model and model formulation. The Strategy is an unusual paper; it presents neither new data nor a new formal model; at times it reads like a manifesto for some (...)
    Download  
     
    Export citation  
     
    Bookmark  
  • The strategy of model building in climate science.Lachlan Douglas Walmsley - 2020 - Synthese 199 (1-2):745-765.
    In the 1960s, theoretical biologist Richard Levins criticised modellers in his own discipline of population biology for pursuing the “brute force” strategy of building hyper-realistic models. Instead of exclusively chasing complexity, Levins advocated for the use of multiple different kinds of complementary models, including much simpler ones. In this paper, I argue that the epistemic challenges Levins attributed to the brute force strategy still apply to state-of-the-art climate models today: they have big appetites for unattainable data, they are limited by (...)
    Download  
     
    Export citation  
     
    Bookmark   2 citations  
  • Newton on Islandworld: Ontic-Driven Explanations of Scientific Method.Adrian Currie & Kirsten Walsh - 2018 - Perspectives on Science 26 (1):119-156.
    . Philosophers and scientists often cite ontic factors when explaining the methods and success of scientific inquiry. That is, the adoption of a method or approach is explained in reference to the kind of system in which the scientist is interested: these are explanations of why scientists do what they do, that appeal to properties of their target systems. We present a framework for understanding such “Opticks to his Principia. Newton’s optical work is largely experiment-driven, while the Principia is primarily (...)
    Download  
     
    Export citation  
     
    Bookmark   7 citations  
  • What are general models about?Alkistis Elliott-Graves - 2022 - European Journal for Philosophy of Science 12 (4):1–26.
    Models provide scientists with knowledge about target systems. An important group of models are those that are called general. However, what exactly is meant by generality in this context is somewhat unclear. The aim of this paper is to draw out a distinction between two notions of generality that has implications for scientific practice. Some models are general in the sense that they apply to many systems in the world and have many particular targets. Another sense is captured by models (...)
    Download  
     
    Export citation  
     
    Bookmark  
  • Non-equilibrium thermodynamics and the free energy principle in biology.Matteo Colombo & Patricia Palacios - 2021 - Biology and Philosophy 36 (5):1-26.
    According to the free energy principle, life is an “inevitable and emergent property of any random dynamical system at non-equilibrium steady state that possesses a Markov blanket” :20130475, 2013). Formulating a principle for the life sciences in terms of concepts from statistical physics, such as random dynamical system, non-equilibrium steady state and ergodicity, places substantial constraints on the theoretical and empirical study of biological systems. Thus far, however, the physics foundations of the free energy principle have received hardly any attention. (...)
    Download  
     
    Export citation  
     
    Bookmark   16 citations  
  • The epistemic benefits of generalisation in modelling I: Systems and applicability.Aki Lehtinen - 2021 - Synthese 199 (3-4):10343-10370.
    This paper provides a conceptual framework that allows for distinguishing between different kinds of generalisation and applicability. It is argued that generalising models may bring epistemic benefits. They do so if they show that restrictive and unrealistic assumptions do not threaten the credibility of results derived from models. There are two different notions of applicability, generic and specific, which give rise to three different kinds of generalizations. Only generalising a result brings epistemic benefits concerning the truth of model components or (...)
    Download  
     
    Export citation  
     
    Bookmark   6 citations  
  • Microbes, mathematics, and models.Maureen A. O'Malley & Emily C. Parke - 2018 - Studies in History and Philosophy of Science Part A 72:1-10.
    Microbial model systems have a long history of fruitful use in fields that include evolution and ecology. In order to develop further insight into modelling practice, we examine how the competitive exclusion and coexistence of competing species have been modelled mathematically and materially over the course of a long research history. In particular, we investigate how microbial models of these dynamics interact with mathematical or computational models of the same phenomena. Our cases illuminate the ways in which microbial systems and (...)
    Download  
     
    Export citation  
     
    Bookmark   3 citations  
  • Geoengineering Tensions.Adrian Currie - forthcoming - Futures.
    There has been much discussion of the moral, legal and prudential implications of geoengineering, and of governance structures for both the research and deployment of such technologies. However, insufficient attention has been paid to how such measures might affect geoengineering in terms of the incentive structures which underwrite scientific progress. There is a tension between the features that make science productive, and the need to govern geoengineering research, which has thus far gone underappreciated. I emphasize how geoengineering research requires governance (...)
    Download  
     
    Export citation  
     
    Bookmark   2 citations  
  • A Cautionary Contribution to the Philosophy of Explanation in the Cognitive Neurosciences.A. Nicolás Venturelli - 2016 - Minds and Machines 26 (3):259-285.
    I propose a cautionary assessment of the recent debate concerning the impact of the dynamical approach on philosophical accounts of scientific explanation in the cognitive sciences and, particularly, the cognitive neurosciences. I criticize the dominant mechanistic philosophy of explanation, pointing out a number of its negative consequences: In particular, that it doesn’t do justice to the field’s diversity and stage of development, and that it fosters misguided interpretations of dynamical models’ contribution. In order to support these arguments, I analyze a (...)
    Download  
     
    Export citation  
     
    Bookmark   4 citations  
  • The problem of prediction in invasion biology.Alkistis Elliott-Graves - 2016 - Biology and Philosophy 31 (3):373-393.
    Invasion biology is a relatively young discipline which is important, interesting and currently in turmoil. Biological invaders can threaten native ecosystems and global biodiversity; they can incur massive economic costs and even introduce diseases. Invasion biologists generally agree that being able to predict when and where an invasion will occur is essential for progress in their field. However, successful predictions of this type remain elusive. This has caused a rift, as some researchers are pessimistic and believe that invasion biology has (...)
    Download  
     
    Export citation  
     
    Bookmark   11 citations  
  • The Limits of Our Explanation: A Case Study in Myxococcus xanthus Cooperation.Saira Khan - forthcoming - Biological Theory:1-16.
    In this article, I demonstrate two ways in which our major theories of the evolution of cooperation may fail to capture particular social phenomena. The first shortcoming of our current major theories stems from the possibility of mischaracterizing the cooperative problem in game theory. The second shortcoming of our current major theories is the insensitivity of these explanatory models to ecological and genomic context. As a case study to illustrate these points, I will use the cooperative interaction of a species (...)
    Download  
     
    Export citation  
     
    Bookmark  
  • Bottled Understanding: The Role of Lab Work in Ecology.Adrian Currie - 2020 - British Journal for the Philosophy of Science 71 (3):905-932.
    It is often thought that the vindication of experimental work lies in its capacity to be revelatory of natural systems. I challenge this idea by examining laboratory experiments in ecology. A central task of community ecology involves combining mathematical models and observational data to identify trophic interactions in natural systems. But many ecologists are also lab scientists: constructing microcosm or ‘bottle’ experiments, physically realizing the idealized circumstances described in mathematical models. What vindicates such ecological experiments? I argue that ‘extrapolationism’, the (...)
    Download  
     
    Export citation  
     
    Bookmark   5 citations