3,366 research outputs found

    Colin Humphris

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    "Colin Humphris 2 Sqdrn. RAAF. 1941 - 1942 Author of - 'Trapped on Timor' (as a result of bombing of Darwin Feb. 19, 1942)".Colin Humphris. 2 Squadron, Royal Australian Air Force 1941 - 1942. Author of - 'Trapped on Timor' (as a result of bombing of Darwin February 19, 1942)

    Interview with Colin Wilson, part 4, undated

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    Interview with Colin Wilson, part 4, features an interview with author Colin Wilson in which he discusses his views regarding society and art, his reclusive nature, and the intellectual and fantastical elements of his works, undated

    Interview with Colin Wilson, part 2, undated

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    Interview with Colin Wilson, part 2, features an interview with author Colin Wilson in which he discusses his views regarding society and art, his reclusive nature, and the intellectual and fantastical elements of his works, undated

    Providence College Faculty Author Series 2017-2018: D. Colin Jaundrill

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    In this installment of the Faculty Authors Series, D. Colin Jaundrill (History, Providence College) discusses his newest book, Samurai to Soldier: Remaking Military Service in Nineteenth-Century Japan

    Providence College Faculty Author Series 2017-2018: D. Colin Jaundrill

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    In this installment of the Faculty Authors Series, D. Colin Jaundrill (History, Providence College) discusses his newest book, Samurai to Soldier: Remaking Military Service in Nineteenth-Century Japan

    Energy conserving upwinded compatible finite element schemes for the rotating shallow water equations

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    We present an energy conserving space discretisation of the rotating shallow water equations using compatible finite elements. It is based on an energy and enstrophy conserving Hamiltonian formulation as described in McRae and Cotter (2014), and extends it to include upwinding in the velocity and depth advection to increase stability. Upwinding for velocity in an energy conserving context was introduced for the incompressible Euler equations in Natale and Cotter (2017), while upwinding in the depth field in a Hamiltonian finite element context is newly described here. The energy conserving property is validated by coupling the spatial discretisation to an energy conserving time discretisation. Further, the discretisation is demonstrated to lead to an improved field development with respect to stability when upwinding in the depth field is included.18 pages, 8 figures, first version: all comments welcom

    Interview with Colin Jerolmack

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    Colin Jerolmack is an Assistant Professor at New York University in Sociology and Environmental Studies. He is the author of The Global Pigeon (forthcoming) and an alumnus of the Robert Wood Johnson Foundation Scholars in Health Policy Program at Harvard University

    Colin Fraser

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    Photograph - Colin Fraser (third from right) in a loaded scow leaving for Fort Chipewyan from Athabasca, Alberta. A group of men are also standing on the pie

    The ‘recovered space’ advection scheme for lowest-order compatible finite element methods

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    This is the author accepted manuscript. The final version is available from the publisher via the DOI in this record.We present a new compatible finite element advection scheme for the compressible Euler equations. Unlike the discretisations described in Cotter and Kuzmin (2016) and Shipton et al. (2018), the discretisation uses the lowest-order family of compatible finite element spaces, but still retains second-order numerical accuracy. This scheme obtains this second-order accuracy by first ‘recovering’ the function in higher-order spaces, before using the discontinuous Galerkin advection schemes of Cotter and Kuzmin (2016). As well as describing the scheme, we also present its stability properties and a strategy for ensuring boundedness. We then demonstrate its properties through some numerical tests, before presenting its use within a model solving the compressible Euler equations.Engineering and Physical Science Research Council (EPSRC

    From Foucauldian Biopower to Energopower and Infopower:An Interview with Dominic Boyer and Colin Koopman

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    Kirsten Hasberg talks to Dominic Boyer, anthropologist and author of Energopolitics: Wind and Power in the Anthroprocene, and to Colin Koopman, philosopher and author of How We Became our Data: A Genealogy of the Informational Person. Their books published in mid-2019 put forward novel conceptualizations of Foucauldian biopower, which they term infopower and energopower, respectively. Criss-crossing between philosophical conceptualizations and concrete problems like the struggles of renewable energy communities (Boyer) and the influence of economic thinking on datafication (Koopman), the conversations show how Foucauldian concepts are relevant to today's power struggles inherent to the energy transition and the digital transformation.Kirsten Hasberg talks to Dominic Boyer, anthropologist and author of Energopolitics: Wind and Power in the Anthroprocene, and to Colin Koopman, philosopher and author of How We Became our Data: A Genealogy of the Informational Person. Their books published in mid-2019 put forward novel conceptualizations of Foucauldian biopower, which they term infopower and energopower, respectively. Criss-crossing between philosophical conceptualizations and concrete problems like the struggles of renewable energy communities (Boyer) and the influence of economic thinking on datafication (Koopman), the conversations show how Foucauldian concepts are relevant to today's power struggles inherent to the energy transition and the digital transformation
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