An early review of stroboscopic visual training: insights,challenges and accomplishments to guide future studies

ABSTRACT

Stroboscopic visual training (SVT) is a form of training in which an individual practices a task under intermittent visual conditions with the intention of enhancing subsequent performance under normal visual conditions. Training with stroboscopic devices is theorized to improve important visual, perceptual, and cognitive skills, which in turn transfers to enhanced sporting performance. Indeed, while there is an abundance of anecdotal evidence suggesting benefits of strobe training, empirical evidence is rarer and less conclusive. This lack of clarity is due, in part, to the challenging methodological issues faced when conducting experimental vision training studies in applied contexts. The present paper is an early review of the research to date with a focus on the key methodological decisions, such as the training and testing protocols employed, participant samples and control groups used, and practical considerations that enable such training in applied settings. Whilst still at an early stage, the existing studies point to SVT enhancing some aspects of foveal visual sensitivity and visual motor control, with notable benefits for some athletic tasks. Such improvements could have implications not just in sport, but in domains such as rehabilitation, education, and motor vehicle safety.     

W.W. Alexander’s reflections on Britain at the Olympic Games, 1908–1912

William Whiteway (W.W.) Alexander (b.1852) was a prominent figure in Midlands athletics from the 1890s to the 1930s. Primarily, he is remembered for his impact upon Birmingham’s Birchfield Harriers Athletic Club, whose stadium in Perry Barr bears his name. Alexander’s involvement went far beyond the club, as he served as a prominent administrator of the sport and wrote a weekly column in the Birmingham sporting newspaper The Sporting Mail. This article will examine Alexander’s comments regarding the Olympic Games of London (1908) and Stockholm (1912), where he provides an alternative perspective on the British attitude at these Games and offers possible reasons as to why the British performance declined.     

Teaching practices of the undergraduate introductory biomechanics faculty: a North American survey

Instruction and assessment strategies of undergraduate introductory biomechanics instructors have yet to be comprehensively examined. The purpose of this study was to identify the current instruction and assessment practices of North American undergraduate introductory biomechanics instructors and equipment needed for effective instruction in lecture and laboratory sessions. One hundred and sixty-five respondents (age: 42.5 ± 10.3 years) who currently teach or have taught an introductory biomechanics course in North America were recruited by electronic mail. Subjects completed a web-based survey, consisting of 60 open- and closed-ended questions. Pearson's correlation coefficients were used to assess relationships between instructor's familiarity with either the Biomechanics Concept Inventory or the NASPE Guidelines for Undergraduate Biomechanics, and instructor and course characteristics (number of years teaching, age, faculty rank, number of quizzes given, etc.) A number of variables were significantly (p < 0.05) correlated. Answers to open-ended questions were processed using content analysis, with results categorized in content areas including: instructor and course characteristics; lecture instruction; assessment and equipment; laboratory instruction; assessment and equipment; and instructor's perspectives. Many active learning strategies for lecture and laboratory instruction were identified by faculty. Limited student preparation and limited resources were noted as the instructor's most common challenges.     

Systematic characterization of degas-driven flow for poly(dimethylsiloxane) microfluidic devices

Degas-driven flow is a novel phenomenon used to propel fluids in poly(dimethylsiloxane) (PDMS)-based microfluidic devices without requiring any external power. This method takes advantage of the inherently high porosity and air solubility of PDMS by removing air molecules from the bulk PDMS before initiating the flow. The dynamics of degas-driven flow are dependent on the channel and device geometries and are highly sensitive to temporal parameters. These dependencies have not been fully characterized, hindering broad use of degas-driven flow as a microfluidic pumping mechanism. Here, we characterize, for the first time, the effect of various parameters on the dynamics of degas-driven flow, including channel geometry, PDMS thickness, PDMS exposure area, vacuum degassing time, and idle time at atmospheric pressure before loading. We investigate the effect of these parameters on flow velocity as well as channel fill time for the degas-driven flow process. Using our devices, we achieved reproducible flow with a standard deviation of less than 8% for flow velocity, as well as maximum flow rates of up to 3 nL∕s and mean flow rates of approximately 1-1.5 nL∕s. Parameters such as channel surface area and PDMS chip exposure area were found to have negligible impact on degas-driven flow dynamics, whereas channel cross-sectional area, degas time, PDMS thickness, and idle time were found to have a larger impact. In addition, we develop a physical model that can predict mean flow velocities within 6% of experimental values and can be used as a tool for future design of PDMS-based microfluidic devices that utilize degas-driven flow.     

Accelerated HE digitalisation: Exploring staff and student experiences of the COVID-19 rapid online-learning transfer

Education and Information Technologies - In the UK, the first ‘lockdown’ of the COVID-19 pandemic necessitated a rapid shift to online learning and digital technologies in Higher...     

Injecting failure: Data center infrastructures and the imaginaries of resilience

Abstract

Data center infrastructures provide a lens for understanding the rise of resilience thinking, for grasping the pragmatism and promise of resilience as approach. Unable to anticipate every threat and lockout every contingency, developers of resilient infrastructure “design in” failure, automate monitoring and maintenance, and build capacity to flexibly adapt to new threats. In enacting resilience in the present, they anticipate possible futures, prototyping forms of future life. In this sense, infrastructures should also be understood as operational imaginaries – as systems that powerfully suggest a set of future possibilities by enacting them concretely in the present.