An Examination of Intercollegiate Athletic Injury Tracking Systems Within Canadian Universities

Information regarding the practice of athletic injury tracking within Canadian intercollegiate institutions has been relatively deficient. The study aimed to assess the current status of athletic injury tracking systems (AITS) in Canadian universities within the Canadian Interuniversity Sport Association (CIS). A secondary purpose was to obtain data from therapists within Canadian Universities, to identify and analyze issues, benefits, barriers and obtain information regarding how athletic injury tracking methods are conducted. This was achieved by obtaining data regarding the current state of AITS in CIS institutions, clinical demographics, athletic therapists and/or physiotherapists’ opinions regarding the pro’s and con’s of athletic injury tracking and AITS protocol implemented within each institution across the CIS. The study had a sample of 45 athletic therapists and/or physiotherapists, representing 38 universities that are members of the CIS. Results of this study suggest that there is no standard in place for athletic injury tracking in Canadian universities. Nine universities are currently tracking athletic injuries, while twenty-nine universities are not tracking athletic injuries through a formalized athletic injury tracking program. The majority of therapists recognized benefits of injury tracking and believed that injury prevention and injury management can be achieved though understanding trends that occur within athletic injuries. The three primary barriers reported as to why universities are not tracking athletic injuries were: time, funding, and resources. The results of the study indicated that although there are recognized barriers, the majority of responding therapists were interested in tracking athletic injuries within their respective institutions through a more formalized system. Additionally the majority of therapists indicated their interest in forming a collaboration to participate in a national injury tracking system among member institutions of the CIS

An Intelligent Fuse-box for use with Renewable Energy Sources integrated within a Domestic Environment

This paper outlines a proposal for an intelligent fuse-box that can replace existing fuse-boxes in a domestic context such that a number of renewable energy sources can easily be integrated into the domestic power supply network, without the necessity for complex islanding and network protection. The approach allows intelligent control of both the generation of power and its supply to single or groups of electrical appliances. Energy storage can be implemented in such a scheme to even out the power supplied and simplify the control scheme required, and environmental monitoring and load analysis can help in automatically controlling the supply and demand profiles for optimum electrical and economic efficiency. Simulations of typical scenarios are carried out to illustrate the concept in operation

C3TM: CEI CCD charge transfer model for radiation damage analysis and testing

Radiation induced defects in the silicon lattice of Charge Couple Devices (CCDs) are able to trap electrons during read out and thus create a smearing effect that is detrimental to the scientific data. To further our understanding of the positions and properties of individual radiation-induced traps and how they affect space- borne CCD performance, we have created the Centre for Electronic Imaging (CEI) CCD Charge Transfer Model (C3TM). This model simulates the physical processes taking place when transferring signal through a radiation damaged CCD. C3TM is a Monte Carlo model based on Shockley-Read-Hall theory, and it mimics the physical properties in the CCD as closely as possible. It runs on a sub-electrode level taking device specific charge density simulations made with professional TCAD software as direct input. Each trap can be specified with 3D positional information, emission time constant and other physical properties. The model is therefore also able to simulate multi-level clocking and other complex clocking schemes, such as trap pumping

Efficient table-top dual-wavelength beamline for ultrafast transient absorption spectroscopy in the soft X-ray region.

We present a table-top beamline providing a soft X-ray supercontinuum extending up to 370 eV from high-order harmonic generation with sub-13 fs 1300 nm driving pulses and simultaneous production of sub-5 fs pulses centered at 800 nm. Optimization of high harmonic generation in a long and dense gas medium yields a photon flux of  ~ 1.4 × 106 photons/s/1% bandwidth at 300 eV. The temporal resolution of X-ray transient absorption experiments with this beamline is measured to be 11 fs for 800 nm excitation. This dual-wavelength approach, combined with high flux and high spectral and temporal resolution soft X-ray absorption spectroscopy, is a new route to the study of ultrafast electronic dynamics in carbon-containing molecules and materials at the carbon K-edge

Optimizing the Jiles-Atherton Model of Hysteresis by a genetic algorithm

Modeling magnetic components for simulation in electric circuits requires an accurate model of the hysteresis loop of the core material used. It is important that the parameters extracted for the hysteresis model be optimized across the range of operating conditions that may occur in circuit simulation. This paper shows how to extract optimal parameters for the Jiles-Atherton model of hysteresis by the genetic algorithm approach. It compares performance with the well-known simulated annealing method and demonstrates that improved results may be obtained with the genetic algorithm. It also shows that a combination of the genetic algorithm and the simulated annealing method can provide an even more accurate solution that either method on its own. A statistical analysis shows that the optimization obtained by the genetic algorithm is better on average, not just on a one-off test basis. The paper introduces and applies the concept of simultaneous optimization for major and minor hysteresis loops to ensure accurate model optimization over a wide variety of operating conditions. It proposes a modification to the Jiles-Atherton model to allow improved accuracy in the modeling of the major loop