675 research outputs found
Screening for Parkinson’s Disease with Response Time Barriers: A Pilot Study
Background: Although significant response time deficits (both reaction time and movement time) have been identified in numerous studies of patients with Parkinson’s disease (PD), few attempts have been made to evaluate the use of these measures in screening for PD.
Methods: Receiver operator characteristic curves were used to identify cutoff scores for a unitweighted composite of two choice response tasks in a sample of 40 patients and 40 healthy participants. These scores were then cross-validated in an independent sample of 20 patients and 20 healthy participants.
Results: The unit-weighted movement time composite demonstrated high sensitivity (90%) and specificity (90%) in the identification of PD. Movement time was also significantly correlated (r = 0.59, p \u3c 0.025) with the motor score of the Unified Parkinson’s Disease Rating Scale (UPDRS).
Conclusions: Measures of chronometric speed, assessed without the use of biomechanically complex movements, have a potential role in screening for PD. Furthermore, the significant correlation between movement time and UPDRS motor score suggests that movement time may be useful in the quantification of PD severity
Origin of Disc Lopsidedness in the Eridanus Group of Galaxies
The HI surface density maps for a sample of 18 galaxies in the Eridanus group
are Fourier analysed. This analysis gives the radial variation of the
lopsidedness in the HI spatial distribution. The lopsidedness is quantified by
the Fourier amplitude of the component normalized to the average
value. It is also shown that in the radial region where the stellar disc and HI
overlap, their coefficients are comparable. All the galaxies studied show
significant lopsidedness in HI. The mean value of in the inner regions of
the galaxies (1.5 - 2.5 scale lengths) is . This value of is
twice the average value seen in the field galaxies. Also, the lopsidedness is
found to be smaller for late-type galaxies, this is opposite to the trend seen
in the field galaxies. These two results indicate a different physical origin
for disc lopsidedness in galaxies in a group environment compared to the field
galaxies. Further, a large fraction ( 30%) shows a higher degree of
lopsidedness (). It is also seen that the disk lopsidedness
increases with the radius as demonstrated in earlier studies, but over a radial
range that is two timeslarger than done in the previous studies. The average
lopsidedness of the halo potential is estimated to be %, assuming that
the lopsidedness in HI disc is due to its response to the halo asymmetry.Comment: 10 pages, 5 figures, Accepted for publication in MNRA
Design and Analysis of Soft-Error Resilience Mechanisms for GPU Register File
Modern graphics processing units (GPUs) are
using increasingly larger register file (RF) which occupies
a
large fraction of GPU core area and is very frequently access
ed.
This makes RF vulnerable to soft-errors (SE). In this paper,
we
present two techniques for improving SE resilience of GPU RF
.
First, we propose compressing the RF values for reducing the
number of vulnerable bits. We leverage value similarity and
the presence of narrow-width values to perform compression
at
warp or thread-level, respectively. Second, we propose sel
ective
hardening to design a portion of register entry with SE immun
e
circuits. By collectively using these techniques, higher r
esilience
can be provided with lower overhead. Without hardening, our
warp and thread-level compression techniques bring 47.0%
and 40.8% reduction in SE vulnerability, respectively
Electrode Heating in a Wire-to-Plane Arc
A steady wire-to-plane electric discharge has been modeled in a prolate spheroidal coordinate system with the wire shape taken as a hyperboloid of revolution. A set of continuum conservation equations for the charged particle densities and temperatures together with Poisson’s equation for the self-consistent electric potential describe the steady electric discharge process. These equations have been solved numerically to obtain ion and electron densities, temperature distribution, and electrode heat fluxes. Particle densities show the main body of the arc is quasineutral bounded by space charge sheaths at both electrodes. The temperature is greatest in a region around the discharge axis about one-third of the distance from the wire to the plane. Strong electric fields are concentrated in the electrode sheaths. The heat flux to the wire is sharply peaked near the tip but on the plane it decays slowly away from the discharge axis. The knowledge of heat transfer from the arc to the electrodes is useful in determining arc parameters that govern the ball formation process used in wire bonding of microelectronic semiconductor chips as well as welding processes
A Magellanic Origin for the Warp of the Galaxy
We show that a Magellanic Cloud origin for the warp of the Milky Way can
explain most quantitative features of the outer HI layer recently identified by
Levine, Blitz & Heiles (2005). We construct a model similar to that of Weinberg
(1998) that produces distortions in the dark matter halo, and we calculate the
combined effect of these dark-halo distortions and the direct tidal forcing by
the Magellanic Clouds on the disk warp in the linear regime. The interaction of
the dark matter halo with the disk and resonances between the orbit of the
Clouds and the disk account for the large amplitudes observed for the vertical
m=0,1,2 harmonics. The observations lead to six constraints on warp forcing
mechanisms and our model reasonably approximates all six. The disk is shown to
be very dynamic, constantly changing its shape as the Clouds proceed along
their orbit. We discuss the challenges to MOND placed by the observations.Comment: 4 pages, 3 figures, submitted to ApJ Letters. Additional graphics, 3d
visualizations and movies available at
http://www.astro.umass.edu/~weinberg/lm
Breakdown of a Wire-to-Plane Discharge: Transient Effects
A wire-to-plane discharge during the early phases of breakdown has been studied. The discharge has been modeled in a prolate spheroidal coordinate system with the wire shape taken as a hyperboloid of revolution. Four simultaneous coupled, time-dependent, nonlinear partial differential equations describe the electrical discharge. These are the conservation equations for ion and electron densities, the energy equation for electron temperature, and Poisson’s equation for the self-consistent electric field. By solving this formulation subject to appropriate initial and boundary conditions, charged particle densities and temperature variations have been obtained as the ionization progresses in the discharge. The results show that both the electron temperature and the charged particle densities increase with the progress of ionization. The effect of different wire polarities is also examined. With a positive wire polarity, the increases in electron temperature and charged particle densities are confined to regions of the discharge in the vicinity of the wire tip. With a negative wire polarity, the breakdown occurs in the entire gap at a faster rate than with a positive wire polarity. The wire polarity affects the magnitude of energy transfer between the particles
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