SHAFAQNA (Shia International News Association) – Monday mornings pretty much always make me feel like blowing things up. So watching videos about things blowing up -- or people blowing things up -- seems to be a perfect way to ease into the work week.
Happily for my now-improving mood, demolition experts demolished a 1930s-era steel bridge along US 281 in Marble Falls, Texas over the weekend, and someone was there to film it. I love how the first two passes of the video -- real-time and semi-slo-mo -- it's difficult to see exactly how the demo goes. But the third time, look closely under the bridge. You can totally see the detonator cords burning up ahead of the ignition of the shaped charges that brought the trusses down. The video also clearly demonstrates the difference between the speed of light in air and the speed of sound in air -- the flashes from the charges are long gone by the time the sound waves make it to the filming location. According to a fact sheet from the Texas Department of Transportation, steel from the bridge will be recycled into "beautification projects." I read elsewhere that it'll be turned into sculptures or other pieces of public artwork.
This isn't the first time we've written about bridge demos. A couple of years ago, we ran a Megapixels about a bridge demolition in Ohio and West Virginia (the bridge spanned the Ohio River). During reporting, we learned that it required some 153 pounds of explosive to bring down that suspension bridge. The demolition occurred in multiple phases: cut the suspension cables, destroy the roadway and then topple the towers. To my glee, that demolition has a slow-motion video as well.-www.shafaqna.com/English
SHAFAQNA (Shia International News Association) — he researchers claim that because Attention Deficit Hyperactivity Disorder (ADHD), Fetal Alcohol Spectrum Disorder (FASD), and Parkinson’s disease each involve ocular control and attention dysfunctions, they can be easily identified through an evaluation of how patients move their eyes while they watch television.
“Natural attention and eye movement behavior—like a drop of saliva—contains a biometric signature of an individual and her/his state of brain function or dysfunction,” they write in the study, which is published in the Journal of Neurology.
“Such individual signatures, and especially potential biomarkers of particular neurological disorders which they may contain, however, have not yet been successfully decoded.”
Typical methods of detection—clinical evaluation, structured behavioral tasks, and neuroimaging—are costly, labor-intensive, and limited by a patient’s ability to understand and comply with instructions.
To solve this problem, doctoral student Po-He Tseng and Professor Laurent Itti of the department of computer science at the University of Southern California’s Viterbi School of Engineering, along with collaborators at Queen’s University in Canada, have devised the new screening method.
Participants in the study were simply instructed to “watch and enjoy” television clips for 20 minutes while their eye movements were recorded.
Eye-tracking data was then combined with normative eye-tracking data and a computational model of visual attention to extract 224 quantitative features, allowing the team to use new machine-learning techniques to identify critical features that differentiated patients from control subjects.
With eye movement data from 108 subjects, the team was able to identify older adults with Parkinson’s Disease with 89.6 percent accuracy, and children with either ADHD or FASD with 77.3 percent accuracy.
Providing new insights into which aspects of attention and gaze control are affected by specific disorders, the team’s method provides considerable promise as an easily deployed, low-cost, high-throughput screening tool, especially for young children and elderly populations who may be less compliant to traditional tests.
“For the first time, we can actually decode a person’s neurological state from their everyday behavior, without having to subject them to difficult or time-consuming tests,” Itti says.
Funding for the research came from the National Science Foundation, the Army Research Office, the Human Frontier Science Program, and the Canadian Institutes of Health Research.—www.shafaqna.com/English