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fuu leurdj fidhd.ekSug m%:u f,dj w;sYhska fõ.j;a leurdjla f,i ;snqfka ;;amrhg rEm rduq ñ,shkhla ,nd.; yels leurdjls'
th w;sYhska ñ, wêlh'
fujka leurdjka wêl jYfhka fhdod .efkkqfha l%slÜ ;rÛ j,§h"
kuq;a l%slÜ ;rÛ j,§ fhdod .kq ,nk “Ultra Slow Motion” leurdfjka ,nd.; yelafla ;;amrhg rEm 1000 la muKh'
fï ishÆ leurdjka wNsNjd hñka fuu leurdj ks¾udKh lr we;af;a “MIT ^Massachusetts Institute of Technology &” m¾fhaIl lKavdhula úisks'
fuu leurdj u.ska wdf,dalh .uka lsÍu mjd b;d fiñka kerôh yel''
Ever wondered what video would look like at 1 trillion frames per second? To put this in perspective, your average consumer video camera captures video at 29.97 frames per second. Slow motion is created through the addition of frames. So, 1 trillion frames would make light, the fastest thing in the universe, look slow. Now, scientists at MIT’s MediaLab have made this phenomenon possible through a video technique that will change the future of digital imaging.
According to Ramesh Raskar, Associate Professor at MIT’s MediaLab, “Such a camera may be useful in medical imaging, in industrial or scientific use, and in the future even for consumer photography. In medical imaging, now we can do ultrasound with light, because we can analyze how light will scatter one-dimensionally inside the body. In industrial imaging, one can use the scattered light to analyze defects in materials. And in consumer photography, we are always fascinated with creating lighting effects that appear to come from very sophisticated light sources.”