2013
DOI: 10.1117/12.2011762
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Kirana: a solid-state megapixel uCMOS image sensor for ultrahigh speed imaging

Abstract: This paper describes a solid-state sensor for ultra-high-speed (UHS) imaging. The 'Kirana' sensor was designed and manufactured in a 180 nm CMOS technology to achieve full-frame 0.7 Megapixel video capture at speeds at 2 MHz. The 30 µm pixels contain a pinned photodiode, a set of 180 low-leakage storage cells, a floating-diffusion, and a source follower output structure. Both the individual cells and the way they are arranged in the pixel are novel. The pixel architecture allows correlated double sampling for … Show more

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Cited by 49 publications
(28 citation statements)
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“…We use long-distance microscopes, primarily a Leica (Z16 APO), with pixel resolution down to 1.04 µm/px. The rapid surface motions during first contact require ultra-high-speed video, acquired with the Kirana-05M from Specialized Imaging in Tring, UK (Crooks et al (2013)), at frame rates up to 5 million fps. The extreme 200 ns time-resolution, allows us to follow individual fringes between video frames and eliminates some of the ambiguity at lower frame-rates, which has required color interferometry to get absolute layer thicknesses , de Ruiter et al (2012)).…”
Section: Optical and Imaging Setupmentioning
confidence: 99%
“…We use long-distance microscopes, primarily a Leica (Z16 APO), with pixel resolution down to 1.04 µm/px. The rapid surface motions during first contact require ultra-high-speed video, acquired with the Kirana-05M from Specialized Imaging in Tring, UK (Crooks et al (2013)), at frame rates up to 5 million fps. The extreme 200 ns time-resolution, allows us to follow individual fringes between video frames and eliminates some of the ambiguity at lower frame-rates, which has required color interferometry to get absolute layer thicknesses , de Ruiter et al (2012)).…”
Section: Optical and Imaging Setupmentioning
confidence: 99%
“…The advent of full-field optical metrology, such as digital image correlation [35] or the grid method [10], combined with the new developments in ultra-high speed imaging [2,29,36] provides a unique opportunity to revisit high strain-rate testing techniques. In particular, full-field of accelerations can be obtained which provides a powerful image-embedded load cell if the material density is known, which is usually the case.…”
Section: Introductionmentioning
confidence: 99%
“…However, in most of our work we use a different approach. With the 5 million fps Kirana video camera (16) we are able to follow interference fringes from one frame to the next and thereby keep track of absolute thicknesses, while using monochromatic light. This requires identifying the last fringe before the drop touches the solid surface, therefore allowing us to trace back the absolute thicknesses at earlier times, by keeping track of new fringe formations.…”
Section: Methodsmentioning
confidence: 99%
“…This requires identifying the last fringe before the drop touches the solid surface, therefore allowing us to trace back the absolute thicknesses at earlier times, by keeping track of new fringe formations. This camera is based on in-sensor image storage (3,4,16) and can acquire a sequence of 180 frames, which corresponds to a total clip duration of 36 µs at the highest frame-rate. This mandates the use of electronic triggering for which we use a laser/photo-diode circuit, which the drop interrupts during its free-fall.…”
Section: Methodsmentioning
confidence: 99%