2017
DOI: 10.1007/s00603-016-1164-0
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High-Speed Photography and Digital Optical Measurement Techniques for Geomaterials: Fundamentals and Applications

Abstract: Geomaterials (i.e., rock, sand, soil and concrete) are increasingly being encountered and used in extreme environments, in terms of the pressure magnitude and the loading rate. Advancing the understanding of the mechanical response of materials to impact loading relies heavily on having suitable high-speed diagnostics. One such diagnostic is high-speed photography, which combined with a variety of digital optical measurement techniques can provide detailed insights into phenomena including fracture, impact, fr… Show more

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Cited by 133 publications
(28 citation statements)
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References 266 publications
(268 reference statements)
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“…In addition, when processing digital images with DIC algorithms, the noise level of the camera needs to be extremely low, as it affects the quality of the displacement fields and especially the fields obtained through temporal and spatial differentiation, such as velocities and strains. These are very stringent requirements for a high-speed camera, since cameras in the ultrahigh-speed range (0.5 million frames/s and above) were traditionally based either on gateintensified technology (which produces noisy images) or rotating mirror systems (which can produce operational challenges at highframe rates due to the elevated rotating speeds) [77,[95][96][97]. On the other hand, cameras that have low noise levels typically are in the low range of frame rates, below what is needed for highly dynamic ruptures [77,96,97].…”
Section: Challenges In Developing Ultrahigh-speed Digitalmentioning
confidence: 99%
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“…In addition, when processing digital images with DIC algorithms, the noise level of the camera needs to be extremely low, as it affects the quality of the displacement fields and especially the fields obtained through temporal and spatial differentiation, such as velocities and strains. These are very stringent requirements for a high-speed camera, since cameras in the ultrahigh-speed range (0.5 million frames/s and above) were traditionally based either on gateintensified technology (which produces noisy images) or rotating mirror systems (which can produce operational challenges at highframe rates due to the elevated rotating speeds) [77,[95][96][97]. On the other hand, cameras that have low noise levels typically are in the low range of frame rates, below what is needed for highly dynamic ruptures [77,96,97].…”
Section: Challenges In Developing Ultrahigh-speed Digitalmentioning
confidence: 99%
“…These are very stringent requirements for a high-speed camera, since cameras in the ultrahigh-speed range (0.5 million frames/s and above) were traditionally based either on gateintensified technology (which produces noisy images) or rotating mirror systems (which can produce operational challenges at highframe rates due to the elevated rotating speeds) [77,[95][96][97]. On the other hand, cameras that have low noise levels typically are in the low range of frame rates, below what is needed for highly dynamic ruptures [77,96,97]. In addition, the high-speed systems acquire images via the presence of multiple sensors, which can introduce further complications in the process of correlation [77].…”
Section: Challenges In Developing Ultrahigh-speed Digitalmentioning
confidence: 99%
“…e maximum height of the pendulum in the first 6 slice tests is 0.5 m (6.50 × 10 6 J), and the pendulum in the 7 th slice test rises step by step until the coal and rock are destroyed. e test monitoring system included a DH960 superdynamic signal test and analysis system, a PIC-2 AE system, a Memrecam GX-3 high-speed camera, and pressure cells [26], and the layout is shown in Figure 5.…”
Section: Test Monitoring Equipment and Layoutmentioning
confidence: 99%
“…The stress components are computed using linear elastic plane-stress constitutive equations with the dynamic Young's modulus of Homalite to account for its strain-rate dependent behavior cameras with a frame rate above 1 million frames/s, referred to as ultrahigh-speed cameras, can achieve a high spatial resolution (in the megapixel range) but typically have a low record length and rather high electronic noise levels, while cameras that can attain a large number of recorded frames can do so at a low sampling rate. Recent advances in high-speed camera technologies have enabled a higher number of recorded frames in the ultrahigh-speed range [44]. While the spatial resolution of these cameras is still limited, their low noise level makes them good candidates for DIC [32,35].…”
Section: Introductionmentioning
confidence: 99%