LEADER 04916nam 2201213z- 450 001 9910404087503321 005 20231214133614.0 010 $a3-03928-515-7 035 $a(CKB)4100000011302263 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/40258 035 $a(EXLCZ)994100000011302263 100 $a20202102d2020 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aAdvances in Digital Image Correlation (DIC) 210 $cMDPI - Multidisciplinary Digital Publishing Institute$d2020 215 $a1 electronic resource (252 p.) 311 $a3-03928-514-9 330 $aDigital image correlation (DIC) has become the most popular full field measurement technique in experimental mechanics. It is a versatile and inexpensive measurement method that provides a large amount of experimental data. Because DIC takes advantage of a huge variety of image modalities, the technique allows covering a wide range of space and time scales. Stereo extends the scope of DIC to non-planar cases, which are more representative of industrial use cases. With the development of tomography, digital volume correlation now provides access to volumetric data, enabling the study of the inner behavior of materials and structures.However, the use of DIC data to quantitatively validate models or accurately identify a set of constitutive parameters remains challenging. One of the reasons lies in the compromises between measurement resolution and spatial resolution. Second, the question of the boundary conditions is still open. Another reason is that the measured displacements are not directly comparable with usual simulations. Finally, the use of full field data leads to new computational challenges. 517 $aAdvances in Digital Image Correlation 610 $aimage classification 610 $anon-contact video gauge 610 $aX-ray microtomography 610 $ainitial condition 610 $aaccuracy 610 $adigital image correlation technique 610 $adigital volume correlation 610 $aoptical coherence elastography 610 $aautomated fiber placement (AFP) 610 $acopper plate 610 $arupture speed 610 $alayered material 610 $anon-liner dynamic deformation 610 $acomposite inspection 610 $aautomated systems 610 $afinite element method 610 $astrain measurement 610 $avirtual fields method 610 $adigital volumetric speckle photography 610 $aspatiotemporal evolution 610 $anon-contact measurement 610 $acomposite materials 610 $astrain 610 $ainterior 3D deformation 610 $ahigh-speed camera 610 $agradient correlation functions 610 $aspatial sampling rate 610 $astress intensity factor 610 $astatic analysis 610 $afinite element model updating 610 $afracture process zone 610 $aelevated temperature 610 $ageosciences 610 $amonitoring 610 $ared sandstone 610 $astructural testing 610 $across dichroic prism 610 $aarch structures 610 $atraceable calibration 610 $astress concentration 610 $afault geometry 610 $aslip velocity 610 $auniaxial tensile test 610 $aexperimental mechanics 610 $amulti-perspective 610 $aimage registration 610 $asuper pressure balloon 610 $astress-strain relationship 610 $aerror 610 $ameasurement 610 $aearthquake rupture 610 $aacoustic emission technique 610 $acomposite structures 610 $a3D deformation 610 $atraction continuity across interfaces 610 $aDIC 610 $alaser speckles 610 $aimage shadowing 610 $adynamic interfacial rupture 610 $aDigital image correlation (DIC) 610 $astrain gage 610 $ainverse method 610 $adigital image correlation 610 $acharacterization of composite materials 610 $aautomated composite manufacturing 610 $awoven composite beam 610 $amachine learning 610 $aexperimental-numerical method 610 $a3D digital image correlation 610 $aunderwater impulsive loading 610 $aimage cross-correlation 610 $ainterlaminar tensile strength 610 $alarge deformation 610 $asingle camera 610 $aimage correlation 700 $aPassieux$b Jean-Charles$4auth$01331099 702 $aPerie$b Jean-Noel$4auth 906 $aBOOK 912 $a9910404087503321 996 $aAdvances in Digital Image Correlation (DIC)$93040128 997 $aUNINA