01273nam 2200337Ia 450 99638652420331620200824132603.0(CKB)4940000000077284(EEBO)2240960643(OCoLC)ocm12425310e(OCoLC)12425310(EXLCZ)99494000000007728419850826d1642 uy |engurbn||||a|bb|The priviledges of the baronage of England, when they sit in Parliament[electronic resource] /collected (and of late revised) by John Selden of the Inner Temple Esquire, out of Parliament rolles ... & and other good authorities ... : the recitalls of the French records in the 4th. chap., also newly translated into English ..London Printed by T. Badger for Matthew Wallbanck ...1642[7], 167 pReproduction of original in British Library.eebo-0018NobilityGreat BritainNobilitySelden John1584-1654.514618EAAEAAm/cWaOLNBOOK996386524203316The priviledges of the baronage of England when they sit in Parliament2389102UNISA05069nam 2201261z- 450 9910404087503321202102113-03928-515-7(CKB)4100000011302263(oapen)https://directory.doabooks.org/handle/20.500.12854/40258(oapen)doab40258(EXLCZ)99410000001130226320202102d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierAdvances in Digital Image Correlation (DIC)MDPI - Multidisciplinary Digital Publishing Institute20201 online resource (252 p.)3-03928-514-9 Digital 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.Advances in Digital Image CorrelationHistory of engineering and technologybicssc3D deformation3D digital image correlationaccuracyacoustic emission techniquearch structuresautomated composite manufacturingautomated fiber placement (AFP)automated systemscharacterization of composite materialscomposite inspectioncomposite materialscomposite structurescopper platecross dichroic prismDICdigital image correlationDigital image correlation (DIC)digital image correlation techniquedigital volume correlationdigital volumetric speckle photographydynamic interfacial ruptureearthquake ruptureelevated temperatureerrorexperimental mechanicsexperimental-numerical methodfault geometryfinite element methodfinite element model updatingfracture process zonegeosciencesgradient correlation functionshigh-speed cameraimage classificationimage correlationimage cross-correlationimage registrationimage shadowinginitial conditioninterior 3D deformationinterlaminar tensile strengthinverse methodlarge deformationlaser speckleslayered materialmachine learningmeasurementmonitoringmulti-perspectiven/anon-contact measurementnon-contact video gaugenon-liner dynamic deformationoptical coherence elastographyred sandstonerupture speedsingle cameraslip velocityspatial sampling ratespatiotemporal evolutionstatic analysisstrainstrain gagestrain measurementstress concentrationstress intensity factorstress-strain relationshipstructural testingsuper pressure balloontraceable calibrationtraction continuity across interfacesunderwater impulsive loadinguniaxial tensile testvirtual fields methodwoven composite beamX-ray microtomographyHistory of engineering and technologyPassieux Jean-Charlesauth1331099Perie Jean-NoelauthBOOK9910404087503321Advances in Digital Image Correlation (DIC)3040128UNINA