Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow

Markus Hofinger, Thomas Pock, Thomas Moosbrugger

Publikation: KonferenzbeitragPaperForschungBegutachtung

Abstract

Wood-composite materials are widely used today as they homogenize humidity related directional deformations. Quantification of these deformations as coefficients is important for construction and engineering and topic of current research but still a manual process.
This work introduces a novel computer vision approach that automatically extracts these properties directly from scans of the wooden specimens, taken at different humidity levels during the long lasting humidity conditioning process. These scans are used to compute a humidity dependent deformation field for each pixel, from which the desired coefficients can easily be calculated.
The overall method includes automated registration of the wooden blocks, numerical optimization to compute a variational optical flow field which is further used to calculate dense strain fields and finally the engineering coefficients and their variance throughout the wooden blocks. The methods regularization is fully parameterizable which allows to model and suppress artifacts due to surface appearance changes of the specimens from mold, cracks, etc. that typically arise in the conditioning process.
Originalspracheenglisch
Seiten97 - 104
Seitenumfang8
PublikationsstatusVeröffentlicht - 5 Feb 2018
VeranstaltungComputer Vision Winter Workshop: 23rd Computer Vision Winter Workshop - Český Krumlov castle, Český Krumlov, Tschechische Republik
Dauer: 5 Feb 20187 Feb 2018
Konferenznummer: 23
http://cmp.felk.cvut.cz/cvww2018

Konferenz

KonferenzComputer Vision Winter Workshop
KurztitelCVWW 2018
LandTschechische Republik
OrtČeský Krumlov
Zeitraum5/02/187/02/18
Internetadresse

Fingerprint

Optical flows
Optical Flow
Humidity
Composite Materials
Atmospheric humidity
Wood
Composite materials
Conditioning
Coefficient
Engineering
Numerical Optimization
Regularization Method
Computer Vision
Quantification
Computer vision
Registration
Flow Field
Flow fields
Crack
Pixel

ASJC Scopus subject areas

  • !!Control and Optimization
  • !!Mechanics of Materials
  • !!Computer Vision and Pattern Recognition

Dies zitieren

Hofinger, M., Pock, T., & Moosbrugger, T. (2018). Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow. 97 - 104. Beitrag in Computer Vision Winter Workshop, Český Krumlov, Tschechische Republik.

Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow. / Hofinger, Markus; Pock, Thomas; Moosbrugger, Thomas.

2018. 97 - 104 Beitrag in Computer Vision Winter Workshop, Český Krumlov, Tschechische Republik.

Publikation: KonferenzbeitragPaperForschungBegutachtung

Hofinger, M, Pock, T & Moosbrugger, T 2018, 'Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow' Beitrag in, Český Krumlov, Tschechische Republik, 5/02/18 - 7/02/18, S. 97 - 104.
Hofinger M, Pock T, Moosbrugger T. Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow. 2018. Beitrag in Computer Vision Winter Workshop, Český Krumlov, Tschechische Republik.
Hofinger, Markus ; Pock, Thomas ; Moosbrugger, Thomas. / Robust Deformation Estimation in Wood-Composite Materials using Variational Optical Flow. Beitrag in Computer Vision Winter Workshop, Český Krumlov, Tschechische Republik.8 S.
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