Star length distribution:​ a volume-based concept for the characterization of structural anisotropy

Smit, Th. H.; Schneider, E.; Odgaard, A.

Affiliations

¹Biomechanics Section, Technical University Hamburg-Harburg, Hamburg, Germany

²Biomechanics Laboratory, Orthopaedics Hospital, University of Aarhus, Aarhus, Denmark

Abstract and keywords

Determination and quantification of anisotropy is of great interest in research fields dealing with physical structures or surface textures. In this paper, a volume-based method is presented, which essentially determines the mean object length in a certain direction for a typical point within a structure or texture. The mean object lengths for all orientations together form the so-called star length distribution (SLD). The validity and the accuracy of the SLD method are investigated, and illustrated by applying it to trabecular bone. By using a line sampling algorithm, the relation with other anisotropy measures could be studied analytically. Preliminary tests suggest that with SLD a more exact description of the mechanical properties of porous structures may be obtained than with other anisotropy measures. However, due to possible secondary orientations that become apparent with SLD, a fabric tensor must be of rank higher than two in order to properly describe an orthogonal structure mathematically.

Keywords: Anisotropy; mean intercept length; porous media; star length distribution; star volume distribution; volume orientation

Links

DOI: 10.1046/j.1365-2818.1998.00394.x

PubMed: 9755497

WoS: 000076022700004

History

Received: 1997-06-24

Accepted: 1998-04-17

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