Learning Function Based Object Classification From 3D Imagery
Learning Function Based Object Classification from 3D Imagery.
CVIU, 2007
Online Version
A pdf version is available for download.
Abstract
We propose a novel scheme for using supervised learning for function based classification of objects in 3D images. During the learning process, a generic multi-level hierarchical description of object classes is constructed. The object classes are described in terms of functional components. The multi-level hierarchy is designed and constructed using a large set of signature-based reasoning and grading mechanisms. This set employs likelihood functions that are built as radial-based functions from the histograms of the object instances. During classification, a probabilistic matching measure is used to search through a finite graph to find the best assignment of geometric parts to the functional structures of each class. An object is assigned to the class that provides the highest matching value. Reuse of functional primitives in different classes enables easy expansion to new categories. We tested the proposed scheme on a database of about one thousand different 3D objects. The proposed scheme achieved high classification accuracy while using small training sets.
Keywords
Co-authors
Bibtex Entry
@article{PechukSR07a,
title = {Learning Function Based Object Classification from 3D Imagery},
author = {Michael Pechuk and Octavian Soldea and Ehud Rivlin},
year = {2007},
month = {April},
journal = {CVIU},
keywords = {Function-based reasoning; Object classification; 3D range data; supervised learning},
abstract = {We propose a novel scheme for using supervised learning for function based classification of objects in 3D images. During the learning process, a generic multi-level hierarchical description of object classes is constructed. The object classes are described in terms of functional components. The multi-level hierarchy is designed and constructed using a large set of signature-based reasoning and grading mechanisms. This set employs likelihood functions that are built as radial-based functions from the histograms of the object instances. During classification, a probabilistic matching measure is used to search through a finite graph to find the best assignment of geometric parts to the functional structures of each class. An object is assigned to the class that provides the highest matching value. Reuse of functional primitives in different classes enables easy expansion to new categories. We tested the proposed scheme on a database of about one thousand different 3D objects. The proposed scheme achieved high classification accuracy while using small training sets.}
}