- Research Fields수리모델연구부
- AuthorKang, Seung-Ho, Cho, Jung-Hee;Lee, Sang-Hee.
-
JournalJournal of Asia-Pacific entomology 17(2), 143-149 (2014
- Classification of papersSCI
Identification of butterfly species is essential because they are directly associated with crop plants used for
human and animal consumption. However, the widely used reliable methods for butterfly identification are
not efficient due to complicated butterfly shapes. We previously developed a novel shape recognition method
that uses branch length similarity (BLS) entropy, which is a simple branching network consisting of a single
node and branches. The method has been successfully applied to recognize battle tanks and characterize
human faces with different emotions. In the present study, we used the BLS entropy profile (an assemble of
BLS entropies) as an input feature in a feed-forward back-propagation artificial neural network to identify
butterfly species according to their shapes when viewed from different angles (for vertically adjustable angle,
θ = ±10°, ±20°, …, ±60° and for horizontally adjustable angle, φ = ±10°, ±20°, …, ±60°). In the field,
butterfly images are generally captured obliquely by camera due to butterfly alignment and viewer positioning,
which generates various shapes for a given specimen. To generate different shapes of a butterfly when viewed
from different angles, we projected the shapes captured from top-view to a plane rotated through angles θ and
φ. Projected shapes with differing θ and φ values were used as training data for the neural network and other
shapes were used as test data. Experimental results showed that our method successfully identified various
butterfly shapes. In addition, we briefly discuss extension of the method to identify more complicated images
of different butterfly species.
Identification of butterfly species is essential because they are directly associated with crop plants used for
human and animal consumption. However, the widely used reliable methods for butterfly identification are
not efficient due to complicated butterfly shapes. We previously developed a novel shape recognition method
that uses branch length similarity (BLS) entropy, which is a simple branching network consisting of a single
node and branches. The method has been successfully applied to recognize battle tanks and characterize
human faces with different emotions. In the present study, we used the BLS entropy profile (an assemble of
BLS entropies) as an input feature in a feed-forward back-propagation artificial neural network to identify
butterfly species according to their shapes when viewed from different angles (for vertically adjustable angle,
θ = ±10°, ±20°, …, ±60° and for horizontally adjustable angle, φ = ±10°, ±20°, …, ±60°). In the field,
butterfly images are generally captured obliquely by camera due to butterfly alignment and viewer positioning,
which generates various shapes for a given specimen. To generate different shapes of a butterfly when viewed
from different angles, we projected the shapes captured from top-view to a plane rotated through angles θ and
φ. Projected shapes with differing θ and φ values were used as training data for the neural network and other
shapes were used as test data. Experimental results showed that our method successfully identified various
butterfly shapes. In addition, we briefly discuss extension of the method to identify more complicated images
of different butterfly species.