TY - JOUR
T1 - Clustering-Driven Deep Embedding With Pairwise Constraints
AU - Fogel, Sharon
AU - Averbuch-Elor, Hadar
AU - Cohen-Or, Daniel
AU - Goldberger, Jacob
N1 - Publisher Copyright:
© 2019 IEEE.
PY - 2019/7/1
Y1 - 2019/7/1
N2 - Recently, there has been increasing interest to leverage the competence of neural networks to analyze data. In particular, new clustering methods that employ deep embeddings have been presented. In this paper, we depart from centroid-based models and suggest a new framework, called Clustering-driven deep embedding with PAirwise Constraints (CPAC), for nonparametric clustering using a neural network. We present a clustering-driven embedding based on a Siamese network that encourages pairs of data points to output similar representations in the latent space. Our pair-based model allows augmenting the information with labeled pairs to constitute a semi-supervised framework. Our approach is based on analyzing the losses associated with each pair to refine the set of constraints. We show that clustering performance increases when using this scheme, even with a limited amount of user queries. We demonstrate how our architecture is adapted for various types of data and present the first deep framework to cluster three-dimensional (3-D) shapes.
AB - Recently, there has been increasing interest to leverage the competence of neural networks to analyze data. In particular, new clustering methods that employ deep embeddings have been presented. In this paper, we depart from centroid-based models and suggest a new framework, called Clustering-driven deep embedding with PAirwise Constraints (CPAC), for nonparametric clustering using a neural network. We present a clustering-driven embedding based on a Siamese network that encourages pairs of data points to output similar representations in the latent space. Our pair-based model allows augmenting the information with labeled pairs to constitute a semi-supervised framework. Our approach is based on analyzing the losses associated with each pair to refine the set of constraints. We show that clustering performance increases when using this scheme, even with a limited amount of user queries. We demonstrate how our architecture is adapted for various types of data and present the first deep framework to cluster three-dimensional (3-D) shapes.
UR - http://www.scopus.com/inward/record.url?scp=85067618150&partnerID=8YFLogxK
U2 - 10.1109/MCG.2018.2881524
DO - 10.1109/MCG.2018.2881524
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C2 - 31226057
AN - SCOPUS:85067618150
SN - 0272-1716
VL - 39
SP - 16
EP - 27
JO - IEEE Computer Graphics and Applications
JF - IEEE Computer Graphics and Applications
IS - 4
M1 - 8739140
ER -