Detection and correction of mislabeled samples based on graph structure

Volume 5, Issue 2, April 2021     |     PP. 12-33      |     PDF (2252 K)    |     Pub. Date: May 17, 2021
DOI: 10.54647/isss12083    78 Downloads     5494 Views  

Author(s)

Junyan Li, University of Kentucky, Lexington, Kentucky, United States
Xinxing Wu, University of Kentucky, Lexington, Kentucky, United States

Abstract
Machine learning trains and obtains learning models based on a large amount of training samples. Mislabeled training samples will affect the generalization/performance of the final predictive model. Some methods of detecting/correcting mislabeled samples such as graph-based methods, are proposed and used in machine learning to improve predictive models' generalization. However, these methods do not perform well for high-dimensional samples. In this paper, we present three algorithms for detecting/correcting mislabeled samples in high-dimensional feature space. First, we propose an improved high-dimensional detection algorithm: PCA-k-RNG. Next, we introduce a notion of ∈-scalar relative neighbourhood graph (∈-SRNG) and study its relationship with relative neighbourhood graph (RNG) and k-relative neighbourhood graph (k-RNG). Then, we give an alternative high-dimensional detection algorithm: PCA-∈-SRNG. After detecting mislabeled training samples, it is necessary to correct these mislabeled samples. Then we further propose a scalar-adapted correction algorithm: Fat location correction/deletion. Finally, we explore and validate our algorithms based on real datasets with high-dimensional features.

Keywords
high dimension, inaccurate supervision learning, mislabeled samples, relative neighbourhood graph (RNG), detection, correction.

Cite this paper
Junyan Li, Xinxing Wu, Detection and correction of mislabeled samples based on graph structure , SCIREA Journal of Information Science and Systems Science. Volume 5, Issue 2, April 2021 | PP. 12-33. 10.54647/isss12083

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