Deep and Structured Robust Information Theoretic Learning for Image Analysis

Yue Deng; Feng Bao; Xuesong Deng; Ruiping Wang; Youyong Kong; Qionghai Dai

doi:10.1109/TIP.2016.2588330

Deep and Structured Robust Information Theoretic Learning for Image Analysis

Yue Deng
, Feng Bao
, Xuesong Deng
, Ruiping Wang
, Youyong Kong
, Qionghai Dai

Tsinghua University
University of California at San Francisco
CAS - Institute of Computing Technology
Southeast University, Nanjing

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

This paper presents a robust information theoretic (RIT) model to reduce the uncertainties, i.e., missing and noisy labels, in general discriminative data representation tasks. The fundamental pursuit of our model is to simultaneously learn a transformation function and a discriminative classifier that maximize the mutual information of data and their labels in the latent space. In this general paradigm, we, respectively, discuss three types of the RIT implementations with linear subspace embedding, deep transformation, and structured sparse learning. In practice, the RIT and deep RIT are exploited to solve the image categorization task whose performances will be verified on various benchmark data sets. The structured sparse RIT is further applied to a medical image analysis task for brain magnetic resonance image segmentation that allows group-level feature selections on the brain tissues.

Original language	English
Article number	7506023
Pages (from-to)	4209-4221
Number of pages	13
Journal	IEEE Transactions on Image Processing
Volume	25
Issue number	9
DOIs	https://doi.org/10.1109/TIP.2016.2588330
State	Published - Sep 2016
Externally published	Yes

Keywords

Brain MRI segmentation
Data embedding
deep learning
image classification
mutual information
structured-sparse learning

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10.1109/TIP.2016.2588330

Cite this

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title = "Deep and Structured Robust Information Theoretic Learning for Image Analysis",

abstract = "This paper presents a robust information theoretic (RIT) model to reduce the uncertainties, i.e., missing and noisy labels, in general discriminative data representation tasks. The fundamental pursuit of our model is to simultaneously learn a transformation function and a discriminative classifier that maximize the mutual information of data and their labels in the latent space. In this general paradigm, we, respectively, discuss three types of the RIT implementations with linear subspace embedding, deep transformation, and structured sparse learning. In practice, the RIT and deep RIT are exploited to solve the image categorization task whose performances will be verified on various benchmark data sets. The structured sparse RIT is further applied to a medical image analysis task for brain magnetic resonance image segmentation that allows group-level feature selections on the brain tissues.",

keywords = "Brain MRI segmentation, Data embedding, deep learning, image classification, mutual information, structured-sparse learning",

author = "Yue Deng and Feng Bao and Xuesong Deng and Ruiping Wang and Youyong Kong and Qionghai Dai",

note = "Publisher Copyright: {\textcopyright} 2016 IEEE.",

year = "2016",

month = sep,

doi = "10.1109/TIP.2016.2588330",

language = "英语",

volume = "25",

pages = "4209--4221",

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TY - JOUR

T1 - Deep and Structured Robust Information Theoretic Learning for Image Analysis

AU - Deng, Yue

AU - Bao, Feng

AU - Deng, Xuesong

AU - Wang, Ruiping

AU - Kong, Youyong

AU - Dai, Qionghai

PY - 2016/9

Y1 - 2016/9

N2 - This paper presents a robust information theoretic (RIT) model to reduce the uncertainties, i.e., missing and noisy labels, in general discriminative data representation tasks. The fundamental pursuit of our model is to simultaneously learn a transformation function and a discriminative classifier that maximize the mutual information of data and their labels in the latent space. In this general paradigm, we, respectively, discuss three types of the RIT implementations with linear subspace embedding, deep transformation, and structured sparse learning. In practice, the RIT and deep RIT are exploited to solve the image categorization task whose performances will be verified on various benchmark data sets. The structured sparse RIT is further applied to a medical image analysis task for brain magnetic resonance image segmentation that allows group-level feature selections on the brain tissues.

AB - This paper presents a robust information theoretic (RIT) model to reduce the uncertainties, i.e., missing and noisy labels, in general discriminative data representation tasks. The fundamental pursuit of our model is to simultaneously learn a transformation function and a discriminative classifier that maximize the mutual information of data and their labels in the latent space. In this general paradigm, we, respectively, discuss three types of the RIT implementations with linear subspace embedding, deep transformation, and structured sparse learning. In practice, the RIT and deep RIT are exploited to solve the image categorization task whose performances will be verified on various benchmark data sets. The structured sparse RIT is further applied to a medical image analysis task for brain magnetic resonance image segmentation that allows group-level feature selections on the brain tissues.

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KW - deep learning

KW - image classification

KW - mutual information

KW - structured-sparse learning

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M3 - 文章

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JO - IEEE Transactions on Image Processing

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ER -

Deep and Structured Robust Information Theoretic Learning for Image Analysis

Abstract

Keywords

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