Fine-Tuning Convolutional Neural Networks for Biomedical Image Analysis: Actively and Incrementally

Zhou, Zongwei; Shin, Jae Y.; Zhang, Lei; Gurudu, Suryakanth R.; Gotway, Michael B.; Liang, Jianming

doi:10.1109/cvpr.2017.506

Cited by 335 publications

(162 citation statements)

References 24 publications

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“…As the two approaches based on uncertainty and distribution are differently motivated, they are complementary to each other. Thus, a variety of hybrid strategies have been proposed [29,59,41,56] for their specific tasks.…”

Section: Related Researchmentioning

confidence: 99%

Learning Loss for Active Learning

Yoo¹,

Kweon

2019

2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)

435

477

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The performance of deep neural networks improves with more annotated data. The problem is that the budget for annotation is limited. One solution to this is active learning, where a model asks human to annotate data that it perceived as uncertain. A variety of recent methods have been proposed to apply active learning to deep networks but most of them are either designed specific for their target tasks or computationally inefficient for large networks. In this paper, we propose a novel active learning method that is simple but task-agnostic, and works efficiently with the deep networks. We attach a small parametric module, named "loss prediction module," to a target network, and learn it to predict target losses of unlabeled inputs. Then, this module can suggest data that the target model is likely to produce a wrong prediction. This method is task-agnostic as networks are learned from a single loss regardless of target tasks. We rigorously validate our method through image classification, object detection, and human pose estimation, with the recent network architectures. The results demonstrate that our method consistently outperforms the previous methods over the tasks.

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Section: Related Researchmentioning

confidence: 99%

Learning Loss for Active Learning

Yoo¹,

Kweon

2019

2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)

435

477

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“…While approaches to semi-supervised learning, which typically handle unlabeled and labeled data from the same data distribution simultaneously, are increasingly common in the field of Medical Image Computing (MIC) [2], we are, to our knowledge, the first to investigate the concept of self-supervised learning to reduce manual labeling effort in medical image segmentation. In contrast to state-of-the-art pre-training methods [24,27,28,32], we initialized our model on the target domain using only unlabeled data rather than on a different domain with labeled data. This is achieved with an auxiliary task that can be assumed to learn a representation of the target domain that is well-suited for the target task.…”

Section: Discussionmentioning

confidence: 99%

Exploiting the potential of unlabeled endoscopic video data with self-supervised learning

et al. 2018

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“…Note that there is no general approach applicable to our setting, we compare the proposed approach with the Random method, which randomly select instances to query their labels. The method AIFT proposed in [44] was originally designed for binary classification of medical images, and thus is not compared in the multi-class cases. Instead, the performance of the fully re-trained model is provided for reference.…”

Section: Performance Comparisonmentioning

confidence: 99%

Cost-Effective Training of Deep CNNs with Active Model Adaptation

Huang

Zhao

Liu

2018

Proceedings of the 24th ACM SIGKDD International Conference on Knowledge Discovery &Amp; Data Mining

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Deep convolutional neural networks have achieved great success in various applications. However, training an effective DNN model for a specific task is rather challenging because it requires a prior knowledge or experience to design the network architecture, repeated trial-and-error process to tune the parameters, and a large set of labeled data to train the model. In this paper, we propose to overcome these challenges by actively adapting a pre-trained model to a new task with less labeled examples. Specifically, the pre-trained model is iteratively fine tuned based on the most useful examples. The examples are actively selected based on a novel criterion, which jointly estimates the potential contribution of an instance on optimizing the feature representation as well as improving the classification model for the target task. On one hand, the pre-trained model brings plentiful information from its original task, avoiding redesign of the network architecture or training from scratch; and on the other hand, the labeling cost can be significantly reduced by active label querying. Experiments on multiple datasets and different pre-trained models demonstrate that the proposed approach can achieve cost-effective training of DNNs.

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Fine-Tuning Convolutional Neural Networks for Biomedical Image Analysis: Actively and Incrementally

Cited by 335 publications

References 24 publications

Learning Loss for Active Learning

Learning Loss for Active Learning

Exploiting the potential of unlabeled endoscopic video data with self-supervised learning

Cost-Effective Training of Deep CNNs with Active Model Adaptation

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