Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs

Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs

The goal of the few-shot learning method is to learn quickly from a low-data regime. Structured output tasks like segmentation are challenging for few-shot learning, due to their being high-dimensional and statistically dependent. For this problem, we propose improved guided networks and combine the...

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Main Authors: Kun Zhang, Yuanjie Zheng, Xiaobo Deng, Weikuan Jia, Jian Lian, Xin Chen
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Electronics
Subjects:
few-shot learning
image segmentation
convolutional neural networks
conditional random fields
Online Access:https://www.mdpi.com/2079-9292/9/9/1508
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spelling doaj-c613878ed133435c96ed98d6b51c19dd2020-11-25T03:14:52ZengMDPI AGElectronics2079-92922020-09-0191508150810.3390/electronics9091508Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFsKun Zhang0Yuanjie Zheng1Xiaobo Deng2Weikuan Jia3Jian Lian4Xin Chen5School of Information Science and Engineering, Shandong Normal University, Jinan 250358, ChinaSchool of Information Science and Engineering, Shandong Normal University, Jinan 250358, ChinaShandong Key Laboratory for Testing Technology of Material, Chemical Safety, Jinan 250102, ChinaSchool of Information Science and Engineering, Shandong Normal University, Jinan 250358, ChinaDepartment of Electrical Engineering and Information Technology, Shandong University of Science and Technology, Jinan 250031, ChinaSchool of Information Science and Engineering, Shandong Normal University, Jinan 250358, ChinaThe goal of the few-shot learning method is to learn quickly from a low-data regime. Structured output tasks like segmentation are challenging for few-shot learning, due to their being high-dimensional and statistically dependent. For this problem, we propose improved guided networks and combine them with a fully connected conditional random field (CRF). The guided network extracts task representations from annotated support images through feature fusion to do fast, accurate inference on new unannotated query images. By bringing together few-shot learning methods and fully connected CRFs, our method can do accurate object segmentation by overcoming poor localization properties of deep convolutional neural networks and can quickly updating tasks, without further optimization, when faced with new data. Our guided network is at the forefront of accuracy for the terms of annotation volume and time.https://www.mdpi.com/2079-9292/9/9/1508few-shot learningimage segmentationconvolutional neural networksconditional random fields
collection DOAJ
language English
format Article
sources DOAJ
author Kun Zhang
Yuanjie Zheng
Xiaobo Deng
Weikuan Jia
Jian Lian
Xin Chen
spellingShingle Kun Zhang
Yuanjie Zheng
Xiaobo Deng
Weikuan Jia
Jian Lian
Xin Chen
Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
Electronics
few-shot learning
image segmentation
convolutional neural networks
conditional random fields
author_facet Kun Zhang
Yuanjie Zheng
Xiaobo Deng
Weikuan Jia
Jian Lian
Xin Chen
author_sort Kun Zhang
title Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
title_short Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
title_full Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
title_fullStr Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
title_full_unstemmed Guided Networks for Few-Shot Image Segmentation and Fully Connected CRFs
title_sort guided networks for few-shot image segmentation and fully connected crfs
publisher MDPI AG
series Electronics
issn 2079-9292
publishDate 2020-09-01
description The goal of the few-shot learning method is to learn quickly from a low-data regime. Structured output tasks like segmentation are challenging for few-shot learning, due to their being high-dimensional and statistically dependent. For this problem, we propose improved guided networks and combine them with a fully connected conditional random field (CRF). The guided network extracts task representations from annotated support images through feature fusion to do fast, accurate inference on new unannotated query images. By bringing together few-shot learning methods and fully connected CRFs, our method can do accurate object segmentation by overcoming poor localization properties of deep convolutional neural networks and can quickly updating tasks, without further optimization, when faced with new data. Our guided network is at the forefront of accuracy for the terms of annotation volume and time.
topic few-shot learning
image segmentation
convolutional neural networks
conditional random fields
url https://www.mdpi.com/2079-9292/9/9/1508
work_keys_str_mv AT kunzhang guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
AT yuanjiezheng guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
AT xiaobodeng guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
AT weikuanjia guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
AT jianlian guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
AT xinchen guidednetworksforfewshotimagesegmentationandfullyconnectedcrfs
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