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Main Authors: Sun, Chengkun, Pan, Jinqian, Liang, Renjie, Fan, Zhengkang, Miao, Xin, Bian, Jiang, Xu, Jie
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.17939
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author Sun, Chengkun
Pan, Jinqian
Liang, Renjie
Fan, Zhengkang
Miao, Xin
Bian, Jiang
Xu, Jie
author_facet Sun, Chengkun
Pan, Jinqian
Liang, Renjie
Fan, Zhengkang
Miao, Xin
Bian, Jiang
Xu, Jie
contents In medical image segmentation, particularly in UNet-like architectures, upsampling is primarily used to transform smaller feature maps into larger ones, enabling feature fusion between encoder and decoder features and supporting multi-scale prediction. Conventional upsampling methods, such as transposed convolution and linear interpolation, operate on fixed positions: transposed convolution applies kernel elements to predetermined pixel or voxel locations, while linear interpolation assigns values based on fixed coordinates in the original feature map. These fixed-position approaches may fail to capture structural information beyond predefined sampling positions and can lead to artifacts or loss of detail. Inspired by deformable convolutions, we propose a novel upsampling method, Deformable Transposed Convolution (DTC), which learns dynamic coordinates (i.e., sampling positions) to generate high-resolution feature maps for both 2D and 3D medical image segmentation tasks. Experiments on 3D (e.g., BTCV15) and 2D datasets (e.g., ISIC18, BUSI) demonstrate that DTC can be effectively integrated into existing medical image segmentation models, consistently improving the decoder's feature reconstruction and detail recovery capability.
format Preprint
id arxiv_https___arxiv_org_abs_2601_17939
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle DTC: A Deformable Transposed Convolution Module for Medical Image Segmentation
Sun, Chengkun
Pan, Jinqian
Liang, Renjie
Fan, Zhengkang
Miao, Xin
Bian, Jiang
Xu, Jie
Computer Vision and Pattern Recognition
In medical image segmentation, particularly in UNet-like architectures, upsampling is primarily used to transform smaller feature maps into larger ones, enabling feature fusion between encoder and decoder features and supporting multi-scale prediction. Conventional upsampling methods, such as transposed convolution and linear interpolation, operate on fixed positions: transposed convolution applies kernel elements to predetermined pixel or voxel locations, while linear interpolation assigns values based on fixed coordinates in the original feature map. These fixed-position approaches may fail to capture structural information beyond predefined sampling positions and can lead to artifacts or loss of detail. Inspired by deformable convolutions, we propose a novel upsampling method, Deformable Transposed Convolution (DTC), which learns dynamic coordinates (i.e., sampling positions) to generate high-resolution feature maps for both 2D and 3D medical image segmentation tasks. Experiments on 3D (e.g., BTCV15) and 2D datasets (e.g., ISIC18, BUSI) demonstrate that DTC can be effectively integrated into existing medical image segmentation models, consistently improving the decoder's feature reconstruction and detail recovery capability.
title DTC: A Deformable Transposed Convolution Module for Medical Image Segmentation
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2601.17939