Water body segmentation network for SAR images combining dual-encoder and adaptive feature fuse

doi:10.11947/j.AGCS.2026.20250303

Abstract

Abstract:

Synthetic aperture radar (SAR) image water body segmentation is widely applied in critical fields such as disaster response, water resource management, and environmental monitoring, holding significant practical importance. To address the issue of low segmentation accuracy for water bodies in complex-background SAR images, a dual-encoder adaptive feature fusion network (DEAFFNet) is proposed to achieve accurate water body segmentation. First, the model employs a lightweight residual network and Swin Transformer to construct a dual-encoder architecture, collaboratively extracting local detail information and global contextual information to mitigate the problem of insufficient information representation capability in complex backgrounds. Second, a feature fusion module based on cross-attention and adaptive weight learning is designed. This module utilizes cross-attention for interaction between local and global information and achieves hybrid feature fusion through adaptive weight learning, thereby enhancing the model's perception of water body structures. Then, a multi-scale convolutional pooling module is integrated into the decoder to reinforce multi-scale contextual information, combined with a lightweight content-aware upsampling method to alleviate feature distortion caused by upsampling. Finally, a composite loss function combining focal loss and active contour loss is adopted to strengthen the model's constraints on sample balance and water body boundary information. Water body segmentation experiments conducted on the ALOS PALSAR and Sen-1SAR datasets demonstrate that DEAFFNet outperforms existing methods across multiple evaluation metrics, achieving more accurate water body segmentation.

Key words: SAR image water body segmentation, dual-encoder, cross attention, adaptive weight learning, composite loss

CLC Number:

P237

Bin HAN, Xin HUANG, Fengyi LI, Xiaozhen LU. Water body segmentation network for SAR images combining dual-encoder and adaptive feature fuse[J]. Acta Geodaetica et Cartographica Sinica, 2026, 55(1): 101-113.

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模型	数据集	IoU	mIoU	P_OA	Kappa
UNet	ALOS PALSAR	89.81	71.19	93.45	68.89
UNet	Sen1-SAR	68.43	68.35	78.62	68.21
ResUNet	ALOS PALSAR	91.37	72.37	94.07	71.76
ResUNet	Sen1-SAR	73.24	71.61	81.21	70.25
SwinUNet	ALOS PALSAR	92.57	79.08	94.74	78.36
SwinUNet	Sen1-SAR	76.78	77.13	83.25	76.45
WaterFormer	ALOS PALSAR	93.42	74.29	94.64	72.01
WaterFormer	Sen1-SAR	85.11	84.52	91.47	83.57
DSHNet	ALOS PALSAR	93.82	83.28	94.97	85.22
DSHNet	Sen1-SAR	84.35	83.21	90.56	82.56
MAFUNet	ALOS PALSAR	94.28	84.75	97.23	86.81
MAFUNet	Sen1-SAR	91.28	86.43	92.32	84.98
LEFormer	ALOS PALSAR	93.98	84.37	96.43	85.92
LEFormer	Sen1-SAR	90.76	85.45	91.47	84.54
QTU-Net	ALOS PALSAR	94.13	85.02	96.91	86.43
QTU-Net	Sen1-SAR	90.97	86.21	91.83	84.72
DEAFFNet	ALOS PALSAR	95.67	86.17	97.89	89.96
DEAFFNet	Sen1-SAR	92.26	88.71	93.67	87.09

模块	IoU	mIoU	P_OA	Kappa
基线	90.16	71.89	93.82	71.28
双编码器	92.37	77.38	94.38	76.97
双编码器+CAAWLFF	94.11	82.85	97.18	85.92
双编码器+MSLCAU	93.27	81.79	96.54	83.38
DEAFFNet	95.67	86.17	97.89	89.96

函数	IoU	mIoU	P_OA	Kappa
Baseline+BCE	89.64	71.12	92.97	68.71
Baseline+Focal	90.02	71.64	93.54	70.82
Baseline+Focal+AC	90.16	71.89	93.82	71.28
DEAFFNet+BCE	94.98	84.81	97.31	86.89
DEAFFNet+Focal	95.32	85.19	97.58	87.11
DEAFFNet+Focal+AC	95.67	86.17	97.89	89.96