Journal of Jilin University(Engineering and Technology Edition) ›› 2025, Vol. 55 ›› Issue (7): 2393-2401.doi: 10.13229/j.cnki.jdxbgxb.20231128

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Few-shot remote sensing image classification based on contrastive learning text perception

Wen-hui LI(),Chen YANG   

  1. College of Computer Science and Technology,Jilin University,Changchun 130012,China
  • Received:2023-10-20 Online:2025-07-01 Published:2025-09-12

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Abstract:

Aiming at the problem that existing methods mainly use a single modality of remote sensing images to solve the problem of low similarity of the same class, a remote sensing image classification method based on multimodal learning is proposed. Firstly, The spatial features of the image are corrected. The image encoder is pre-trained using contrastive learning to generate image features and text features are generated using text encoder. Secondly, a feature decoder is introduced to acquire text perception visual features, and a new attention mechanism approach is proposed in the feature fusion stage. Thirdly, a new image encoder is designed to improve the classification accuracy. Finally, the similarity between the support set and the query set is computed for further class prediction. Experiments are conducted on the NWPU-RESISC45, AID and UC Merced datasets. The 5-way 5-shot accuracies of 86.46%, 85.89%, and 80.32% respectively outperform existing methods in few-shot remote sensing image classification.

Key words: computer application technology, contrastive learning, text perception, few-shot learning, remote sensing image classification

CLC Number: 

  • TP751.1

Fig.1

Pre-training contrastive learning stage"

Fig.2

Structure of CLTP-ML framework"

Fig.3

Structure of image encoder"

Fig.4

Structure of feature decoder"

Fig.5

Fusion of image features and text features"

Fig.6

Structure of attention mechanism"

Table1

Comparison of classification accuracies of models on three datasets %"

模型5-way 5-shot
NWPUAIDUCM
ProtoNet666.64±0.5170.33±0.4867.84±0.15
RelationNet781.43±0.7374.46±0.8762.24±0.54
DLA-MatchNet182.62±0.5476.57±0.7463.86±0.37
SCL-MLNet282.77±0.2979.83±0.6667.39±0.74
FEAT883.84±0.3781.39±0.7175.87±0.52
SPNet980.55±0.4678.28±0.5873.52±0.53
TeAw1085.57±0.2584.62±0.2577.50±0.27
CLTP-ML86.46±0.4385.89±0.2480.32±0.06

Table2

Experimental results for each model parameter"

模型参数量/MFLOPs/G
ProtoNet611.841.82
RelationNet722.432.44
DLA-MatchNet115.061.95
SCL-MLNet214.242.03
FEAT837.523.98
SPNet912.962.26
TeAw1014.592.17
CLTP-ML14.352.06

Fig.7

Comparison of classification accuracy with different weighting factors"

Fig.8

Comparison of classification accuracy of different image encoders"

Table3

Comparison of classification accuracy of different attentional mechanisms"

方法数据集5-way 5-shot/%
SENetNWPU85.71±0.63
ECANetNWPU85.84±0.28
CBAMNWPU86.19±0.56
ECSAMNWPU86.46±0.43
SENetAID85.42±0.67
ECANetAID85.04±0.31
CBAMAID84.88±0.45
ECSAMAID85.89±0.24
SENetUCM79.37±0.72
ECANetUCM79.65±0.39
CBAMUCM79.97±0.24
ECSAMUCM80.32±0.36

Fig.9

Cluster heatmap"

Table4

Ablation experiment"

方法数据集分类准确度/%
CLTP-MLNWPU83.39±0.63
CLTP-ML+PNWPU85.84±0.28
CLTP-ML+P+TNWPU86.05±0.58
CLTP-ML+P+T+ANWPU86.46±0.43
CLTP-MLAID82.19±0.89
CLTP-ML+PAID84.83±0.24
CLTP-ML+P+TAID85.28±0.55
CLTP-ML+P+T+AAID85.89±0.36
CLTP-MLUCM77.26±0.72
CLTP-ML+PUCM78.89±0.52
CLTP-ML+P+TUCM79.73±0.44
CLTP-ML+P+T+AUCM80.32±0.41
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