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[Objective] This study aims to address critical challenges in open-environment synthetic aperture radar(SAR) applications, where high-value targets continuously emerge but labeled samples remain scarce. The study proposes an orthogonality-constrained distribution-calibrated replay method for continuous learning in SAR target recognition. Unlike traditional deep learning models, which assume closed environments with abundant data, this method targets the stability–plasticity dilemma, aiming to resolve the dual problems of catastrophic forgetting of old knowledge and overfitting on limited new data. [Methods] First, during the initial base class training phase, the proposed method establishes a highly structured embedding space to reserve non-overlapping geometric regions for future classes. It optimizes the feature space by utilizing a combined orthogonal prototype distribution and intra-class compactness loss. Specifically, the method employs an iterative process to construct an orthogonal basis space by selecting prototype vectors with the lowest cosine similarity to existing bases and projecting them into the orthogonal complement space. This approach ensures that the embedding space is inter-class separable and intra-class compact, leaving adequate room for future incremental classes. When new classes are accommodated, a dual knowledge preservation method is proposed to mitigate catastrophic forgetting of old knowledge during incremental updates by integrating orthogonal gradient projection and distribution-calibrated replay. Orthogonal gradient projection minimizes interference with established knowledge by constraining the update direction. It projects gradient updates into the orthogonal space of the base class feature matrix, such that the model's response to old classes remains invariant. However, achieving a strictly orthogonal space is challenging, and gradual drift still occurs. To further recall old class knowledge from the feature distribution of previous classes, we employ distribution-calibrated replay to reinforce historical knowledge by generating and rehearsing high-fidelity pseudo-features. This strategy utilizes a Gaussian sampler based on the statistics of old classes and introduces a learnable recursive calibrator to correct deviations between the sampled Gaussian distribution and the complex real feature distribution. By minimizing the Kullback–Leibler(KL) divergence between the generated and real distributions, this module replays high-quality pseudo-features that effectively consolidate memory. To enhance the model's robust generalization on scarce new classes, a self-supervised progressive learning strategy is proposed that advances from easy to hard tasks, ensuring effective feature mining from limited samples. This includes a rotation-based self-supervised branch optimized with an uncertainty-weighted focal loss, which effectively optimizes the feature extractor. The self-supervised branch encourages the model to learn azimuth-invariant features, thereby mitigating overfitting. In addition, the uncertainty-weighted focal loss dynamically assigns higher weights to hard-to-classify samples based on prediction probabilities, encouraging the model to focus on mining discriminative features. [Results] Experiment results on the moving and stationary target acquisition and recognition, and SAR AIRcraft-1.0 datasets validate the effectiveness of the proposed method. It significantly outperforms state-of-the-art methods, demonstrating superior efficiency and stability by achieving the highest recognition accuracy with minimal accuracy drop across various scenarios, including different numbers of incremental classes, varying incremental sample sizes, and distinct datasets. Ablation studies confirm that the proposed stability and plasticity modules enhance target recognition performance. [Conclusions] By integrating orthogonal gradient projection, distribution calibration replay, and self-supervised progressive learning, this paper successfully addresses the inherent challenges in continuous learning, providing a robust solution for dynamic SAR automatic target recognition.
[1]丁泽刚,李凌豪,李埔丞,等.合成孔径雷达高分辨率成像虚拟仿真实验平台设计[J].实验技术与管理, 2024, 41(1):136–142.DING Z G, LI L H, LI P C, et al. Design of synthetic aperture radar high-resolution imaging virtual simulation experiment platform[J]. Experimental Technology and Management, 2024,41(1):136–142.(in Chinese)
[2]REN H H, YU X L, LIU S, et al. Adaptive convolutional subspace reasoning network for few-shot SAR target recognition[J]. IEEE Transactions on Geoscience and Remote Sensing,2023, 61:5210813.
[3]NOVAK L M, OWIRKA G J, BROWER W S, et al. The automatic target-recognition system in SAIP[J]. Lincoln Laboratory Journal, 1997, 10(2):16698788.
[4]HUMMEL R. Model-based ATR using synthetic aperture radar[C]//Record of the IEEE 2000 International Radar Conference.Alexardria, USA, 2000:856–861.
[5]CHEN S Z, WANG H P, XU F, et al. Target classification using the deep convolutional networks for SAR images[J]. IEEE Transactions on Geoscience and Remote Sensing, 2016, 54(8):4806–4817.
[6]REBUFFI S A, KOLESNIKOV A, SPERL G, et al. iCaRL:Incremental classifier and representation learning[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition(CVPR). Honolulu, USA, 2017:5533–5542.
[7]赵琰,赵凌君,张思乾,等.自监督解耦动态分类器的小样本类增量SAR图像目标识别[J].电子与信息学报, 2024, 46(10):3936–3948.ZHAO Y, ZHAO L J, ZHANG S Q, et al. Few-shot classincremental SAR image target recognition using self-supervised decoupled dynamic classifier[J]. Journal of Electronics&Information Technology, 2024, 46(10):3936–3948.(in Chinese)
[8]PARISI G I, KEMKER R, PART J L, et al. Continual lifelong learning with neural networks:A review[J]. Neural Networks,2019, 113:54–71.
[9]LI Z Z, HOIEM D. Learning without forgetting[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence,2018, 40(12):2935–2947.
[10]YAN S P, XIE J W, HE X M. DER:Dynamically expandable representation for class incremental learning[EB/OL].(2021-03-31)[2025-11-11]. https://arxiv.org/abs/2103.16788.
[11]TAO X Y, HONG X P, CHANG X Y, et al. Few-shot class-incremental learning[EB/OL].(2020-04-23)[2025-11-11].https://arxiv.org/abs/2004.10956.
[12]ZHOU D W, WANG F Y, YE H J, et al. Forward compatible few-shot class-incremental learning[C]//Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. New Orleans, USA, 2022:9036–9046.
[13]WANG L, YANG X Y, TAN H Y, et al. Few-shot classincremental SAR target recognition based on hierarchical embedding and incremental evolutionary network[J]. IEEE Transactions on Geoscience and Remote Sensing, 2023, 61:5204111.
[14]ZHAO Y, ZHAO L J, ZHANG S Q, et al. Azimuth-aware subspace classifier for few-shot class-incremental SAR ATR[J].IEEE Transactions on Geoscience and Remote Sensing, 2024,62:5203020.
[15]KONG L Z, GAO F, HE X Y, et al. Few-shot class-incremental SAR target recognition via orthogonal distributed features[J].IEEE Transactions on Aerospace and Electronic Systems, 2024,61(1):325–341.
[16]ZHAO Y, ZHAO L J, ZHANG S Q, et al. Decoupled selfsupervised subspace classifier for few-shot class-incremental SAR target recognition[J]. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2024, 17:15845–15861.
[17]KARANTAIDIS G, PANTSIOS A, KOMPATSIARIS I, et al.Few-shot class-incremental learning for efficient SAR automatic target recognition[EB/OL].(2025-05-26)[2025-11-11].https://arxiv.org/abs/2505.19565.
[18]DENG Z W, LUO C B, TANG Z X, et al. An orthogonal pseudo-prototype and pseudo-target-based method for few-shot class-incremental automatic modulation recognition[J]. IEEE Transactions on Cognitive Communications and Networking,2025, 12:2542–2557.
[19]张承畅,王艺培,李吉利,等.基于轻量级残差网络的信号调制识别研究[J].实验技术与管理, 2025, 42(3):114–122.ZHANG C C, WANG Y P, LI J L, et al. Research on signal modulation recognition based on lightweight residual networks[J]. Experiment Technology and Management, 2025, 42(3):114–122.(in Chinese)
[20]LI X B, WANG W Q. GopGAN:Gradients orthogonal projection generative adversarial network with continual learning[J]. IEEE Transactions on Neural Networks and Learning Systems, 2021,34(1):215–227.
[21]LIU B H, YANG B Y, XIE L X, et al. Learnable distribution calibration for few-shot class-incremental learning[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence,2023, 45(10):12699–12706.
[22]BENGIO Y, LOURADOUR J, COLLOBERT R, et al. Curriculum learning[C]//Proceedings of the 26th Annual International Conference on Machine Learning. Montreal, CA, 2009:41–48.
[23]LIN T Y, GOYAL P, GIRSHICK R, et al. Focal loss for dense object detection[C]//Proceedings of the IEEE International Conference on Computer Vision. Venice, Italy, 2017:2999–3007.
[24]HOU S H, PAN X Y, LOY C C, et al. Learning a unified classifier incrementally via rebalancing[C]//Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. Long Beach, CA, USA, 2019:831–839.
[25]CHEN K L, LEE C G. Incremental few-shot learning via vector quantization in deep embedded space[C]//International Conference on Learning Representations. Vienna, Austria:Open Review. net,2021:1–16.
[26]REN H H, ZHOU R S, ZOU L, et al. Hierarchical distributionbased exemplar replay for incremental SAR automatic target recognition[J]. IEEE Transactions on Aerospace and Electronic Systems, 2025, 61(3):6576–6588.
Basic Information:
DOI:10.16791/j.cnki.sjg.2026.03.004
China Classification Code:TN957.52;TP18
Citation Information:
[1]ZHOU Yun,LI Junyi,REN Haohao ,et al.Continuous learning-based few-shot synthetic aperture radar ground target recognition[J].Experimental Technology and Management,2026,43(03):25-34.DOI:10.16791/j.cnki.sjg.2026.03.004.
Fund Information:
四川省高等学校首批高阶课程项目(2023030); 四川省高等学校创新性实验项目(2023016); 国家自然科学基金项目(62201124); 四川省自然科学基金(2025ZNSFSC1432)
2025-11-11
2025
2026-01-05
2026
2026-01-04
1
2026-03-09
2026-03-09
2026-03-09