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基于压缩感知理论的随机噪声雷达目标检测算法研究 被引量:4

A Target Detection Algorithm Based on Compressive Sensing for Random Noise Radar
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摘要 随机噪声雷达通常利用时域相关完成脉冲压缩从而进行目标检测。该文根据压缩感知理论提出一种适用于噪声雷达目标检测的新算法,它用低维投影测量和信号重建取代了传统的相关操作和压缩处理,将大量运算转移到后期处理。该算法以噪声雷达所检测的目标空间分布满足稀疏性为前提;利用发射信号形成卷积矩阵,然后通过随机抽取卷积矩阵的行构建测量矩阵;并采用迭代收缩阈值算法实现目标信号重建。该文对算法作了详细的理论推导,形成完整的实现框架。仿真实验验证了算法的有效性,并分析了对处理结果影响较大的因素。该算法能够有效地重建目标,具有良好的运算效率。与时域相关法相比,大幅度减小了目标检测误差,有效抑制了输出旁瓣,并保持了信号的相位特性。 Random noise radar executes pulse compression via direct correlation in time domain for target detection A novel algorithm is proposed based on compressive sensing for random noise radar system. Projection for low dimension data is adopted instead of correlation; Signal reconstruction is used to substitute signal compression; And much computational load is transferred to background processing. In this algorithm, detected targets in scene satisfy the requirement of sparsity peculiarity, and measurement matrix is constructed by selecting the rows of convolution matrix stochastically. Furthermore, two step iterative shrinkage/thresholding algorithm is applied to reconstruct target signals. With elaborate theoretical derivation, the whole processing of this algorithm is presented. Simulation results are provided to show that the algorithm is able to reconstruct targets efficiently with well computational efficiency. Moreover, factors highly influencing on the results are analyzed. In contrast to correlation operation, reconstruction error is significantly reduced and sidelobes are faithfully suppressed. In addition, phase characters of target information are preserved well.
作者 武昕 王岩飞 刘畅
机构地区 中国科学院电子学研究所 中国科学院研究生院
出处 《电子与信息学报》 EI CSCD 北大核心 2012年第7期1609-1615,共7页 Journal of Electronics & Information Technology
关键词 随机噪声雷达 目标检测 压缩感知 重建误差 Random noise radar Target detection Compressive Sensing (CS) Reconstruction error
分类号 TN958 [电子电信—信号与信息处理]
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参考文献13

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同被引文献55

  • 1焦李成,谭山.图像的多尺度几何分析:回顾和展望[J].电子学报,2003,31(z1):1975-1981. 被引量:228
  • 2蔡骋,张明,朱俊平.基于压缩感知理论的杂草种子分类识别[J].中国科学:信息科学,2010,40(S1):160-172. 被引量:17
  • 3Yu Jun, Tao Da-cheng, and Wang Meng. Adaptive hypergraph learning and its application in image classification[J]. IEEE Transactions on Image Processing, 2012, 21(7): 3262-3272.
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  • 5Song Xiang-fa, Jiao Li-cheng, Yang Shu-yuan, et al.. Sparse coding and classifier ensemble based multi-instance learning for image categorization[J]. Signal Processing, 2013, 93(1): 1-11.
  • 6Zhou Zhi-hua and Zhang Min-ling. Multi-instance multi-label learning with application to scene classification[C]. Proceedings of Neural Information Processing Systems, Vancouver, 2006: 1609-1616.
  • 7Zhou Zhi-hua, Zhang Min-ling, Huang Sheng-jun, et al.. Multi-instance multi-label learning[J]. Artificial Intelligence, 2011, 176(1): 2291-2320.
  • 8Zhang Min-ling and Wang Zhi-jian. MIMLRBF: RBF neural networks for multi-instance multi-label learning[J]. Neurocomputing, 2009, 72(16-18): 3951-3956.
  • 9Zhang Min-ling. A k-nearest neighbor based multi-instance multi-label learning algorithm[C]. Proceedings of International Conference on Tools with Artificial Intelligence Arras, 2010: 207-212.
  • 10Li Ying-Xin, Ji Shui-wang, Kumar S, ct al.. Drosophila gene expression pattern annotation through multi-instance multi-label learning[J]. A CM/ IEEE Transactions on Computational Biology and Bioinformatics, 2012, 9(1): 98-112.

引证文献4

二级引证文献29

电子与信息学报
2012年 第7期

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