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基于联合时空滤波和 L1 范数正则化的红外目标检测。

Infrared Target Detection Based on Joint Spatio-Temporal Filtering and L1 Norm Regularization.

机构信息

School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China.

Dongfeng Liuzhou Motor Co., Ltd., Liuzhou 545005, China.

出版信息

Sensors (Basel). 2022 Aug 20;22(16):6258. doi: 10.3390/s22166258.

DOI:10.3390/s22166258
PMID:36016018
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9413064/
Abstract

Infrared target detection is often disrupted by a complex background, resulting in a high false alarm and low target recognition. This paper proposes a robust principal component decomposition model with joint spatial and temporal filtering and L1 norm regularization to effectively suppress the complex backgrounds. The model establishes a new anisotropic Gaussian kernel diffusion function, which exploits the difference between the target and the background in the spatial domain to suppress the edge contours. Furthermore, in order to suppress the dynamically changing background, we construct an inversion model that combines temporal domain information and L1 norm regularization to globally constrain the low rank characteristics of the background, and characterize the target sparse component with L1 norm. Finally, the overlapping multiplier method is used for decomposition and reconstruction to complete the target detection.Through relevant experiments, the proposed background modeling method in this paper has a better background suppression effect in different scenes. The average values of the three evaluation indexes, SSIM, BSF and IC, are 0.986, 88.357 and 18.967, respectively. Meanwhile, the proposed detection method obtains a higher detection rate compared with other algorithms under the same false alarm rate.

摘要

红外目标检测常常受到复杂背景的干扰,导致高误报率和低目标识别率。本文提出了一种稳健的主成分分解模型,该模型具有联合空域和时域滤波以及 L1 范数正则化功能,可有效抑制复杂背景。该模型建立了一种新的各向异性高斯核扩散函数,利用目标和背景在空域中的差异来抑制边缘轮廓。此外,为了抑制动态变化的背景,我们构建了一个结合时域信息和 L1 范数正则化的反演模型,全局约束背景的低秩特性,并使用 L1 范数对目标稀疏分量进行特征描述。最后,采用重叠乘法器方法进行分解和重构,完成目标检测。通过相关实验,本文提出的背景建模方法在不同场景下具有更好的背景抑制效果。三个评价指标 SSIM、BSF 和 IC 的平均值分别为 0.986、88.357 和 18.967。同时,在相同误报率下,与其他算法相比,所提出的检测方法具有更高的检测率。

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Low-Altitude Infrared Slow-Moving Small Target Detection via Spatial-Temporal Features Measure.基于时空特征度量的低空红外慢速小目标检测。
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IEEE Trans Image Process. 2013 Dec;22(12):4996-5009. doi: 10.1109/TIP.2013.2281420.