双边加权组稀疏残差约束的面阵卫星影像去噪

Area-Array Satellite Images Denoising Based on Bilateral Weighted Group Sparsity Residual Constraint Model

  • 摘要: 传统的组稀疏表示模型受到噪声的影响可能无法准确估计每个影像组的稀疏性,从而导致对理想影像的复原失真。提出了双边加权的组稀疏残差约束模型,引入组稀疏残差约束,首先利用稀疏编码系数的非局部自相似性获得理想影像的组稀疏系数估计,然后约束对应退化影像的组稀疏系数来逼近这一估计。由于面阵卫星影像噪声较为复杂,用简单加性高斯白噪声难以精确建模,将两个权重矩阵分别引入组稀疏残差约束的数据保真项和正则化项中,以表征影像和噪声的统计特性。使用模拟数据和珞珈三号01星获取的真实影像进行实验,在模拟实验中,双边加权组稀疏残差约束模型在去除加性高斯白噪声和空间异质噪声方面表现优于其他对比方法。在真实影像实验中,使用该模型去噪后的影像熵值相较于三维块匹配滤波方法、多波段加权核范数最小化方法、非局部中心化稀疏表示方法、低秩化组稀疏表示方法和三边加权稀疏编码方法,分别提升了2.03%、1.18%、1.26%、1.24%和2.10%。结果表明,双边加权组稀疏残差约束模型在保留影像边缘细节和消除真实影像噪声方面优于对比方法。

     

    Abstract:
    Objectives The conventional group sparse representation (GSR) model encounters challenges in precisely estimating the sparsity of individual image groups, because the influence of noise results in distortion in the restoration of original image group.
    Methods This paper introduces a strategy denominated as the group sparse residual constraint. This strategy leverages non-local self-similarity priors to derive precise estimate of sparse coefficients for each original image group. Subsequently, the sparse coefficients of corresponding degraded image groups are constrained to approximate this estimate. Furthermore, the intricate nature of noise in area-array satellite images (e.g., Luojia3-01 satellite images), surpasses the simplicity of additive white Gaussian noise (AWGN). Consequently, conventional GSR model tailored for AWGN exhibits a reduction in efficacy when deployed in real image denoising scenarios. To address this, this paper introduces two distinct weight matrices into the data fidelity term and regularization, respectively, with the intent of characterizing the statistical features inherent in both images and noise. This paper adopts the alternating direction method of multipliers for optimizing the proposed image denoising task.
    Results The effectiveness of the proposed model is validated by the experiments using simulated data and real images obtained from the Luojia3-01 satellite. In the experiments of simulated data, the proposed model outperforms other methods in removing AWGN and spatially variant noise. In the experiments of real images, the entropy of denoised images by the proposed model shows improvements of 2.03%, 1.18%, 1.26%, 1.24%, and 2.10% , compared to the block-matching and 3-D filtering method, multi-channel weighted nuclear norm minimization method, nonlocally centralized sparse representation method, low-rankness guided group sparse representation method, and trilateral weighted sparse coding method, respectively.
    Conclusions The proposed method exhibits good performance in processing area-array satellite images with low signal-to-noise ratios and complex noise structures, significantly enhancing the quality of the image. By effectively reducing noise while preserving crucial details and edges, it provides a reliable solution for enhancing the usability and interpretability of area-array satellite images, particularly in challenging conditions.

     

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