Adaptive Dynamic Range Compression Method for Panchromatic Images Based on Detail Regions Gradient Preservation

IF 2 4区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

IET Image Processing Pub Date : 2025-04-08 DOI:10.1049/ipr2.70067

Peng Zhang, Qiang Xu, Yuwei Zhai, Tao Guo, Jiale Wang, Jinlong Xie

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引用次数: 0

Abstract

An effective panchromatic remote sensing image dynamic range compression method is proposed to solve the issue in existing panchromatic remote sensing image grayscale conversion algorithms, which tend to cause overexposure in certain areas or overall excessive darkness. This method employs an empirical approach of detail region extraction and optimal parameter selection based on gradient to achieve dynamic range compression. First, a novel adaptive detail segmentation method based on the expansion of detail points within image blocks is introduced. Second, a detail optimisation module is established based on local detail preservation, which optimises the extraction of detail regions using gradient-based Otsu segmentation results and improved CLAHE-gradient-based Otsu segmentation results. Then, candidate adaptive dynamic range compression coefficients are determined based on the extracted detail layers, and the optimal adaptive dynamic range compression parameters are selected based on the high gradient proportion of the detail regions. Simulation experiments are conducted on multiple panchromatic remote sensing images with different scenes using the proposed method, and the effects of various dynamic range compression methods are evaluated based on multiple metrics. The results indicate that the proposed dynamic range compression method demonstrates excellent performance.

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基于细节区域梯度保持的全色图像自适应动态范围压缩方法

针对现有全色遥感图像灰度转换算法容易造成局部过曝光或整体过暗的问题，提出了一种有效的全色遥感图像动态范围压缩方法。该方法采用基于梯度的细节区域提取和参数选择的经验方法来实现动态范围压缩。首先，提出了一种基于图像块内细节点扩展的自适应细节分割方法。其次，建立基于局部细节保留的细节优化模块，利用基于梯度的Otsu分割结果和改进的CLAHE-gradient-based Otsu分割结果对细节区域的提取进行优化；然后，根据提取的细节层确定候选自适应动态范围压缩系数，并根据细节区域的高梯度比例选择最优自适应动态范围压缩参数；利用该方法对多幅不同场景的全色遥感图像进行了仿真实验，并基于多个指标评价了各种动态范围压缩方法的效果。结果表明，所提出的动态范围压缩方法具有良好的性能。

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来源期刊

IET Image Processing 工程技术-工程：电子与电气

CiteScore

5.40

自引率

8.70%

发文量

282

审稿时长

6 months

期刊介绍： The IET Image Processing journal encompasses research areas related to the generation, processing and communication of visual information. The focus of the journal is the coverage of the latest research results in image and video processing, including image generation and display, enhancement and restoration, segmentation, colour and texture analysis, coding and communication, implementations and architectures as well as innovative applications. Principal topics include: Generation and Display - Imaging sensors and acquisition systems, illumination, sampling and scanning, quantization, colour reproduction, image rendering, display and printing systems, evaluation of image quality. Processing and Analysis - Image enhancement, restoration, segmentation, registration, multispectral, colour and texture processing, multiresolution processing and wavelets, morphological operations, stereoscopic and 3-D processing, motion detection and estimation, video and image sequence processing. Implementations and Architectures - Image and video processing hardware and software, design and construction, architectures and software, neural, adaptive, and fuzzy processing. Coding and Transmission - Image and video compression and coding, compression standards, noise modelling, visual information networks, streamed video. Retrieval and Multimedia - Storage of images and video, database design, image retrieval, video annotation and editing, mixed media incorporating visual information, multimedia systems and applications, image and video watermarking, steganography. Applications - Innovative application of image and video processing technologies to any field, including life sciences, earth sciences, astronomy, document processing and security. Current Special Issue Call for Papers: Evolutionary Computation for Image Processing - https://digital-library.theiet.org/files/IET_IPR_CFP_EC.pdf AI-Powered 3D Vision - https://digital-library.theiet.org/files/IET_IPR_CFP_AIPV.pdf Multidisciplinary advancement of Imaging Technologies: From Medical Diagnostics and Genomics to Cognitive Machine Vision, and Artificial Intelligence - https://digital-library.theiet.org/files/IET_IPR_CFP_IST.pdf Deep Learning for 3D Reconstruction - https://digital-library.theiet.org/files/IET_IPR_CFP_DLR.pdf