JPEG2000-Based Semantic Image Compression using CNN

IF 0.8 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

International Journal of Electrical and Computer Engineering Systems Pub Date : 2023-06-05 DOI:10.32985/ijeces.14.5.4

Anish Nagarsenker, P. Khandekar, Minal Deshmukh

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引用次数: 0

Abstract

Some of the computer vision applications such as understanding, recognition as well as image processing are some areas where AI techniques like convolutional neural network (CNN) have attained great success. AI techniques are not very frequently used in applications like image compression which are a part of low-level vision applications. Intensifying the visual quality of the lossy video/image compression has been a huge obstacle for a very long time. Image processing tasks and image recognition can be addressed with the application of deep learning CNNs as a result of the availability of large training datasets and the recent advances in computing power. This paper consists of a CNN-based novel compression framework comprising of Compact CNN (ComCNN) and Reconstruction CNN (RecCNN) where they are trained concurrently and ideally consolidated into a compression framework, along with MS-ROI (Multi Structure-Region of Interest) mapping which highlights the semiotically notable portions of the image. The framework attains a mean PSNR value of 32.9dB, achieving a gain of 3.52dB and attains mean SSIM value of 0.9262, achieving a gain of 0.0723dB over the other methods when compared using the 6 main test images. Experimental results in the proposed study validate that the architecture substantially surpasses image compression frameworks, that utilized deblocking or denoising post- processing techniques, classified utilizing Peak Signal to Noise Ratio (PSNR) and Structural Similarity Index Measures (SSIM) with a mean PSNR, SSIM and Compression Ratio of 38.45, 0.9602 and 1.75x respectively for the 50 test images, thus obtaining state-of-art performance for Quality Factor (QF)=5.

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基于CNN的jpeg2000语义图像压缩

一些计算机视觉应用，如理解、识别以及图像处理，是卷积神经网络(CNN)等人工智能技术取得巨大成功的一些领域。人工智能技术并不经常用于像图像压缩这样的应用程序，这是低级视觉应用程序的一部分。长期以来，增强有损视频/图像压缩的视觉质量一直是一个巨大的障碍。由于大型训练数据集的可用性和计算能力的最新进步，深度学习cnn的应用可以解决图像处理任务和图像识别问题。本文由一个基于CNN的新型压缩框架组成，该框架包括紧凑CNN (ComCNN)和重建CNN (RecCNN)，它们同时被训练并理想地整合到一个压缩框架中，以及MS-ROI(多结构感兴趣区域)映射，该映射突出了图像的符号显著部分。该框架的平均PSNR值为32.9dB，增益为3.52dB，平均SSIM值为0.9262，与其他方法相比，使用6个主要测试图像进行比较，增益为0.0723dB。本研究的实验结果表明，该架构大大优于图像压缩框架，该框架利用去块或去噪后处理技术，利用峰值信噪比(PSNR)和结构相似度指标(SSIM)对50幅测试图像进行分类，平均PSNR、SSIM和压缩比分别为38.45倍、0.9602倍和1.75倍，在质量因子(QF)=5时获得了最先进的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Electrical and Computer Engineering Systems ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

1.20

自引率

11.80%

发文量

期刊介绍： The International Journal of Electrical and Computer Engineering Systems publishes original research in the form of full papers, case studies, reviews and surveys. It covers theory and application of electrical and computer engineering, synergy of computer systems and computational methods with electrical and electronic systems, as well as interdisciplinary research. Power systems Renewable electricity production Power electronics Electrical drives Industrial electronics Communication systems Advanced modulation techniques RFID devices and systems Signal and data processing Image processing Multimedia systems Microelectronics Instrumentation and measurement Control systems Robotics Modeling and simulation Modern computer architectures Computer networks Embedded systems High-performance computing Engineering education Parallel and distributed computer systems Human-computer systems Intelligent systems Multi-agent and holonic systems Real-time systems Software engineering Internet and web applications and systems Applications of computer systems in engineering and related disciplines Mathematical models of engineering systems Engineering management.