Joint Optimization of Low-power DCT Architecture and Effcient Quantization Technique for Embedded Image Compression - VLSI-SoC: Forward-Looking Trends in IC and Systems Design
Conference Papers Year : 2012

Joint Optimization of Low-power DCT Architecture and Effcient Quantization Technique for Embedded Image Compression

Maher Jridi
Ayman Alfalou

Abstract

The Discrete Cosine Transform (DCT)-based image com- pression is widely used in today's communication systems. Signi cant research devoted to this domain has demonstrated that the optical com- pression methods can o er a higher speed but su er from bad image quality and a growing complexity. To meet the challenges of higher im- age quality and high speed processing, in this chapter, we present a joint system for DCT-based image compression by combining a VLSI archi- tecture of the DCT algorithm and an e cient quantization technique. Our approach is, rstly, based on a new granularity method in order to take advantage of the adjacent pixel correlation of the input blocks and to improve the visual quality of the reconstructed image. Second, a new architecture based on the Canonical Signed Digit and a novel Common Subexpression Elimination technique is proposed to replace the constant multipliers. Finally, a recon gurable quantization method is presented to e ectively save the computational complexity. Experimental results obtained with a prototype based on FPGA implementation and com- parisons with existing works corroborate the validity of the proposed optimizations in terms of power reduction, speed increase, silicon area saving and PSNR improvement.
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hal-00685875 , version 1 (03-05-2017)

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Maher Jridi, Ayman Alfalou. Joint Optimization of Low-power DCT Architecture and Effcient Quantization Technique for Embedded Image Compression. 18th International Conference on Very Large Scale Integration (VLSISOC), Sep 2010, Madrid, Spain. pp.155-181, ⟨10.1007/978-3-642-28566-0_7⟩. ⟨hal-00685875⟩
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