Authors: N. Muthukumaran, R. Ravi

Abstract:

The Simulation based VLSI Implementation of FELICS (Fast Efficient Lossless Image Compression System) Algorithm is proposed to provide the lossless image compression and is implemented in simulation oriented VLSI (Very Large Scale Integrated). To analysis the performance of Lossless image compression and to reduce the image without losing image quality and then implemented in VLSI based FELICS algorithm. In FELICS algorithm, which consists of simplified adjusted binary code for Image compression and these compression image is converted in pixel and then implemented in VLSI domain. This parameter is used to achieve high processing speed and minimize the area and power. The simplified adjusted binary code reduces the number of arithmetic operation and achieved high processing speed. The color difference preprocessing is also proposed to improve coding efficiency with simple arithmetic operation. Although VLSI based FELICS Algorithm provides effective solution for hardware architecture design for regular pipelining data flow parallelism with four stages. With two level parallelisms, consecutive pixels can be classified into even and odd samples and the individual hardware engine is dedicated for each one. This method can be further enhanced by multilevel parallelisms.

Keywords: Image compression, Pixel, Compression Ratio, Adjusted Binary code, Golumb Rice code, High Definition display, VLSI Implementation.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1098104

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2028

References:

[1] Chenwei Deng, Weisi Lin “Content- based Image Compression for Arbitrary-Resolution Display Devices” IEEE transactions on multimedia, vol.14, no. 4, August 2012.
[2] Tsung-Han Tsai,Yu-Hsuan Lee and Yu-Yu Lee,“Design and Analysis of High-Throughput Lossless Image Compression Engine Using VLSIOriented FELICS Algorithm” in IEEE Transactions On Very Large Scale Integration (VLSI) Systems, Vol. 18, NO. 1, pp.39-52,Jan 2010.
[3] L. Xiaowen, X. Chen, X. Xie, G. Li, L. Zhang, C. Zhang, and Z.Wang, “A low power, fully pipelined JPEG-LS encoder for lossless image compression,” in Proc. IEEE Int. Conf. Multimedia EXPO, pp. 1906– 1909, 2007.
[4] W. D. Len-Salas, S. Balkir, K. Sayood, N. Schemm, and M. W. Hoffman, “A CMOS imager with focal plane compression using predictive coding,” IEEE J. Solid-State Circuits, vol. 42, no. 11, pp. 2555–2572, Nov. 2007.
[5] L. Yang, H. Lekatsas, and R. P. Dick, “High-performance operating system controlled memory compression,” in Proc. Int. Conf. Des. Autom. Conf., Jul. 2006.
[6] R. Mehboob, S. A. Khan, and Z. Ahmed, “High speed lossless data compression architecture,” in Proc. IEEE Int. Conf. Multitopic, pp. 84– 88, 2006.
[7] X. Xie, G. L. Li, X. K. Chen, C. Zhang, and Z. H. Wang, “A low complexity near-lossless image compression method and its ASIC design for wireless endoscopy system,” in Proc. Int. Conf. ASICON, 2005.
[8] C.-C. Cheng, P.-C. Tseng, C.-T. Huang, and L.-G. Chen, “Multi-mode embedded compression codec engine for power-aware video coding system,” in Proc. IEEE Workshop. Signal Process. Syst., 2005.
[9] P. Corsonello, S. Perri, P. Zicari, and G. Cocorullob, "Microprocessor based FPGA implementation of SPIHT image compression subsystems,” Microprocess. Microsyst., vol. 29, no. 6, pp. 299–305, Aug.2005.
[10] M. Milward, J. L. Nunez, and D. Mulvaney, “Design and implementation of a lossless parallel high-speed data compression system,” IEEE Trans. Parallel Distrib. Syst., vol. 15, no. 6, pp. 481–490, Jun. 2004.