Your search keyword '"DDPCM"' showing total 2 results

1. An Effective Algorithm and Architecture for the High-Throughput Lossless Compression of High-Resolution Images

Author

Jaeshin Lee, Juwon Yun, Jinyoung Lee, Imjae Hwang, Dukki Hong, Youngsik Kim, Cheong Ghil Kim, and Woo-Chan Park

Subjects

Variable length coding, lossless image compression, DDPCM, Golomb-Rice coding, UHD, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes a high-throughput lossless image-compression algorithm based on Golomb-Rice coding and its hardware architecture. The proposed solution increases compression ratios (CRs) while preserving the throughput by taking advantage of a novel parallel variable-length sign coding (PVSC) algorithm that reduces the sign bits to achieve a higher CR. In addition, the proposed solution adopts and modifies the two existing compression algorithms to improve the overall compression performance. The experimental results show that the proposed solution yields an average CR of 3.12, which is higher than those achieved with the previous algorithms. The hardware implementation of the proposed solution for an 8x8 block unit achieves a throughput of 18 GBps and 24 GBps when encoding and decoding, respectively. This hardware performance is enough to handle 7680 x 4320@240-Hz image processing.

Published

2019

2. A Lossless Color Image Compression Architecture Using a Parallel Golomb-Rice Hardware CODEC.

Author

Kim, Hong-Sik, Lee, Joohong, Kim, Hyunjin, Kang, Sungho, and Park, Woo Chan

Subjects

*IMAGE compression, *HARDWARE, *COMPUTER software, *IMAGE reconstruction, *PULSE modulation, *DATA compression, *EXPERIMENTS

Abstract

In this paper, a high performance lossless color image compression and decompression architecture to reduce both memory requirement and bandwidth is proposed. The proposed architecture consists of differential-differential pulse coded modulation (DDPCM) and Golomb-Rice coding. The original image frame is organized as m by n sub-window arrays, to which DDPCM is applied to produce one seed and m\times n-1 pieces of differential data. Then the differential data are encoded using the Golomb-Rice algorithm to produce losslessly compressed data. According to the experimental results on benchmark images, the proposed architecture can guarantee high enough compression rate and throughput to perform real-time lossless CODEC operations with a reasonable hardware area. [ABSTRACT FROM AUTHOR]

Published

2011