Hardware Architecture of CABAC Binary Arithmetic Encoder for HEVC Encoder

Jo, Hyungu; A.N, Gookyi Dennis; Ryoo, Kwangki

doi:10.14257/astl.2016.141.12

Cited by 3 publications

(2 citation statements)

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“…In [15], the author utilized a dedicated core for every bin that is utilized and the utilized bin is processed for every cycle. To improve speed, the author introduced two concurrent four-stage pipelined binary arithmetic encoding cores in [16]. They used a LUT to generate bitstream in order to minimize operating time.…”

Section: Binary Arithmetic Codingmentioning

confidence: 99%

Context-based Adaptive Binary Arithmetic Coding (CABAC): Design and Implementation Using a Multi-Symbol Binary Arithmetic Coder

B. Keerthi Priya, B. Kalyan Chakravarthy

2023

tjjpt

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The most recent standard for encoding video, known as H.265/MPEG-HEVC, achieves a rise in coding efficiency that is fifty percent higher than that of its predecessor, known as H.264/MPEG-AVC. High-resolution video coding (such as 4K, 8K, etc.) has attracted considerable interest since it was anticipated that H.265/MPEG-HEVC will end up replacing practically all current H.264/MPEG-AVC codecs. Video compression is a crucial method, especially in this day and age where greater quality and quicker frame-rate video are in high demand. There are other video compression algorithms available today, but the H.265 standard is one of the most well-known and widely utilized. The standard's last stage is the construction of a binary arithmetic coding algorithm that employs arithmetic coding theory principles to accomplish efficient encoding of the produced information. Binary arithmetic coding (BAC) is an important component of modern video compression techniques. A novel BAC method is examined in this work to demonstrate the feasibility of breaking the dependency of bin-bin in the refreshing of range and low registers. It is suggested to create new dataflow. The design implementation is performed using the Modelsim tool.

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Section: Binary Arithmetic Codingmentioning

confidence: 99%

Context-based Adaptive Binary Arithmetic Coding (CABAC): Design and Implementation Using a Multi-Symbol Binary Arithmetic Coder

B. Keerthi Priya, B. Kalyan Chakravarthy

2023

tjjpt

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“…[4]. In this paper, we propose a hardware design of a CABAC binary arithmetic encoder with high throughput by applying a four-stage pipeline structure that can operate optimally by separating delayed sections in the computation process -this paper is an elaborate version of our previous work [5]. In order to optimize critical path and output the variable bitstream in one cycle, the information bit is generated and output simply through the LUT.…”

Section: Introductionmentioning

confidence: 99%

High-Throughput Architecture of HEVC CABAC Binary Arithmetic Encoder

Jo¹,

Park²,

Ryoo³

2017

IJCA

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This paper proposes an efficient binary arithmetic encoder hardware architecture for CABAC (Context-based Adaptive Binary Arithmetic Coding) encoding. UHD (Ultra High Definition) images require very high throughput for standard video encoder. CABAC is an entropy coding method that is used in HEVC standard. Entropy coding removes statistical redundancy and supports a high compression ratio of images. However, the binary arithmetic encoder causes a delay in real time processing, making parallel processing difficult, because of the high dependency between data. The function of the proposed CABAC BAE hardware structure is to separate the renormalization and process the conventional iterative algorithm in parallel. In addition, it generates an information bit for outputting a bitstream, and outputs a variable bitstream in one cycle. The new scheme was designed as a four-stage pipeline structure that can reduce critical path optimally. The proposed CABAC BAE hardware architecture was designed with Verilog-HDL and synthesized in 65nm technology. Its gate count is 11.2K and maximum clock frequency is 625MHz. It processes 4 Bins per clock cycle, with a 36% increase in maximum processing speed compared to existing hardware architectures.

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