Your search keyword '"*STATIC VAR compensators"' showing total 5 results

1. A complexity-scalable hybrid H.264/AVC-to-SVC transcoder.

Subjects

*COMPUTATIONAL complexity, *COMPUTER networks, *SCALABILITY, *HYBRID systems, *CODING theory, *STREAMING video & television, *COMPUTER architecture

Abstract

Transcoding of H.264/AVC bitstreams is frequently used for adapting video streams to varying network conditions or different end-user device characteristics. Transcoding requires a relatively high complexity (and thus high operational cost) for each adaptation operation, and possibly reduces the video quality. In comparison, transcoding the input bitstream to SVC requires only one adaptation step. Afterwards, the resulting SVC bitstream can be adapted instantly. To reduce the H.264/AVC-to-SVC transcoding complexity, a transcoding architecture which combines existing open-loop transcoding techniques with optimized closed-loop transcoding is proposed. Furthermore, this approach allows to scale the complexity of the system. Doing so, compared with a cascaded decoder-encoder only 8.48% of the complexity is required for the highest complexity, while a high rate-distortion efficiency is maintained and a high degree of scalability is guaranteed. When only limited resources are available, the transcoding complexity can be scaled such that over 99% of the complexity is reduced compared to a cascaded decoder-encoder. [ABSTRACT FROM PUBLISHER]

Published

2013

2. Designing and implementing a scalable video-streaming system using an adaptive control scheme.

Author

Hsiao, Yi-Mao, Chen, Chia-Hsiang, Lee, Jeng-Farn, and Chu, Yuan-sun

Subjects

*SYSTEMS design, *SCALABILITY, *STREAMING video & television, *ADAPTIVE control systems, *COMPUTER networks, *BANDWIDTHS, *SIGNAL-to-noise ratio

Abstract

Designing a real-time video-streaming system involves the challenges of, network congestion and bandwidth fluctuations, lowering the video quality. In this paper, a realtime video-streaming system is designed and implemented for scalable video coding (SVC) with an adaptive control scheme, containing macro- and micro-control, to resolve the bandwidth fluctuation and network congestion. Under macro-control, the server allocates appropriated video-streaming of SVC for heterogeneous clients based on terminal capacity and network conditions. Under micro-control, the server changes the video frame rate based on video bit rates and network bandwidth. The streaming system with the adaptive control scheme is implemented to improve the peak signal noise ratio (PSNR) by 4.01 % to 10.89 % of the Foreman and Stefan videos. [ABSTRACT FROM AUTHOR]

Published

2012

3. Memory and computation efficient hardware design for a 3 spatial and temporal layers SVC encoder.

Author

Lee, Kyujoong, Rhee, Chae, Lee, Hyuk-Jae, and Kang, Jung

Subjects

*VIDEO coding, *SPATIAL analysis (Statistics), *COMPUTER networks, *SCALABILITY, *BANDWIDTHS

Abstract

Spatial and temporal scalability in Scalable Video Coding (SVC) compression enables a video encoder to generate bit streams efficiently for various resolutions and frame rates. However, doing this requires more complex computations and greater memory bandwidth than H.264/AVC compression. In this paper, the performance and memory bandwidth for a SVC hardware encoder with three spatial and temporal layers are analyzed. Based on the analysis, a novel method is proposed for the source and interlayer data load. Experimental results show that the memory bandwidth is reduced by 77%. Furthermore, the memory access latency of the source data for the base layer is reduced by creating a data load for the base layer overlap with the execution of the enhancement layer. To satisfy the latency requirement, a mode pre-decision algorithm for a hardware SVC encoder is proposed. It reduces the computation of the fractional motion estimation (FME) and the inter-layer residual prediction by 80%. Simulation results show that the proposed methods decrease the BD-PSNR by 0.05 dB and increase the BD-BR by 1.64%, an amount that can be considered negligible in terms of degradation, while an encoding speed of 30 fps for Full HD (1920?1080) videos is achieved at an operating clock frequency of less than 200 MHz.1 [ABSTRACT FROM AUTHOR]

Published

2011

4. Fast mode decision for combined scalable video coding based on the block complexity function.

Subjects

*COMPUTER networks, *SCALABILITY, *CODING theory, *ALGORITHMS, *COMPUTATIONAL complexity, *STATISTICAL correlation, *SIMULATION methods & models, *IMAGE quality analysis

Abstract

Scalable Video Coding is an H.264/AVC scalable extension that is used to provide various network-friendly scalability using a single bit stream. In SVC, the newly adapted predictive coding techniques can achieve high encoding efficiency, but they increase the computational complexity. To reduce the computational complexity, we present a fast mode decision algorithm based on the block complexity function considering the degree of correlation between base layer and enhancement layer. The simulation results show that the encoding time of the proposed fast mode decision algorithm for the combined scalability is about 54.72% compared with normal method although the loss of visual quality is negligible. [ABSTRACT FROM PUBLISHER]

Published

2011

5. Motion-based temporal transcoding from H.264/AVC-to-SVC in baseline profile.

Subjects

*SYNCHRONOUS capacitors, *ELECTRIC potential, *MOBILE communication systems, *DATA transmission systems, *HOUSEHOLD electronics, *BIT rate, *CODING theory, *COMPUTER networks, *SCALABILITY

Abstract

Video contents needs to be compressed in order to reduce the resources required for storage and network transmission. It is desirable that the encoded bitstreams are adaptable to the varying characteristics of consumer electronics devices and heterogeneous networks. Scalable Video Coding provides temporal, spatial and quality scalability by organizing the encoded bitstream into layers. Since the majority of the produced video content is currently encoded using H.264/AVC, it will be necessary to implement techniques for converting from single-layer H.264/AVC to scalable bitstreams. In this paper, a technique for transcoding from H.264/AVC-to-SVC with temporal scalability in Baseline Profile is discussed. Applying the presented approach, a reduction of 64% of the coding complexity is achieved while maintaining the coding efficiency. [ABSTRACT FROM PUBLISHER]

Published

2011