State-of-the-Art and Trends in Scalable Video Compression with Wavelet Based Approaches

3noScalable Video Coding (SVC) differs form traditional single point approaches mainly because it allows to encode in a unique bit stream several working points corresponding to different quality, picture size and frame rate. This work describes the current state-of-the-art in SVC, focusing on wavelet based motion-compensated approaches (WSVC). It reviews individual components that have been designed to address the problem over the years and how such components are typically combined to achieve meaningful WSVC architectures. Coding schemes which mainly differ from the space-time order in which the wavelet transforms operate are here compared, discussing strengths and weaknesses of the resulting implementations. An evaluation of the achievable coding performances is provided considering the reference architectures studied and developed by ISO/MPEG in its exploration on WSVC. The paper also attempts to draw a list of major differences between wavelet based solutions and the SVC standard jointly targeted by ITU and ISO/MPEG. A major emphasis is devoted to a promising WSVC solution, named STP-tool, which presents architectural similarities with respect to the SVC standard. The paper ends drawing some evolution trends for WSVC systems and giving insights on video coding applications which could benefit by a wavelet based approach.partially_openpartially_openADAMI N; SIGNORONI. A; R. LEONARDIAdami, Nicola; Signoroni, Alberto; Leonardi, Riccard

A New Compressive Video Sensing Framework for Mobile Broadcast

A new video coding method based on compressive sampling is proposed. In this method, a video is coded using compressive measurements on video cubes. Video reconstruction is performed by minimization of total variation (TV) of the pixelwise discrete cosine transform coefficients along the temporal direction. A new reconstruction algorithm is developed from TVAL3, an efficient TV minimization algorithm based on the alternating minimization and augmented Lagrangian methods. Video coding with this method is inherently scalable, and has applications in mobile broadcast

Devolopment of Mean and Median Based Adaptive Search Algorithm for Motion Estimation in SNR Scalable Video Coding

Now a day’s quality of video in encoding is challenging in many video applications like video conferences, live streaming and video surveillance. The development of technology has resulted in invention of various devices, different network conditions and many more. This has made video coding challenging day by day. An answer to the need of all can be scalable video coding, where a single bit stream contains more than one layer known as base and enhancement layers respectively. There are various types of scalability as spatial, SNR, temporal scalability. Among these three types of scalability, SNR scalability deals with the quality of the frames i.e. base layers includes least quality frames and enhancement layer gets frames with better quality. Motion estimation is the most important aspect of video coding. Usually the adjacent frames of a video are very much similar to each other. Hence to increase the coding efficiency to remove redundancy as well as to reduce computational complexity,motion should be estimatedand compensated.Hence, in the scalable video coding, videos have been encoded in SNR scalability mode and then the motion estimation has been carried out by two proposed methods.The approach depends on eliminating the unnecessary blocks, which have not undergone motion, by taking the specific threshold value for every search region. It is desirable to reduce the time of computation to increase the efficiency but keeping in view that not at the cost of much quality. In second method, the search method has been optimized using ‘particle swarm optimization’ (PSO) technique, which is a method of computation aims at optimizing a problem with the help of popular candidate solutions.In block matching based on PSO, a swarm of particles will fly in random directions in search window of reference frame, which can be indexed by the horizontal and vertical coordinates of the center pixel of the candidate block. These algorithm mainly used to reducing the computational time by checking some random position points in the search window for finding out the best match.PSO algorithm estimate the motion with very low complexity in the context of video estimation. Both the methods have been analyzed and performance have been compared with various video sequences.The proposed technique out performs to the existing techniques in terms of computational complexity and video qualit

Motion Scalability for Video Coding with Flexible Spatio-Temporal Decompositions

PhDThe research presented in this thesis aims to extend the scalability range of the wavelet-based video coding systems in order to achieve fully scalable coding with a wide range of available decoding points. Since the temporal redundancy regularly comprises the main portion of the global video sequence redundancy, the techniques that can be generally termed motion decorrelation techniques have a central role in the overall compression performance. For this reason the scalable motion modelling and coding are of utmost importance, and specifically, in this thesis possible solutions are identified and analysed. The main contributions of the presented research are grouped into two interrelated and complementary topics. Firstly a flexible motion model with rateoptimised estimation technique is introduced. The proposed motion model is based on tree structures and allows high adaptability needed for layered motion coding. The flexible structure for motion compensation allows for optimisation at different stages of the adaptive spatio-temporal decomposition, which is crucial for scalable coding that targets decoding on different resolutions. By utilising an adaptive choice of wavelet filterbank, the model enables high compression based on efficient mode selection. Secondly, solutions for scalable motion modelling and coding are developed. These solutions are based on precision limiting of motion vectors and creation of a layered motion structure that describes hierarchically coded motion. The solution based on precision limiting relies on layered bit-plane coding of motion vector values. The second solution builds on recently established techniques that impose scalability on a motion structure. The new approach is based on two major improvements: the evaluation of distortion in temporal Subbands and motion search in temporal subbands that finds the optimal motion vectors for layered motion structure. Exhaustive tests on the rate-distortion performance in demanding scalable video coding scenarios show benefits of application of both developed flexible motion model and various solutions for scalable motion coding

R-D Optimal Scalable Video Coding Using Soft Decision Quantization

In this thesis, we study the concept of scalable video coding as implemented in the extension to the H.264 video coding standard. Specifically, for the spatial and quality scalability scenarios, we propose an optimization algorithm based on the Soft Decision Quantization (SDQ) concept, which aims at jointly optimizing all layers being encoded. The performance of the algorithm was assessed in an SVC implementation. Experimental results show, that the proposed method significantly improves the coding efficiency when compared to an unmodified SVC encoder