一种高效的运动补偿三维小波视频编码方案

该文提出了一种高效的运动补偿三维小波视频编码方案。该方案采用运动补偿时域分析技术,以有效去除视频序列中存在的时间冗余。然后,基于视频序列的运动特征,自适应确定帧组结构,在提高编码效率的同时降低内存需求和运算复杂度。最后,根据小波图像系数特性,采用基于四叉树分裂的小波图像编码方法对三维时/空子带进行编码,以获得更高的压缩效率。实验结果表明,与其它运动补偿三维小波视频编码方法相比,该文提出的编码方案能够获得更好的性能。     

应用Virtual SPECK的视频编码技术

讨论并实现了基于提升格式三维小波变换的Virtual SPECK视频编码方法。该方法不涉及运动估计和运动补偿，具有计算量较小、编码快、低复杂的特点，产生的视频流是完全嵌入的。实验结果表明该方法能够快速的高效的压缩视频图像，是一种很有潜力的视频压缩编码方法。     

彩色分层和相位相关的视频稳像

针对小波变换和相位相关法实现的视频稳像精度不足的问题,本文引入彩色分层技术,提出了一种新的视频稳像技术方法.首先,对待处理视频图像进行彩色分层,分别进行小波变换(即金字塔式分层),并利用相位相关法求取相关运动矢量,然后对矢量参数进行权值滤波处理以保留正常扫描运动而去除抖动矢量,最后针对抖动量进行运动补偿实现视频稳像.针...     

基于小波变换的视频图像压缩算法研究

提出一种时域加强并结合时间轴稳定性码率控制的三维小波变换的视频图像编码方法。该算法根据人类视觉系统(HVS)的特性对视频图像不同频率的数据进行粗细不同的量化,可以很好地解决当图像运动变化较大时所产生的大数据量的问题;该算法无运动估计和补偿环节,降低了复杂度;采用提升型变换可以节省内存空间并提高运算速度;进行了码率控制,得到了良好的时间轴稳定性,提高了视频图像的清晰度和流畅度。     

一种新的3－D小波变换图像编码方法

基于图像序列三维小波变换的视频编码技术是一种很有潜力的编码方法．本文针对目前实际中采用的三维小波变换只是一种准三维变换，不能提供对变换结果的统一描述等不足，推导了信号真正的三维小波变换的有关理论及其实现方法．在此基础上，我们将这种三维小波变换方法用于视频图像的编码，模拟结果表明这种编码结构具有良好性能，值得进一步的深入研究．     

一种新的3—D小波变换图像编码方法

基于图像序列三小波变换的视频编码技术是一种很有潜力的编码方法。本文针对目前实际中采用的三维小波变换只是一种准三维变换，不能提供对变换结果的统一描述等不足，推导了信号真正的三维小波变换的有关及其实现方法，在此基础上，我们将这种三维小波变换方法用于视频图像的编码，模拟结果表明这种编码结构具有良好性能，值得进一步的深入研究     

一种基于最佳比特分配策略的三维小波视频编码新方法

对基于三维小波变换的视频编码进行了研究。由于视频图像传统的三维小波变换结构存在着诸多不足．文章提出了一种改进的三维小波变换结构。在给定的比特率条件下，通过对使得解码图像量化误差达到最小的最佳比特分配策略进行研究，给出了在均匀量化情况下的改进三维小波变换结构的量化步长。实验结果表明该方法的压缩性能明显优于传统方法。     

一种基于运动补偿三维小波的 多描述视频编码方法

 本文将多描述编码与运动补偿三维小波可扩展视频编码相结合,提出了一种基于运动补偿三维小波的多描述视频编码方法.该方法首先根据编码序列的运动特性,自适应地进行每个描述的码率分配,以控制各个描述中的冗余,然后将编码序列的关键信息-运动矢量和低频帧码流复制到两个描述中,并将高频帧码流分配到不同的描述中.在解码端根据正确接收信息的不同,采用不同的方法进行视频重建.实验结果表明,与单描述编码方法相比,在信道丢包率较高的情况下,本文方法可以提供更好的传输鲁棒性.     

一种新的小波可视电话编码算法

针对极低比特率应用提出一种新的结合H.263与SLCCA的混合小波视频编码算法。在提出的算法中,首先,用基于H.263的微调运动估计减小时间冗余,用无遗漏覆盖块运动补偿保证运动补偿误差帧的连续性;第二,对运动补偿误差帧进行小波变换得到全局能量压缩;第三,用SLCCA组织和表示小波变换后的数据,最后,运动向量的水平和垂直分量分别用自适应算法编码,算法在A级测试序列Akiyo和B级测试序列Foreman（QFIF）上测试取得了良好效果。     

一种时域质量稳定的三维小波视频编码率控制技术

三维小波视频编码提供了分辨率、时域和质量的可伸缩性。在三维小波编码中，如何调整各小波频带间的码率分配以达到最佳的码率控制至关重要。就小波变换和反变换的结构而言，常规的三维小波视频编码方法会导致解码视频帧沿时间方向播放质量的周期振荡，这种周期的振荡会影响了观看质量。本文研究了重建信号与小波频带间失真分布的关系，提出了一种具有稳定的时域解码质量的率控制方法，实验结果表明该算法在保证播放质量稳定的同时，还具有与常规三维小波视频编码方法近似的平均解码质量。     

Lifting-based invertible motion adaptive transform (LIMAT) framework for highly scalable video compression

We propose a new framework for highly scalable video compression, using a lifting-based invertible motion adaptive transform (LIMAT). We use motion-compensated lifting steps to implement the temporal wavelet transform, which preserves invertibility, regardless of the motion model. By contrast, the invertibility requirement has restricted previous approaches to either block-based or global motion compensation. We show that the proposed framework effectively applies the temporal wavelet transform along a set of motion trajectories. An implementation demonstrates high coding gain from a finely embedded, scalable compressed bit-stream. Results also demonstrate the effectiveness of temporal wavelet kernels other than the simple Haar, and the benefits of complex motion modeling, using a deformable triangular mesh. These advances are either incompatible or difficult to achieve with previously proposed strategies for scalable video compression. Video sequences reconstructed at reduced frame-rates, from subsets of the compressed bit-stream, demonstrate the visually pleasing properties expected from low-pass filtering along the motion trajectories. The paper also describes a compact representation for the motion parameters, having motion overhead comparable to that of motion-compensated predictive coders. Our experimental results compare favorably to others reported in the literature, however, our principal objective is to motivate a new framework for highly scalable video compression.     

高性能三维小波视频编码方法

讨论并实现了基于３Ｄ－ＳＰＩＨＴ算法的三维小波视频编码方法。该方法建立在真三维小波分解基础上，通过定义一种新的时空方向树结构，实现了静止图像ＳＰＩＨＴ算法的三维扩展。该方法不涉及运动估计，具有较低的计算负荷和时间延迟，所产生的视频流是完全嵌入的。实验结果表明该方法能够快速地、高质量地压缩视频图像，是一种很有潜力的视频编码方法。     

Scalable wavelet video coding using aliasing-reduced hierarchicalmotion compensation

We describe a spatially scalable video coding framework in which motion correspondences between successive video frames are exploited in the wavelet transform domain. The basic motivation for our coder is that motion fields are typically smooth and, therefore, can be efficiently captured through a multiresolutional framework. A wavelet decomposition is applied to each video frame and the coefficients at each level are predicted from the coarser level through backward motion compensation. To remove the aliasing effects caused by downsampling in the transform, a special interpolation filter is designed with the weighted aliasing energy as part of the optimization goal, and motion estimation is carried out with low pass filtering and interpolation in the estimation loop. Further, to achieve robust motion estimation against quantization noise, we propose a novel backward/forward hybrid motion compensation scheme, and a tree structured dynamic programming algorithm to optimize the backward/forward mode choices. A novel adaptive quantization scheme is applied to code the motion predicted residue wavelet coefficients, Experimental results reveal 0.3-2-dB increase in coded PSNR at low bit rates over the state-of-the-art H.263 standard with all enhancement modes enabled, and similar improvements over MPEG-2 at high bit rates, with a considerable improvement in subjective reconstruction quality, while simultaneously supporting a scalable representation.     

结合零树的分形运动补偿编码算法的研究

当前的视频编码算法无论是使用小波变换、分形理论还是运动补偿技术，使用单一的编码算法总是存在着压缩效率与实时视觉的矛盾。至今为止，已提出的小波分形混合编码方法也没能很好地利用小波变换后系数的统计特性，压缩的效果不论是在压缩比PSNR或是可伸缩性上并不理想，为此，本文提出了一种小波域内基于零树特点的分形运动补偿混合编码算法。实验证明，该算法具有良好的压缩性能，并且在重建图像和拥有逼真的视觉特件，获得了可伸缩的能够渐进的传输的编码码流。     

Hybrid picture coding with wavelet transform and overlappedmotion-compensated interframe prediction coding

A novel video coding scheme using an orthonormal wavelet transform is proposed. The wavelet transform is used in a motion compensated interframe coder in which a blockless motion compensation technique is employed to increase efficiency of wavelet transform coding. A new scanning method for wavelet coefficients is also proposed which is rather different from subband coding. Simulation work is carried out to evaluate the proposed coding method. Significant improvement in subjective quality is obtained over that obtained with conventional hybrid coding methods that use blockwise motion compensation and DCT. Some improvement has also been realized in the signal to noise ratio. Although wavelet coding is still in its early stages of development, it appears to hold great promise for motion picture coding     

Scalable video compression via overcomplete motion compensated wavelet coding

Recently, there have been a flurry of works on overcomplete motion compensated wavelet coding (OMCWC). In this paper, we address the importance of phase and focus on the design of scalable video coding algorithms within the OMCWC framework. Specifically, our new contributions consist of the following three components: (1) efficient block motion estimation techniques in the wavelet domain including hierarchical and fractional-pel block matching, (2) extend overcomplete motion compensated prediction (MCP) into overcomplete motion compensated temporal filtering (MCTF) to achieve temporal scalability (3) context modeling strategies for embedded quantization and entropy coding of 3D wavelet coefficients. Experiment results are used to demonstrate that the class of overomplete MCP/MCTF coders are capable of achieving comparable performance to other competing interframe wavelet coders.     

Flexible three-band motion-compensated temporal filtering for scalable video coding

A novel scheme for scalable video coding using three-band lifting-based motion-compensated transform is presented in this article. A series of flexible three-band motion-compensated lifting steps are used to implement the temporal wavelet transform, which provide improved compression performance by selecting specific motion model according to real video sequences, and offer higher temporal scalability flexibility by using three-band lifting steps. The experimental results compared with motion picture expert group (MPEG)-4 codec concerning standard video sequences demonstrate the effectiveness of the method.     

Bottom-up motion compensated prediction in wavelet domain for spatially scalable video coding

A new in-band motion compensation algorithm for wavelet-based video coding is proposed: the bottom-up prediction algorithm (BUP). This algorithm overcomes the periodic shift-invariance of the discrete wavelet transform (DWT) and is formalised into prediction rules using filtering operations. The combination of all prediction rules of the BUP algorithm defines a new transform: the bottom-up overcomplete DWT or BUP ODWT, which is shift-invariant. The envisaged application for the BUP algorithm is spatially scalable wavelet video coding.