低速率视频传输的抗误码技术

误码掩盖是在无线信道进行低速率视频传输的一种抗误码技术。本文在比较和分析了现有几种误码掩盖方法优劣势后,提出了一种混合误码掩盖法。该算法在没有过多增加解码端运算复杂度的同时,大大提高了恢复图像的质量。     

H．264后处理误码掩盖技术

数字视频通信中往往会由于信道不理想等原因而产生误码,而且误码在空间和时间上的扩散会导致重建图像质量不同程度的下降.而误码掩盖技术就是用来改进重建视频质量的重要方法之一.文章论述了国内外误码掩盖技术的现状及其典型算法,分析了误码掩盖技术的应用范围和性能,最后指出误码掩盖技术的发展前景.     

视频通信中的误码掩盖技术初探

在数字视频通信中,由于信道不理想等原因容易产生误码,而且误码在空间和时间上的扩散会导致重建图像质量不同程度的下降。最近发展起来的误码掩盖技术就是用来解决这类问题、改进重建视频质量的重要方法之一。在简要介绍误码掩盖的基本原理和相关技术的基础上,着重分析了新近采用的几种误码掩盖方法的应用范围和性能,并指出了它们的发展前景。．     

基于H.264的改进时域误码掩盖算法

提出一种模式自适应的误码掩盖算法。对宏块进行误码掩盖时,对宏块的模式进行估计,选择最优的模式进行误码掩盖。这样可以近似地恢复了宏块运动矢量和编码模式,而不是通常算法中仅仅只恢复运动矢量。通过一定的实验测试,该算法在不同的序列和不同的丢包率均稳定的优于单一模式的误码掩盖算法。     

视频通信中空域和时域误码掩盖方法的研究

随着多媒体通信技术的不断发展,在无线网络和因特网上进行视频传输显得尤为迫切。但是在传输过程中,误码几乎是不可避免的。文中从空域和时域出发,回顾了国外主流视频通信误码掩盖技术,分析了它们的应用范围和性能,并指出了其发展前景。     

基于多方向边界匹配的视频误码掩盖算法

视频压缩码流对于信道误码十分敏感,可能导致重建图像质量严重下降.误码掩盖技术利用图像在时间和空间上的相关性,可以有效地降低误码对视频图像的影响.文中提出了一种基于多方向边界匹配的时域误码掩盖算法.该算法能更精确地恢复错误宏块的运动矢量,从而获得比传统的时域掩盖算法更好的视频质量.     

基于H.263视频解码的误码掩盖技术研究

本文提出了一种基于接收端像素域的误码掩盖算法,包括误码检测、重同步、误码定位和估计误码数据等四个环节。计算机模拟结果显示,经误码掩盖之后的图像质量有显著的改善     

基于无线H．264时域误码掩盖算法的改进

为解决传统H.264时域误码掩盖算法中丢失块的相邻运动矢量在无线环境下极易丢失的问题,结合部分误码掩盖算法研究成果,提出了一种利用相邻参考帧和丢失块相邻运动矢量,运用投影加权的方法估计出最优丢失块运动矢量用于误码补偿的改进误码掩盖算法.实验证明,运用改进算法掩盖后的图像质量有所提高,并且抑制了误码的错误积累和扩散,具有一定实际应用意义.     

一种新颖实用的交互式视频抗误码方法

本文提出一种新颖的交互式视频抗误码方法.首先,分析了块匹配运动补偿编码方法产生时域误码扩散的机理,然后,相应地提出了一种新颖的误码掩盖和防止误码扩散联合方法.实验结果表明,使用本文提出的交互式视频抗误码方法能够有效地抑制和防止误码的扩散,保证了恢复视频质量.另外,该算法与H.263+标准兼容,具有实用价值.     

基于H.264/AVC的多参考帧时域误码掩盖

根据H．264／AVC编码的新特点,提出两种基于多参考帧的误码掩盖方法：一种是基于运动矢量均值的多参考帧误码掩盖;另一种是基于加权的多参考块的误码掩盖。仿真实验表明,解码后的图像质量优于H．264／AVC传统校验模型JM5．0的误码掩盖方法。     

Error control and concealment for video communication: a review

The problem of error control and concealment in video communication is becoming increasingly important because of the growing interest in video delivery over unreliable channels such as wireless networks and the Internet. This paper reviews the techniques that have been developed for error control and concealment. These techniques are described in three categories according to the roles that the encoder and decoder play in the underlying approaches. Forward error concealment includes methods that add redundancy at the source end to enhance error resilience of the coded bit streams. Error concealment by postprocessing refers to operations at the decoder to recover the damaged areas based on characteristics of image and video signals. Last, interactive error concealment covers techniques that are dependent on a dialogue between the source and destination. Both current research activities and practice in international standards are covered     

3D视频的错误隐藏快速算法

具有独特编码结构的3D视频在不可靠信道上传输时遭遇丢包后极易造成错误传播,因此研究基于3D视频的错误隐藏技术十分必要。而且,压缩后传输的3D视频数据量仍然较大,这对解码器的解码速度提出了很高的要求。如何在解码端加速进行错误隐藏是研究重点,通过快速定位静止宏块的方法加速错误隐藏速度。实验结果表明该算法在保证不降低视频的主、客观质量的同时,能有效地降低错误隐藏算法的复杂度。     

基于H.264的差错掩盖技术的研究

介绍了基本的差错掩盖技术以及最近新提出的基于H.264的差错掩盖技术,并对在编码端加入引导信息的决策树法进行了改进,给出了初步的实验结果,最后概括了这些掩盖方法的特点.     

基于3G的H.264视频编码数据传输

论述了H.264视频编码数据在无线网络上的有效传输,综合运用了帧内更新,交织的前向纠错(FEC)和错误隐藏技术.实验表明,此方法在无线信道中传输视频编码数据效果良好.     

基于内容的无线视频误码隐藏技术仿真

仿真了基于内容的误码隐藏技术,分析了各种技术的性能,最后给出了在实际的通信系统中如何选择合适的误码隐藏技术的结论,即误码隐藏技术必须根据视频特征和实际应用来决定采用何种技术.     

Error concealment techniques for digital TV

Compressed video bitstreams are intended for real-time transmission over communication networks. Most of the video coding standards employ the temporal and spatial prediction structure to reduce the transmitted video data. Therefore, the coded video bitstreams are highly sensitive to information loss and channel errors. Even a single bit error can lead to disastrous quality degradation in both time and space. This quality deterioration is exacerbated when no error resilient coding mechanism is employed to protect coded video data against the error prone environments. Error concealment is a data recovery technique that enables the decoder to conceal effects of transmission errors by predicting the lost or corrupted video data from the previously reconstructed error-free information. Motion vector recovery and motion compensation with the estimated motion vector is a good approach to conceal the corrupted macroblock data. In this paper, we develop various error concealment algorithms based on motion vector recovery, and compare their performances to those of conventional error concealment methods.     

地面数字电视广播系统中的视频传输容错算法

本文提出了一套针对MPEG-2视频压缩数据传输的自适应容错机制,用于支持地面数字电视广播系统中的可靠电视传输.具体地,本文首先提出了一种基于时域隐藏和块匹配的差错隐藏算法,在保持较好隐藏效果的同时,通过有效地减小搜索窗口而显著降低了算法复杂度.同时,针对独立I帧图像还提出了独特的差错隐藏方法.将这两种差错隐藏算法与低运算复杂度的空域/时域运动检测方法相结合,又衍生出一种自适应空/时域结合差错隐藏算法.仿真结果表明,本文提出的算法即使在很高的数据差错率情况下,仍然可以实现地面数字电视广播系统中可靠而高效的视频传输.     

A joint encoder–decoder error control framework for stereoscopic video coding

Stereoscopic video coding (SSVC) plays an important role in various 3D video applications. In SSVC, robust stereoscopic video transmission over error-prone networks is still a challenge problem to be solved. In this paper, we propose a joint encoder–decoder error control framework for SSVC, where error-resilient source coding, transmission network conditions, and error concealment scheme are jointly considered to achieve better error robustness performance. The proposed joint encoder–decoder error control framework includes two parts: an error concealment algorithm at the decoder side and a rate–distortion optimized error resilience algorithm at the encoder side. For error concealment at the decoder side, an overlapped block motion and disparity compensation based error concealment scheme is proposed to adaptively utilize inter-view correlations and temporal correlations. For error resilience at the encoder side, first, the inter-view refreshment is proposed for SSVC to suppress error propagations. Then, an end-to-end distortion model for SSVC is derived, which jointly considers the transmission network conditions, inter-view refreshment, and error concealment tools at the decoder side. Finally, based on the derived end-to-end distortion model, the rate–distortion optimized error resilience algorithm is presented to adaptively select inter-view, inter- or intra-coding for SSVC. The experimental results show that the proposed joint encoder–decoder error control framework has superior error robustness performance for stereoscopic video transmission over error-prone networks.