远程网络视频监控系统的设计与实现

提出了一种使用组播技术 ,用MPEG 4进行编解码的网络视频监控系统的设计与实现方法。文中首先介绍了系统的总体结构 ,然后重点讨论了系统中软件部分各主要功能模块的具体实现。     

嵌入式视频监控系统视频服务器的设计与实现

提出了基于AT91RM9200微处理器的嵌入式Linux视频监控系统[1]的视频服务器设计方法.采用韩国Pentamicro公司的视频芯片AT2042对数字视频数据进行MPEG-4压缩编码,生成MPEG-4码流.为实现交互性的要求,在嵌入式WEB服务器中采用CGI技术,对远程监控端的控制信息分析处理,实现B/S模式的交互功能和系统的远程控制.与传统的设计方法相比,该系统视频图像的质量得到改进,开发便捷,成本低廉,应用范围广.     

道路视频监控系统的设计

采用MPEG-4图像编码标准,使用TCP／IP网络协议,组建了一个道路视频监控系统。从硬件的选取到管理端软件的设置,该系统都体现了其先进性。该系统可以及时发现异常突发事件,及时采取措施,减少对道路交通的影响。     

新型嵌入式视频监控系统的设计

介绍了一种嵌入式视频监控系统的设计与实现方法。该系统可用于完成视音频信号的采集、MPEG-4编解码和传输三大功能。文中给出了用视频采集模块、音频模块、存储模块、无线模块、以太网传输模块等组成的视频监控系统的总体框架、同时给出了主要系统模块的设计与实现方法。     

一种嵌入式移动视频监控系统的设计

介绍了一种基于嵌入式处理器的移动视频监控系统。系统硬件平台由CMOS图像传感器、G07007SB视频编码器、S3C4510B处理器组成，负责MPEG-4视频数据的采集和压缩编码；软件实现了MPEG-4数据的RTP封装和网络传输。     

基于DirectShow的 MPEG-4远程视频监控系统

介绍了基于网络的多媒体远程监控系统,根据Sockets网络编程技术以及Directshow技术,着重研究了在DirectShow的架构上如何实现基于MPEG-4的远程监控系统,并给出了相应的实现方案.     

远程网络视频监控系统的设计与应用

本文提出了一种使用组播技术,用MPEG-4进行编解码的网络视频监控系统的设计方案,并对系统的总体结构和用到的关键技术进行了介绍,重点讨论了系统中软件部分各主要功能模块的具体实现。     

基于V4L2的移动视频监控系统研究与设计

设计了一种基于ARM-Linux的移动视频监控系统,介绍了嵌入式Linux操作系统下的V4L2视频采集流程。该系统分为采集端和监控端,采集端主要完成视频采集、图像压缩处理和视频传输等功能;远程监控端通过手机3G上网方式连接到视频采集端,从而实现视频监控功能。该系统结构简单,使用便利,成本低廉,非常适用于家居安防。     

远程网络视频监控系统的设计与实现

本提出了一种使用组播技术，用MPEG-4进行编解码的网络视频监控系统的设计方案，并对系统的总体结构和用到的关键技术进行了介绍，重点讨论了系统中软件部分各主要功能模块的具体实现。     

3G视频监控系统传输部分的设计

提出了一种基于3G网络传输的移动视频监控系统传输部分的设计方法,重点对系统传输部分的设计和实时传输的实现作了详细介绍.经测试,该传输部分在本视频监控系统中工作稳定并已得到良好应用.     

一种基于CDMA系统的MPEG-4视频传输速率平滑算法

该文研究了码分多址(CDMA)系统中反向链路上传输MPEG-4视频流的速率平滑算法。由于MPEG-4视频编码具有峰值速率高、速率变化频繁等特点,使得在CDMA蜂窝系统中传输变比特速率(VBR)视频有一定的难度。通过对MEPG视频在图像组(GOP)内应用速率平滑算法,结合CDMA系统物理层的传输速率匹配,可减小传输速率的峰值和变化率,节约带宽。仿真结果表明,该算法有利于提高反向链路系统稳定性,并保证MPEG-4视频的QoS要求,对于信道条件较差的用户,该算法带来的性能改进较明显。     

基于MPEG-4视频采集PCI板卡的设计与实现

介绍一种基于MPEG-4的视频压缩编码卡。该板卡为4路的编码PCI卡，将采集到的模拟视频图像以MPEG-4的方式进行压缩处理。使用标准PCI2．2的规范，完成有CPU控制板与编码PCI卡之间的通信，使CPU控制板通过一块桥芯片可以访问编码芯片内部寄存器，读出编码芯片压缩的MPEG-4的视频压缩流、音频压缩流。从而使压缩的MPEG-4数据完成远程传输或本地存贮。另一个是完成视频预览功能。该板卡为实现远程实时监控提供了必要的硬件设备，他以最新的MPEG-4压缩方式进行编码，对整个数字监控系统和视频网络传输系统提供了最优化的硬件设计，使视频数据数字化管理更加方便、可靠，也使整个系统在市场竞争中更具有活力。     

Platform-Based MPEG-4 SOC Design for Video Communications

An MPEG-4 video coding SOC design is presented in this paper. We adopt platform-based architecture with an embedded RISC core and efficient memory organization. A motion estimator supporting predictive diamond search and spiral full search is implemented for compromise between compression performance and design cost. The proposed data reuse scheme reduces required memory access bandwidth. For texture coding path, an interleaving DCT/IDCT scheduling with substructure sharing technique is proposed. Several key modules are integrated into an efficient platform in hardware/software co-design fashion. The cost-efficient video encoder SOC consumes 256.8 mW at 40 MHz and achieves real-time encoding of 30 CIF (352×288) frames per second. Yung-Chi Chang was born in Kaohsiung, Taiwan, R.O.C., in 1975. He received the B.S. and M.S. degrees from the Department of Electrical Engineering, National Taiwan University, Taipei, Taiwan, R.O.C., in 1998 and 2000, respectively, where he is currently pursuing the Ph.D. degree in the Graduate Institute of Electrical Engineering. His research interests include video coding algorithms and VLSI architectures for image/video processing. Wei-Min Chao was born in Taoyuan, Taiwan, R.O.C., in 1977. He received the B.S. and M.S. degrees from the Department of Electronics Engineering, National Taiwan University in 2000 and 2002 separately. His research interests include video coding algorithms and VLSI architecture for image and video processing. Chih-Wei Hsu was born in Taipei, Taiwan, in 1979. He received the B.S.E.E and M.S.E.E degrees from National Taiwan University (NTU), Taipei, in 2001 and 2003, respectively. He joined MediaTek, Inc., Hsinchu, Taiwan, in 2003, where he develops integrated circuits related to multimedia systems and optical storage devices. His research interests include object tracking, video coding, baseband signal processing, and VLSI design. Liang-Gee Chen was born in Yun-Lin, Taiwan, in 1956. He received the B.S., M.S., and Ph.D. degrees in electrical engineering from National Cheng Kung University, Tainan, Taiwan, in 1979, 1981, and 1986, respectively. He was an Instructor (1981-1986), and an Associate Professor (1986-1988) in the Department of Electrical Engineering, National Cheng Kung University. In the military service during 1987 to 1988, he was an Associate Professor in the Institute of Resource Management, Defense Management College. In 1988, he joined the Department of Electrical Engineering, National Taiwan University. During 1993 to 1994 he was a Visiting Consultant of DSP Research Department, AT & T Bell Lab, Murray Hill. In 1997, he was a visiting scholar of the Department of Electrical Engineering, University of Washington, Seattle. During 2001 to 2004, he was the first director of the Graduate Institute of Electronics Engineering (GIEE) in National Taiwan University (NTU). Currently, he is a Professor of the Department of Electrical Engineering and GIEE in NTU, Taipei, Taiwan. He is also the director of the Electronics Research and Service Organization in Industrial Technology Research Institute, Hsinchu, Taiwan. His current research interests are DSP architecture design, video processor design, and video coding systems. Dr. Chen has served as an Associate Editor of IEEE Transactions on Circuits and Systems for Video Technology since 1996, as Associate Editor of IEEE Transactions on VLSI Systems since 1999, and as Associate Editor of IEEE Transactions on Circuits and Systems II since 2000. He has been the Associate Editor of the Journal of Circuits, Systems, and Signal Processing since 1999, and a Guest Editor for the Journal of Video Signal Processing Systems. He is also the Associate Editor of the Proceedings of the IEEE. He was the General Chairman of the 7th VLSI Design/CAD Symposium in 1995 and of the 1999 IEEE Workshop on Signal Processing Systems: Design and Implementation. He is the Past-Chair of Taipei Chapter of IEEE Circuits and Systems (CAS) Society, and is a member of the IEEE CAS Technical Committee of VLSI Systems and Applications, the Technical Committee of Visual Signal Processing and Communications, and the IEEE Signal Processing Technical Committee of Design and Implementation of SP Systems. He is the Chair-Elect of the IEEE CAS Technical Committee on Multimedia Systems and Applications. During 2001--2002, he served as a Distinguished Lecturer of the IEEE CAS Society. He received the Best Paper Award from the R.O.C. Computer Society in 1990 and 1994. Annually from 1991 to 1999, he received Long-Term (Acer) Paper Awards. In 1992, he received the Best Paper Award of the 1992 Asia-Pacific Conference on circuits and systems in the VLSI design track. In 1993, he received the Annual Paper Award of the Chinese Engineer Society. In 1996 and 2000, he received the Outstanding Research Award from the National Science Council, and in 2000, the Dragon Excellence Award from Acer. He is a member of Phi Tan Phi.     

嵌入式实时MPEG-2以太网传输系统的设计

介绍了一种实时MPEG-2以太网传输系统的设计方案,它由硬件MPEG-2编/解码卡和基于ARM处理器的嵌入式系统卡构成,前者用于视音频的实时压缩编码和解码,后者将MPEG-2数据流进行IP封装和解封装,还分析了IP网络传输对接收端MPEG-2解码视音频的影响,并设计了一些测评方法对系统进行了相关测评.     

基于蓝牙技术的视频传输系统的硬件设计与实现

本文介绍了基于蓝牙技术的视频传输系统的硬件设计与实现。在以ARM芯片作微处理器的系统中,视频信号压缩采用MPEG-4编码格式,并在嵌入式Linux中内置Web服务器应用程序。数据采集压缩模块实时采集视频数据,压缩后经ARM芯片发送给蓝牙传输模块。文中重点讨论了该系统中服务器的组成以及三大模块的功能和硬件实现。     

基于MPEG-4的数字监控系统

介绍了一种基于MPEG-4的数字监控系统的系统构成和软件实现方法。该系统采用MPEG-4标准压缩方法,比较其他压缩方法其压缩比更大。通过对MPEG压缩原理的分析,比较了MPEG-1、MPEG-2和MPEG-4三种标准,说明MPEG-4采用视频对象VO的概念进行编码,更适合远程数字监控。     

Improved rate control for MPEG-4 video transport over wireless channel

Video streaming over wireless channel is challenging due to a number of factors such as limited bandwidth and loss sensitivity. In this paper, we develop a novel rate control algorithm for MPEG-4 video coding. Unlike traditional rate control schemes, we jointly consider the encoding complexity variation and buffer variation as well as human visual properties to optimize the rate control efficiency. We also analyze the sensitivity of a macroblock (MB) as a result of bit errors and calculate its error sensitivity metric. This metric is used in unequal error protection of the MB. Simulation results show that proposed approach can improve the decoded picture quality in wireless video coding and transmission.     

高效实时MPEG-2/4 AAC编码器的实现

介绍了一种高效的MPEG-2/4AAC低复杂度编码器的实现。由于MPEG-2/4AAC算法计算量相当大,为了达到实时性,对窗切换方法、心理声学模型、比特分配、滤波器等模块进行了优化,使其在Pentium41.8GHz处理器上达到比实时编码快4倍的编码速度。而且利用M/S编码和Huffman码表的有效选择,提高了声音质量。     

基于RTP的MPEG-4视频传输策略研究

在简述实时传输协议（RTP）原理及MPEG-4视频编码标准的基础上，提出了MPEG-4视频传输模型，并详细介绍了基于RTP的码率自适应调整算法，通过丢包率和传输延时来分析当前网络状况。采取适当的码率调整策略，使整个传输过程既能充分利用带宽又不引起网络拥塞。实验表明本方案能够在变化的网络状况下取得理想的图像传输质量。     

MPEG-4标准浅析

对支持多媒体应用的MPEG-4标准关键技术进行分析，归纳了MPEG-4标准的新特点，并对MPEG-4的应用前景进行了展望。