Due to the growing maturity of broadband services, multimedia streaming systems and peer-to-peer on demand service are gaining vast popularity in recent times. Stable and reliable transmission of multimedia data is becoming increasingly important for multimedia communication over networks subject to packet erasures. To achieve stability and reliability, efficient fault-tolerant and error-resilience methods for multimedia communication are typical analytical and numerical approaches, so as to attain multi-objective performance metrics. The characteristics of video traffic differ substantially from those of traditional data traffic in four ways. First, packet loss is the major cause of nondeterministic distortion on the Internet and may have significant impact on perceptual quality of the streaming video. Second, aggregate bandwidth requirements, supporting video-on-demand services, are still far in excess of the existing communication network infrastructure. Third, although buffering on the client side can provide an opportunity to absorb variations in transmission rates, it is not sufficient to guarantee the service quality of multimedia streams like IPTV (Internet Protocol television) and VoIP (Voice over IP). Finally, most compressed media data are transmitted over lossy and error-prone networks, and a certain degree of quality degradation is tolerable due to noise in some regions which are below the threshold of human visual perception. Thus, video transmission based on scalable coding and unequal error protection codes can be one of the approaches of maintaining acceptable media quality in a network. Error control for video communication and resource allocation in peer-to-peer multimedia systems remain open issues and are the focus of this work. In this thesis, we built scalable, error-resilient, and high-performance multimedia frameworks to adapt to changing network conditions. We developed a framework of fine-level packetization schemes for the streaming of 3D wavelet-based video content over lossy packet networks. An adaptive fine-granularity unequal error protection algorithm was proposed to allow a tradeoff between rate and distortion, and jointly adopt scalable source coding rates and the level of FEC protection. Experimental results show that the proposed framework strikes a fine balance between the reconstructed video quality and the level of error protection under time-varying lossy channels. In the study of P2P video streaming, we developed a replication strategy to optimize resource allocation based on the video-distortion technique for unstructured P2P overlay networks. Failure recovery action can be accomplished by distributing high quality impact and popular replicas to regions of low peers density or discontinuous areas. The results demonstrated the efficiency and robustness of the proposed method at compensating for network-induced errors, and the framework can be applied at a range of different scales of free-riding peers. Moreover, the proposed algorithm was able to handle the load imposed on the system efficiently and improved average visual quality in the overall system.