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Characterizing and optimizing internet video streaming
thesisposted on 04.03.2020 by Yun seong Nam
In order to distinguish essays and pre-prints from academic theses, we have a separate category. These are often much longer text based documents than a paper.
Internet video comprises a major portion of Internet traffic today. While core and access network capacities continue to grow, optimizing Internet video delivery will remain a challenge, as new forms of video and technology keep emerging, and content publishers continue to seek higher Quality of Experience(QoE) of users due to its correlations with user engagement and revenue. The goals of this thesis are to create a deeper understanding of the Internet video ecosystem and to propose novel methodologies to improve QoE of Internet video delivery. In this thesis, we make the following contributions. First, we create a deeper understanding of video management plane by characterizing it, at scale, along its key dimensions based on more than 100 content publishers data spanning 27 months, and we propose new metrics to measure complexity of video management plane. Next, in order to enhance video control plane, we propose Oboe, a system that improves the dynamic range of Adaptive Bitrate(ABR) algorithms by automatically tuning ABR behaviors to the current network state of a client connection to improve QoE of a wide range of users. Through testbed experiments, we show Oboe significantly improves performance of several different ABR algorithms. Finally, given that performance of ABRs critically depends on throughput prediction accuracy, we propose a new throughput prediction approach, called Xatu, to address challenges in existing prediction methods used by ABRs. Xatu, a learning based throughput prediction framework, uses richer information (e.g., ISP or chunk size) without apriori partitioning data, and we show that Xatu reduces the prediction error by more than 23% relative to state-of-the-art throughput prediction.