FHVAC: Feature-Level Hybrid Video Adaptive Configuration for Machine-Centric Live Streaming

IF 5.6 2区计算机科学 Q1 COMPUTER SCIENCE, THEORY & METHODS IEEE Transactions on Parallel and Distributed Systems Pub Date : 2024-03-04 DOI:10.1109/TPDS.2024.3372046

Yuanhong Zhang;Weizhan Zhang;Haipeng Du;Caixia Yan;Li Liu;Qinghua Zheng

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Abstract

With the widespread deployment of edge computing, the focus has shifted to machine-centric live video streaming, where endpoint-collected videos are transmitted over networks to edge servers for analysis. Unlike maximizing user's Quality of Experience (QoE), machine-centric video streaming optimizes the machine's Quality of Inference (QoI) by balancing the inference accuracy, inference delay, and transmission latency with video adaptive configuration. Traditional heuristic configuration adaption methods are reliable but unable to respond to erratic network fluctuations. Reinforcement learning (RL) based algorithms exhibit superior flexibility but suffer from exploration mechanisms, resulting in long-tail effects on upload latency. In this paper, we propose FHVAC, which dynamically selects video encoding parameters for live streaming by coherently fusing rule-based and RL-based agent at the feature level. We initially develop a robust rule-based approach for ensuring the low latency in transmission, and employ imitation learning to convert it into a neural network equivalently. Subsequently, we design a novel module to combine the two approaches and assess various fusion mechanisms. Our evaluation of FHVAC across two vision tasks (pose estimation and semantic segmentation) in two scenarios (trace-driven simulation and testbed-based experiment) shows that FHVAC enhances the average QoI, and reduces 10.61%-65.27% latency tail performance compared to prior work.

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FHVAC：面向以机器为中心的实时流媒体的特征级混合视频自适应配置

随着边缘计算的广泛部署，重点已转移到以机器为中心的实时视频流，即通过网络将终端收集的视频传输到边缘服务器进行分析。与最大限度提高用户体验质量（QoE）不同，以机器为中心的视频流通过视频自适应配置平衡推理精度、推理延迟和传输延迟来优化机器的推理质量（QoI）。传统的启发式配置自适应方法虽然可靠，但无法应对不稳定的网络波动。基于强化学习（RL）的算法具有出色的灵活性，但受到探索机制的影响，导致上传延迟产生长尾效应。在本文中，我们提出了 FHVAC，它通过在特征级别上协调融合基于规则和基于 RL 的代理，动态选择直播流媒体的视频编码参数。我们首先开发了一种基于规则的稳健方法，以确保低延迟传输，并利用模仿学习将其等效转换为神经网络。随后，我们设计了一个新模块，将两种方法结合起来，并评估了各种融合机制。我们在两种场景（基于轨迹的模拟和基于试验台的实验）中对 FHVAC 在两个视觉任务（姿势估计和语义分割）中的应用进行了评估，结果表明，与之前的研究相比，FHVAC 提高了平均 QoI，并降低了 10.61%-65.27% 的延迟尾随性能。

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来源期刊

IEEE Transactions on Parallel and Distributed Systems 工程技术-工程：电子与电气

CiteScore

11.00

自引率

9.40%

发文量

281

审稿时长

5.6 months

期刊介绍： IEEE Transactions on Parallel and Distributed Systems (TPDS) is published monthly. It publishes a range of papers, comments on previously published papers, and survey articles that deal with the parallel and distributed systems research areas of current importance to our readers. Particular areas of interest include, but are not limited to: a) Parallel and distributed algorithms, focusing on topics such as: models of computation; numerical, combinatorial, and data-intensive parallel algorithms, scalability of algorithms and data structures for parallel and distributed systems, communication and synchronization protocols, network algorithms, scheduling, and load balancing. b) Applications of parallel and distributed computing, including computational and data-enabled science and engineering, big data applications, parallel crowd sourcing, large-scale social network analysis, management of big data, cloud and grid computing, scientific and biomedical applications, mobile computing, and cyber-physical systems. c) Parallel and distributed architectures, including architectures for instruction-level and thread-level parallelism; design, analysis, implementation, fault resilience and performance measurements of multiple-processor systems; multicore processors, heterogeneous many-core systems; petascale and exascale systems designs; novel big data architectures; special purpose architectures, including graphics processors, signal processors, network processors, media accelerators, and other special purpose processors and accelerators; impact of technology on architecture; network and interconnect architectures; parallel I/O and storage systems; architecture of the memory hierarchy; power-efficient and green computing architectures; dependable architectures; and performance modeling and evaluation. d) Parallel and distributed software, including parallel and multicore programming languages and compilers, runtime systems, operating systems, Internet computing and web services, resource management including green computing, middleware for grids, clouds, and data centers, libraries, performance modeling and evaluation, parallel programming paradigms, and programming environments and tools.