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引用次数: 30
摘要
无线技术的进步导致了在外形因素、内存和计算能力方面具有高度可变性的设备的普及。为了保持高可靠性数据传输的连续连接,需要重新考虑传输层协议的传统设计。本文研究了在拥塞避免状态下,q -学习在TCP cwnd适应中的使用,其中经典的窗口交替被取代,从而允许协议立即响应先前看到的网络条件。此外,它还演示了内存如何在构建探索空间中发挥关键作用,并提出了通过函数近似减少这种开销的方法。通过全面的仿真研究证明了基于学习的方法优于TCP New Reno的性能,在评估的拓扑中,吞吐量和延迟分别提高了33.8%和12.1%。我们还展示了如何使用函数近似来显著降低基于学习的协议的内存需求,同时保持相同的吞吐量和延迟。
Learning-Based and Data-Driven TCP Design for Memory-Constrained IoT
Advances in wireless technology have resulted in pervasive deployment of devices of a high variability in form factors, memory and computational ability. The need for maintaining continuous connections that deliver data with high reliability necessitate re-thinking of conventional design of the transport layer protocol. This paper investigates the use of Q-learning in TCP cwnd adaptation during the congestion avoidance state, wherein the classical alternation of the window is replaced, thereby allowing the protocol to immediately respond to previously seen network conditions. Furthermore, it demonstrates how memory plays a critical role in building the exploration space, and proposes ways to reduce this overhead through function approximation. The superior performance of the learning-based approach over TCP New Reno is demonstrated through a comprehensive simulation study, revealing 33.8% and 12.1% improvement in throughput and delay, respectively, for the evaluated topologies. We also show how function approximation can be used to dramatically reduce the memory requirements of a learning-based protocol while maintaining the same throughput and delay.
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