Delays and the Capacity of Continuous-Time Channels

S. Khanna, M. Sudan
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引用次数: 1

Abstract

Any physical channel of communication offers two potential reasons why its capacity (the number of bits it can transmit in a unit of time) might be unbounded: (1) (Uncountably) infinitely many choices of signal strength at any given instant of time, and (2) (Uncountably) infinitely many instances of time at which signals may be sent. However channel noise cancels out the potential unboundedness of the first aspect, leaving typical channels with only a finite capacity per instant of time. The latter source of infinity seems less extensively studied. A potential source of unreliability that might restrict the capacity also from the second aspect is ``delay'': Signals transmitted by the sender at a given point of time may not be received with a predictable delay at the receiving end. In this work we examine this source of uncertainty by considering a simple discrete model of delay errors. In our model the communicating parties get to subdivide time as microscopically finely as they wish, but still have to cope with communication delays that are macroscopic and variable. The continuous process becomes the limit of our process as the time subdivision becomes infinitesimal. We taxonomize this class of communication channels based on whether the delays and noise are stochastic or adversarial, and based on how much information each aspect has about the other when introducing its errors. We analyze the limits of such channels and reach somewhat surprising conclusions: The capacity of a physical channel is finitely bounded only if at least one of the two sources of error (signal noise or delay noise) is adversarial. In particular the capacity is finitely bounded only if the delay is adversarial, or the noise is adversarial and acts with knowledge of the stochastic delay. If both error sources are stochastic, or if the noise is adversarial and independent of the stochastic delay, then the capacity of the associated physical channel is infinite!
延迟和连续时间信道的容量
任何物理通信信道的容量(单位时间内可以传输的比特数)可能是无界的,这有两个潜在的原因:(1)在任何给定的时刻,(不可数)有无限多的信号强度选择,(2)(不可数)有无限多的信号可以发送。然而,信道噪声抵消了第一个方面的潜在无界性,使典型的信道每瞬间只有有限的容量。后一种无限来源似乎没有得到广泛的研究。可能从第二个方面限制容量的潜在不可靠性来源是“延迟”:发送者在给定时间点发送的信号在接收端可能不会以可预测的延迟接收。在这项工作中,我们通过考虑一个简单的离散延迟误差模型来检查这种不确定性的来源。在我们的模型中,通信各方可以按照自己的意愿在微观上细分时间,但仍然需要处理宏观和可变的通信延迟。随着时间的细分变得无限小,连续的过程成为我们过程的极限。我们根据延迟和噪声是随机的还是对抗性的,以及在引入其误差时每个方面对另一个方面的信息的多少来对这类通信信道进行分类。我们分析了这些信道的极限,并得出了一些令人惊讶的结论:只有当两个误差源(信号噪声或延迟噪声)中至少有一个是对抗性的,物理信道的容量才有有限界限。特别是,只有当延迟是对抗性的,或者噪声是对抗性的,并且随随机延迟的知识而起作用时,容量才有有限界。如果两个误差源都是随机的,或者如果噪声是对抗的并且独立于随机延迟,那么相关的物理信道的容量是无限的!
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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