Population Stability: Regulating Size in the Presence of an Adversary

S. Goldwasser, R. Ostrovsky, Alessandra Scafuro, Adam Sealfon
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引用次数: 7

Abstract

We introduce a new coordination problem in distributed computing that we call the population stability problem. A system of agents each with limited memory and communication, as well as the ability to replicate and self-destruct, is subjected to attacks by a worst-case adversary that can at a bounded rate (1) delete agents chosen arbitrarily and (2) insert additional agents with arbitrary initial state into the system. The goal is perpetually to maintain a population whose size is within a constant factor of the target size N. The problem is inspired by the ability of complex biological systems composed of a multitude of memory-limited individual cells to maintain a stable population size in an adverse environment. Such biological mechanisms allow organisms to heal after trauma or to recover from excessive cell proliferation caused by inflammation, disease, or normal development. We present a population stability protocol in a communication model that is a synchronous variant of the population model of Angluin et al. In each round, pairs of agents selected at random meet and exchange messages, where at least a constant fraction of agents is matched in each round. Our protocol uses three-bit messages and ω(log^2 N) states per agent. We emphasize that our protocol can handle an adversary that can both insert and delete agents, a setting in which existing approximate counting techniques do not seem to apply. The protocol relies on a novel coloring strategy in which the population size is encoded in the variance of the distribution of colors. Individual agents can locally obtain a weak estimate of the population size by sampling from the distribution, and make individual decisions that robustly maintain a stable global population size.
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人口稳定性:在对手存在的情况下调节人口规模
我们在分布式计算中引入了一个新的协调问题,我们称之为种群稳定性问题。一个由有限的内存和通信,以及复制和自毁能力的代理组成的系统,会受到最坏情况对手的攻击,对手可以以有限的速度(1)删除任意选择的代理,(2)将具有任意初始状态的其他代理插入系统。目标是永远保持种群规模在目标规模n的恒定因子内。这个问题的灵感来自于由大量记忆有限的单个细胞组成的复杂生物系统在不利环境中保持稳定种群规模的能力。这种生物机制允许生物体在创伤后愈合,或从炎症、疾病或正常发育引起的过度细胞增殖中恢复。本文提出了一种通信模型中的种群稳定性协议,该协议是Angluin等人种群模型的同步变体。在每一轮中,随机选择的代理对相遇并交换消息,其中在每一轮中至少匹配恒定比例的代理。我们的协议使用3位消息和每个代理的ω(log^2 N)状态。我们强调,我们的协议可以处理既可以插入又可以删除代理的对手,在这种情况下,现有的近似计数技术似乎不适用。该协议依赖于一种新的着色策略,其中种群大小在颜色分布的方差中进行编码。个体智能体可以通过从分布中抽样获得局部总体规模的弱估计,并做出稳健地维持稳定的总体规模的个体决策。
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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