求解MAXCUT的随机神经形态电路

Bradley H. Theilman, Yipu Wang, Ojas D. Parekh, William M. Severa, J. D. Smith, J. Aimone
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引用次数: 4

摘要

寻找图的最大截点(MAXCUT)是一个经典的优化问题,它激发了并行算法的发展。虽然MAXCUT的近似算法提供了有吸引力的理论保证,并展示了令人信服的经验性能,但这种近似方法可以将主要的计算成本转移到随机抽样操作上。神经形态计算(Neuromorphic computing)提供了一种可能的解决方案,它利用神经系统的组织原理来激发新的并行计算架构。自然大脑的一个普遍特征是随机性:生物神经网络的单个元素具有内在的随机性,作为一种资源,使其具有独特的计算能力。通过设计类似于自然大脑的随机性的电路和算法,我们假设微电子设备中固有的随机性可以转化为神经形态架构的一个有价值的组成部分,从而实现更高效的计算。在这里,我们提出了神经形态电路,将随机设备池的随机行为转化为有用的相关性,从而驱动MAXCUT的随机解。我们表明,与软件求解器相比,这些电路表现良好,并认为这种神经形态硬件实现为扩展优势提供了一条途径。这项工作证明了将神经形态原理与内在随机性结合起来作为新计算架构的计算资源的实用性。
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Stochastic Neuromorphic Circuits for Solving MAXCUT
Finding the maximum cut of a graph (MAXCUT) is a classic optimization problem that has motivated parallel algorithm development. While approximate algorithms to MAXCUT offer attractive theoretical guarantees and demonstrate compelling empirical performance, such approximation approaches can shift the dominant computational cost to the stochastic sampling operations. Neuromorphic computing, which uses the organizing principles of the nervous system to inspire new parallel computing architectures, offers a possible solution. One ubiquitous feature of natural brains is stochasticity: the individual elements of biological neural networks possess an intrinsic randomness that serves as a resource enabling their unique computational capacities. By designing circuits and algorithms that make use of randomness similarly to natural brains, we hypothesize that the intrinsic randomness in microelectronics devices could be turned into a valuable component of a neuromorphic architecture enabling more efficient computations. Here, we present neuromorphic circuits that transform the stochastic behavior of a pool of random devices into useful correlations that drive stochastic solutions to MAXCUT. We show that these circuits perform favorably in comparison to software solvers and argue that this neuromorphic hardware implementation provides a path for scaling advantages. This work demonstrates the utility of combining neuromorphic principles with intrinsic randomness as a computational resource for new computational architectures.
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