Time Dilation and Contraction for Programmable Analog Devices with Jaunt

Proceedings of the Twenty-Third International Conference on Architectural Support for Programming Languages and Operating Systems Pub Date : 2018-03-19 DOI:10.1145/3173162.3173179

Sara Achour, M. Rinard

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引用次数: 5

Abstract

Programmable analog devices are a powerful new computing substrate that are especially appropriate for performing computationally intensive simulations of neuromorphic and cytomorphic models. Current state of the art techniques for configuring analog devices to simulate dynamical systems do not consider the current and voltage operating ranges of analog device components or the sampling limitations of the digital interface of the device. We present Jaunt, a new solver that scales the values that configure the analog device to ensure the resulting analog computation executes within the operating constraints of the device, preserves the recoverable dynamics of the original simulation, and executes slowly enough to observe these dynamics at the sampled digital outputs. Our results show that, on a set of benchmark biological simulations, 1) unscaled configurations produce incorrect simulations because they violate the operating ranges of the device and 2) Jaunt delivers scaled configurations that respect the operating ranges to produce correct simulations with observable dynamics.

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具有Jaunt的可编程模拟器件的时间膨胀和收缩

可编程模拟器件是一种功能强大的新型计算基板，特别适用于执行神经形态和细胞形态模型的计算密集型模拟。目前用于配置模拟设备以模拟动态系统的最先进技术没有考虑模拟设备组件的电流和电压工作范围或设备数字接口的采样限制。我们提出了Jaunt，一种新的求解器，它可以缩放配置模拟设备的值，以确保在设备的操作约束内执行所得到的模拟计算，保留原始模拟的可恢复动态，并且执行速度足够慢，可以在采样的数字输出中观察这些动态。我们的研究结果表明，在一组基准生物模拟中，1)未缩放的配置会产生不正确的模拟，因为它们违反了设备的工作范围;2)Jaunt提供的缩放配置尊重工作范围，从而产生具有可观察动态的正确模拟。

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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Proceedings of the Twenty-Third International Conference on Architectural Support for Programming Languages and Operating Systems

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