Learning and Communications Co-Design for Remote Inference Systems: Feature Length Selection and Transmission Scheduling

Md Kamran Chowdhury Shisher;Bo Ji;I-Hong Hou;Yin Sun
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引用次数: 3

Abstract

In this paper, we consider a remote inference system, where a neural network is used to infer a time-varying target (e.g., robot movement), based on features (e.g., video clips) that are progressively received from a sensing node (e.g., a camera). Each feature is a temporal sequence of sensory data. The inference error is determined by (i) the timeliness and (ii) the sequence length of the feature, where we use Age of Information (AoI) as a metric for timeliness. While a longer feature can typically provide better inference performance, it often requires more channel resources for sending the feature. To minimize the time-averaged inference error, we study a learning and communication co-design problem that jointly optimizes feature length selection and transmission scheduling. When there is a single sensor-predictor pair and a single channel, we develop low-complexity optimal co-designs for both the cases of time-invariant and time-variant feature length. When there are multiple sensor-predictor pairs and multiple channels, the co-design problem becomes a restless multi-arm multi-action bandit problem that is PSPACE-hard. For this setting, we design a low-complexity algorithm to solve the problem. Trace-driven evaluations demonstrate the potential of these co-designs to reduce inference error by up to 10000 times.
远程推理系统的学习和通信协同设计:特征长度选择和传输调度
在本文中,我们考虑了一个远程推理系统,其中神经网络用于根据从感测节点(例如相机)逐渐接收到的特征(例如视频剪辑)来推断时变目标(例如机器人运动)。每个特征都是感官数据的时间序列。推断误差由(i)特征的及时性和(ii)序列长度决定,其中我们使用信息年龄(AoI)作为及时性的度量。虽然较长的特征通常可以提供更好的推理性能,但发送该特征通常需要更多的信道资源。为了最小化时间平均推断误差,我们研究了一个学习和通信协同设计问题,该问题联合优化了特征长度选择和传输调度。当存在单个传感器预测器对和单个通道时,我们针对时不变和时变特征长度的情况开发了低复杂度的最优联合设计。当存在多个传感器预测器对和多个通道时,协同设计问题变成了PSPACE难以解决的多臂多动作土匪问题。对于这种设置,我们设计了一个低复杂度的算法来解决这个问题。跟踪驱动的评估证明了这些协同设计可以将推理误差减少10000倍的潜力。
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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CiteScore
8.20
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