分叉不确定性:通过共形风险控制利用序列模型进行可靠预测和模型预测控制

Matteo Zecchin;Sangwoo Park;Osvaldo Simeone
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引用次数: 0

摘要

在现实世界的许多问题中,预测被用来监测和控制网络物理系统,要求保证满足可靠性和安全性要求。然而,预测本身具有不确定性,在以复杂动态和分叉轨迹为特征的环境中,管理预测的不确定性会带来巨大挑战。在这项工作中,我们假设可以访问预先设计的隐式或显式概率序列模型,该模型可能是通过基于模型或无模型方法获得的。我们引入了概率时间序列-共形风险预测(PTS-CRC),这是一种新颖的事后校准程序,可对任何预先设计的概率预测器生成的预测结果进行操作,以产生可靠的误差条。与现有技术不同的是,PTS-CRC 基于从序列模型中采样的多个原型轨迹的集合生成预测集,支持对分叉不确定性的有效表示。此外,与现有技术不同的是,PTS-CRC 可以满足超出覆盖范围的可靠性定义。利用这一特性,我们设计了一个新颖的模型预测控制(MPC)框架,在控制策略的质量或安全性的一般平均约束条件下解决开环和闭环控制问题。我们通过研究无线网络背景下的一些使用案例,在实验中验证了 PTS-CRC 预测和控制的性能。在所有考虑的任务中,PTS-CRC 预测器都能提供信息量更大的预测集,以及回报率更高的安全控制策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Forking Uncertainties: Reliable Prediction and Model Predictive Control With Sequence Models via Conformal Risk Control
In many real-world problems, predictions are leveraged to monitor and control cyber-physical systems, demanding guarantees on the satisfaction of reliability and safety requirements. However, predictions are inherently uncertain, and managing prediction uncertainty presents significant challenges in environments characterized by complex dynamics and forking trajectories. In this work, we assume access to a pre-designed probabilistic implicit or explicit sequence model, which may have been obtained using model-based or model-free methods. We introduce probabilistic time series-conformal risk prediction (PTS-CRC), a novel post-hoc calibration procedure that operates on the predictions produced by any pre-designed probabilistic forecaster to yield reliable error bars. In contrast to existing art, PTS-CRC produces predictive sets based on an ensemble of multiple prototype trajectories sampled from the sequence model, supporting the efficient representation of forking uncertainties. Furthermore, unlike the state of the art, PTS-CRC can satisfy reliability definitions beyond coverage. This property is leveraged to devise a novel model predictive control (MPC) framework that addresses open-loop and closed-loop control problems under general average constraints on the quality or safety of the control policy. We experimentally validate the performance of PTS-CRC prediction and control by studying a number of use cases in the context of wireless networking. Across all the considered tasks, PTS-CRC predictors are shown to provide more informative predictive sets, as well as safe control policies with larger returns.
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