数字双胞胎的因果语义交流:可推广的模仿学习方法

Christo Kurisummoottil Thomas;Walid Saad;Yong Xiao
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引用次数: 0

摘要

数字孪生(DT)利用物理世界的虚拟表示,以及通信(如 6G)、计算(如边缘计算)和人工智能(AI)技术,实现了许多互联智能服务。为了处理基于数字双胞胎(DTs)的大量网络数据,无线系统可以利用语义通信(SC)范例,通过因果推理等人工智能技术,在严格的通信限制条件下促进知情决策。本文为基于 DT 的无线系统提出了一种称为因果语义通信(CSC)的新框架。CSC 系统被视为一个模仿学习(IL)问题,即发射器利用 DT 获取最优网络控制策略,并通过带宽受限的无线信道利用 SC 向接收器传授如何改进其知识以执行最优控制操作。利用深度端到端因果推理框架中的新方法提取发射机数据中的因果结构,从而创建因果不变的语义表征,这反过来又有助于将学习到的系统知识泛化到新的和未见过的情况中。接收器上的 CSC 解码器旨在提取和估计语义信息,同时确保高语义可靠性。接收器控制策略、语义解码器和因果推理在变分推理框架内被表述为一个双层优化问题。该问题的解决采用了一种称为网络状态模型的新概念,其灵感来源于生成式人工智能中的世界模型,它忠实地反映了导致数据生成的环境动态。此外,所提出的框架还包括对性能差距的分析表征,这种性能差距是由接收器利用传输的语义信息构建物理环境模型而学习到的次优策略所导致的。CSC 系统利用两个概念,即意识理论中的综合信息论原理和拓扑学中的抽象细胞复合体概念,来精确表达因果状态及其关系所传递的信息内容。通过这一分析,提出了语义信息、语义可靠性、失真和相似性度量的新表述,这些表述超越了香农的不确定性概念。仿真结果表明,所提出的 CSC 系统优于传统无线系统和最先进的 SC 系统,它以更少的比特实现了更高的语义可靠性,并且由于采用了生成式人工智能架构,随着时间的推移可以实现更好的控制策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Causal Semantic Communication for Digital Twins: A Generalizable Imitation Learning Approach
A digital twin (DT) leverages a virtual representation of the physical world, along with communication (e.g., 6G), computing (e.g., edge computing), and artificial intelligence (AI) technologies to enable many connected intelligence services. In order to handle the large amounts of network data based on digital twins (DTs), wireless systems can exploit the paradigm of semantic communication (SC) for facilitating informed decision-making under strict communication constraints by utilizing AI techniques such as causal reasoning. In this paper, a novel framework called causal semantic communication (CSC) is proposed for DT-based wireless systems. The CSC system is posed as an imitation learning (IL) problem, where the transmitter, with access to optimal network control policies using a DT, teaches the receiver using SC over a bandwidth-limited wireless channel how to improve its knowledge to perform optimal control actions. The causal structure in the transmitter’s data is extracted using novel approaches from the framework of deep end-to-end causal inference, thereby enabling the creation of a semantic representation that is causally invariant, which in turn helps generalize the learned knowledge of the system to new and unseen situations. The CSC decoder at the receiver is designed to extract and estimate semantic information while ensuring high semantic reliability. The receiver control policies, semantic decoder, and causal inference are formulated as a bi-level optimization problem within a variational inference framework. This problem is solved using a novel concept called network state models, inspired from world models in generative AI, that faithfully represents the environment dynamics leading to data generation. Furthermore, the proposed framework includes an analytical characterization of the performance gap that results from employing a suboptimal policy learned by the receiver that uses the transmitted semantic information to construct a model of the physical environment. The CSC system utilizes two concepts, namely the integrated information theory principle in the theory of consciousness and the abstract cell complex concept in topology, to precisely express the information content conveyed by the causal states and their relationships. Through this analysis, novel formulations of semantic information, semantic reliability, distortion, and similarity metrics are proposed, which extend beyond Shannon’s concept of uncertainty. Simulation results demonstrate that the proposed CSC system outperforms conventional wireless and state-of-the-art SC systems by achieving better semantic reliability with reduced bits and enabling better control policies over time thanks to the generative AI architecture.
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