Neuro-symbolic Explainable Artificial Intelligence Twin for Zero-touch
IoE in Wireless Network
- URL: http://arxiv.org/abs/2210.06649v1
- Date: Thu, 13 Oct 2022 01:08:06 GMT
- Title: Neuro-symbolic Explainable Artificial Intelligence Twin for Zero-touch
IoE in Wireless Network
- Authors: Md. Shirajum Munir, Ki Tae Kim, Apurba Adhikary, Walid Saad, Sachin
Shetty, Seong-Bae Park, and Choong Seon Hong
- Abstract summary: Explainable artificial intelligence (XAI) twin systems will be a fundamental enabler of zero-touch network and service management (ZSM)
A reliable XAI twin system for ZSM requires two composites: an extreme analytical ability for discretizing the physical behavior of the Internet of Everything (IoE) and rigorous methods for characterizing the reasoning of such behavior.
A novel neuro-symbolic explainable artificial intelligence twin framework is proposed to enable trustworthy ZSM for a wireless IoE.
- Score: 61.90504487270785
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Explainable artificial intelligence (XAI) twin systems will be a fundamental
enabler of zero-touch network and service management (ZSM) for sixth-generation
(6G) wireless networks. A reliable XAI twin system for ZSM requires two
composites: an extreme analytical ability for discretizing the physical
behavior of the Internet of Everything (IoE) and rigorous methods for
characterizing the reasoning of such behavior. In this paper, a novel
neuro-symbolic explainable artificial intelligence twin framework is proposed
to enable trustworthy ZSM for a wireless IoE. The physical space of the XAI
twin executes a neural-network-driven multivariate regression to capture the
time-dependent wireless IoE environment while determining unconscious decisions
of IoE service aggregation. Subsequently, the virtual space of the XAI twin
constructs a directed acyclic graph (DAG)-based Bayesian network that can infer
a symbolic reasoning score over unconscious decisions through a first-order
probabilistic language model. Furthermore, a Bayesian multi-arm bandits-based
learning problem is proposed for reducing the gap between the expected
explained score and the current obtained score of the proposed neuro-symbolic
XAI twin. To address the challenges of extensible, modular, and stateless
management functions in ZSM, the proposed neuro-symbolic XAI twin framework
consists of two learning systems: 1) an implicit learner that acts as an
unconscious learner in physical space, and 2) an explicit leaner that can
exploit symbolic reasoning based on implicit learner decisions and prior
evidence. Experimental results show that the proposed neuro-symbolic XAI twin
can achieve around 96.26% accuracy while guaranteeing from 18% to 44% more
trust score in terms of reasoning and closed-loop automation.
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