TY - GEN
T1 - Towards Federated, Autonomous and Cognitive Digital Twins with DARLING
AU - Souza, Diego
AU - Webber, Thais
AU - Wanner, Elizabeth
N1 - Copyright © 2025 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works.
PY - 2025/7/28
Y1 - 2025/7/28
N2 - With the widespread adoption of Digital Twins (DTs) in research and industry, this technology is emerging as a key decision-making tool in Industry 4.0. Advancements have expanded its applications across manufacturing, healthcare, aerospace, and robotics. Open and enterprise platforms now simplify deployment, enabling asset management, communication, IoT integration, data aggregation, visualisation, simulation, and real-time updates to physical counterparts. These improvements enhance efficiency, reduce costs, and support sustainability. Despite these benefits, existing DT platforms provide limited support for AI-driven reasoning in distributed environments. Simulation analysis and decision-making typically occur after data consolidation within a single component, constraining scalability and adaptability. Federated Learning partially addresses this by enabling decentralised model training but lacks continuous reasoning and dynamic what-if scenario evaluation. This paper introduces DARLING (Digital Twins with Autonomous Reconfiguration and Learning), a flexible DT framework embedding AIdriven reasoning for distributed and edge ecosystems. It extends conventional DTs through an Imaginary Twin, a conceptual entity enabling predictive simulations, autonomous goal-setting, and scenario planning without modifying the physical counterpart. The architecture supports distributed inference at the edge, allowing AI models to run locally on DT nodes, reducing reliance on centralised processing while improving scalability and privacy. Additionally, we position this work within the broader DT research perspective, drawing from existing studies on AI-driven reasoning, hierarchical DT representations, and varying levels of autonomy. Our aim is to address their gaps by embedding real-time AI-driven reasoning whilst supporting adaptive, goaloriented coordination across distributed DTs.
AB - With the widespread adoption of Digital Twins (DTs) in research and industry, this technology is emerging as a key decision-making tool in Industry 4.0. Advancements have expanded its applications across manufacturing, healthcare, aerospace, and robotics. Open and enterprise platforms now simplify deployment, enabling asset management, communication, IoT integration, data aggregation, visualisation, simulation, and real-time updates to physical counterparts. These improvements enhance efficiency, reduce costs, and support sustainability. Despite these benefits, existing DT platforms provide limited support for AI-driven reasoning in distributed environments. Simulation analysis and decision-making typically occur after data consolidation within a single component, constraining scalability and adaptability. Federated Learning partially addresses this by enabling decentralised model training but lacks continuous reasoning and dynamic what-if scenario evaluation. This paper introduces DARLING (Digital Twins with Autonomous Reconfiguration and Learning), a flexible DT framework embedding AIdriven reasoning for distributed and edge ecosystems. It extends conventional DTs through an Imaginary Twin, a conceptual entity enabling predictive simulations, autonomous goal-setting, and scenario planning without modifying the physical counterpart. The architecture supports distributed inference at the edge, allowing AI models to run locally on DT nodes, reducing reliance on centralised processing while improving scalability and privacy. Additionally, we position this work within the broader DT research perspective, drawing from existing studies on AI-driven reasoning, hierarchical DT representations, and varying levels of autonomy. Our aim is to address their gaps by embedding real-time AI-driven reasoning whilst supporting adaptive, goaloriented coordination across distributed DTs.
KW - Technological innovation
KW - Scalability
KW - Cognition
KW - Decision making
KW - System architecture
KW - Artificial intelligence
KW - Real-time systems
KW - Digital twins
KW - System of systems
KW - Simulation and modelling
UR - https://ieeexplore.ieee.org/document/11083783
UR - http://www.scopus.com/inward/record.url?scp=105022267669&partnerID=8YFLogxK
U2 - 10.1109/SoSE66311.2025.11083783
DO - 10.1109/SoSE66311.2025.11083783
M3 - Conference publication
SN - 9798331515362
T3 - Proceeding from Annual System of Systems Engineering Conference (SoSE)
BT - 2025 20th Annual System of Systems Engineering Conference (SoSE)
PB - IEEE
T2 - 2025 20th Annual System of Systems Engineering Conference (SoSE)
Y2 - 8 June 2025 through 11 June 2025
ER -