Cognitive Digital Twin Framework: Modeling and Real-Time Decision Making

Yangyang Zhang; Mengtong Li; Xinyu Wang; Zhihao Lin; Xiang Luo; Ernie Tian; Ning Lyu; Zhiguo Tao; Xiaotong Ding; Chuanzhen Wang

Cognitive Digital Twin Framework: Modeling and Real-Time Decision Making

Yangyang Zhang, Mengtong Li, Xinyu Wang, Zhihao Lin, Xiang Luo, Ernie Tian, Ning Lyu, Zhiguo Tao, Xiaotong Ding, Chuanzhen Wang

Published: 02 Mar 2026, Last Modified: 11 Mar 2026ICLR 2026 Workshop World ModelsEveryoneRevisionsBibTeXCC BY 4.0

Keywords: Multi-Agent Systems; Agentic Decision-Making; Consensus Formation; Role-Specialized Agents; Reinforcement Learning for Agent Coordination; Evidence-Grounded Reasoning; High-Stakes Real-World Applications

TL;DR: We propose a role-specialized multi-agent system that uses reinforcement learning to drive consensus formation and evidence-grounded decision-making in high-stakes real-world settings.

Abstract: Digital twins can support modeling and optimization of complex physical systems. However, many existing frameworks remain passive and cannot learn or decide online under non-stationary conditions. We present a Cognitive Digital Twin (CDT) framework that couples real-time perception, reasoning, and adaptation. CDT builds on deep reinforcement learning, temporal knowledge graphs, and federated learning. It makes three design choices. First, it uses a quality-aware multi-modal fusion module to weight heterogeneous inputs. Second, it uses a hierarchical reasoning engine with reactive (0–10 ms), deliberative (10 ms–1 s), and reflective (asynchronous) layers. Third, it uses a privacy-preserving federated protocol to coordinate multiple twins. Experiments on three industrial IoT testbeds show that CDT reduces prediction error by 25.5%, reduces average response latency by 30.0%, and improves decision quality by 25.7% over the best baseline. Ablations show that each module contributes, and the full system gives the best overall performance.

Submission Number: 90

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