Archive/A Verifiable Service-Oriented Industrial Cyber–Physical Systems Framework for Energy-Aware Autonomous Navigation Using a High-Fidelity Cyber–Physical Twin
A Verifiable Service-Oriented Industrial Cyber–Physical Systems Framework for Energy-Aware Autonomous Navigation Using a High-Fidelity Cyber–Physical Twin
Omar Abdelaty, Veera Ragavan Sampath Kumar, Darwin Gouwanda et al.
14 de julio de 2026
en

Abstract

Autonomous Cyber–Physical Systems (CPS) must jointly satisfy energy efficiency, accuracy, and real-time constraints, which are typically treated separately in existing methods. This paper proposes a verifiable service-oriented CPS framework for energy-aware autonomous navigation using a high-fidelity cyber–physical twin. The approach integrates physics-based Model Predictive Control (MPC) with explicit power modeling (P=F·v) and Dubins curve-based trajectory generation under the 5C (connection, conversion, cyber, cognition, and configuration) architecture using CARLA for synchronized cyber–physical interaction. The proposed method achieves 30.7% reduction in mean power consumption and 12.5% reduction in total energy usage while maintaining sub-centimeter tracking error (<0.05 m). Mission duration increases by 26.3% with only 7% computational overhead, confirming real-time feasibility. The framework provides a verifiable CPS methodology that unifies physics-based control, digital twin synchronization, and service-oriented design for energy-aware autonomous navigation.

IPC Classification

G06H01

Keywords

verifiableservice-orientedindustrialcyberphysicalsystemsframeworkenergy-awareautonomousnavigationhigh-fidelitytwinsoftwaremustjointlysatisfyenergyefficiencyaccuracyreal-timeconstraintswhichtypicallytreated
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