Recent papers on Scalability in Complex Systems

Sorted by publication year (newest first) via OpenAlex. List regenerates every 24h.

1. When Fragmentation Impedes Decisions : Supporting knowledge sharing for decision-making in large scale complex system design

   2026 · Lenssen, Jan

   2026

2. Scale-Aware Adversarial Analysis: A Diagnostic for Generative AI in Multiscale Complex Systems

   2026 · arXiv (Cornell University) · Zhao, Mengke, Li, Guang-Xing, Xu, Duo et al.

   2026

3. Post-Complex Systems I: Cross-Scale Verification from Percolation Phase Transitions to Cognitive Architectures

   2026 · Zenodo (CERN European Organization for Nuclear Research) · zhou, changzheng, zhou, ziqing

   2026

4. Post-Complex Systems F; Multi-scale Coarse-graining and Renormalization Group- From Micro-Individuals to Macro-Organizations as Generative Dynamics

   2026 · Zenodo (CERN European Organization for Nuclear Research) · zhou, changzheng, zhou, ziqing

   2026

5. Ramsey Number Reconstruction for AI Emergence and Scaling Laws: A Unified Perspective of Signal Filtering and Complex System

   2026 · Zenodo (CERN European Organization for Nuclear Research) · Chen, Yongsheng, Gao, Yunduan

   2026

6. The Dynamic Stability Signature: A Cross-Scale Framework for Asymmetrical Balance in Complex Systems

   2026 · Zenodo (CERN European Organization for Nuclear Research) · OKUMUS, IBRAHIM

   2026

7. Unified Cyclical Dynamics Framework (ABCD–BDG Integration Model) A Multi-Scale Ontological and Energetic Approach to Complex System Evolution

   2026 · Zenodo (CERN European Organization for Nuclear Research) · Boko, Irfan

   2026

8. Evaluating Civilization-Scale Cross-Level Complex Systems Theories: A Methodological Framework Subtitle: Avoiding Systematic Underestimation - Methodological Lessons and Universal Standards from the Natural Human Philosophy Peer Review Case Study

   2026 · Zenodo (CERN European Organization for Nuclear Research) · Panel, International Interdisciplinary Methodological Review

   2026

9. Global Legal Architecture for Active Sensing Signal Fusion: Integrating Radar-Lidar-Sonar Cross-Modal Processing, Transnational Navigation Sovereignty, and Algorithmic Liability Standards into Cross-Border Autonomous Operations Frameworks Prepared and Authored by Dr. Mohamed Kamal Arafa El-Rakhawi International Law & Emerging Technologies Governance Specialist Abstract The global deployment of active sensing architectures, encompassing radar, lidar, sonar, and multi-spectral emitter systems, has fundamentally transformed autonomous navigation, cross-border surveillance, maritime traffic management, and aerial corridor coordination. Despite their engineering maturity in cross-modal signal fusion, interference mitigation, and real-time spatial tracking, these systems operate within a fragmented transnational regulatory landscape where spectrum allocation statutes, navigation sovereignty doctrines, and algorithmic liability frameworks lack interoperable compliance standards. While technical implementations achieve high precision in target detection, environmental mapping, and dynamic obstacle avoidance, they provide no legally calibrated translation mechanism to satisfy international spectrum usage mandates, cross-jurisdictional navigation clearance thresholds, or harmonized operational liability standards. This study introduces, for the first time globally, a unified legal-technical architecture that transforms active sensing fusion metrics into internationally harmonized navigation and spectrum governance standards. The framework operationalizes two novel constructs: the Active Sensing Compliance Matrix (ASCM), which maps cross-modal fusion stability, electromagnetic and acoustic interference rejection scores, and localization precision to transnational navigation safety and spectrum sovereignty tiers, and the Cross-Border Sensor Liability Protocol (CBSLP), which dynamically calibrates collision avoidance decision boundaries, sensor fault attribution weights, and spectrum usage compliance to legally recognized liability and operational adequacy thresholds. By integrating multi-sensor signal fusion, cryptographic telemetry anchoring, and international navigation and spectrum harmonization doctrine, this research establishes the first globally scalable standard for legally enforceable active sensing governance. Through comparative legal analysis and a counterfactual simulation of a transnational maritime-aviation corridor incident involving multi-sensor autonomous navigation, we demonstrate that ASCM alignment exceeding zero point eight five combined with CBSLP verification satisfies spectrum compliance, navigation sovereignty, safety certification, and cross-border enforcement requirements across European, North American, Asian, Middle Eastern, and hybrid jurisdictions. This framework bridges the historical divide between active sensing signal processing engineering and international navigation and spectrum law, positioning cross-modal emitter systems as legally verifiable, globally interoperable, and sovereign-compliant operational paradigms. Keywords Active Sensing Signal Fusion · Radar-Lidar-Sonar Integration · Transnational Navigation Sovereignty · Cross-Border Sensor Liability · Spectrum Compliance · Global Autonomous Operations Law · Multi-Sensor Fusion Governance · Algorithmic Navigation Standards · Electromagnetic Interference Mitigation 1. Introduction The exponential proliferation of active sensing systems utilizing radio frequency, optical, and acoustic emitters has redefined the operational architecture of global autonomous navigation, border surveillance, maritime traffic control, and aerial corridor management. Modern active sensing platforms integrate radar Doppler processing, lidar point cloud mapping, sonar bathymetric scanning, and multi-static emitter arrays to achieve continuous environmental perception, target tracking, and dynamic path optimization across complex transnational operational zones. Despite their transformative impact on safety enhancement, traffic efficiency, and cross-border mobility, these active sensing signal processing systems operate within a legally fragmented international environment where national spectrum allocation statutes, navigation sovereignty frameworks, and algorithmic liability doctrines impose conflicting compliance requirements. Instruments such as the International Telecommunication Union Radio Regulations, United Nations Convention on the Law of the Sea, International Civil Aviation Organization Annexes, European Union Radio Equipment Directive and Artificial Intelligence Act, and regional spectrum management frameworks across Asia, Africa, and the Global South establish stringent frequency licensing, navigation right-of-way, and operational safety obligations, yet provide no standardized methodology for evaluating cross-modal sensor fusion metrics against transnational legal thresholds. This regulatory misalignment creates systemic friction that

   2026 · Zenodo (CERN European Organization for Nuclear Research) · elrakhawi, mohamed kamal arafa

   2026

10. Scale Geometry of Complex Systems: Repository and Manuscript Artifacts

    2026 · Zenodo (CERN European Organization for Nuclear Research) · Sotiriadi, Nazar

    2026

11. Scale Geometry of Complex Systems: Formalism and Empirical Verification of Local Λb–Πb Closure in Atmospheric Data

    2026 · Zenodo (CERN European Organization for Nuclear Research) · Sotiriadi, Nazar

    2026

12. Turbulence-like 5/3 spectral scaling in contextual representations of language as a complex system

    2026 · ArXiv.org · Yang, Zhongxin, Bao, Chun, Bin, Yuanwei et al.

    2026

13. Bridging Domains in Large-scale Complex and Critical Systems, 2026 Ed.

    2026 · Zenodo (CERN European Organization for Nuclear Research) · Robinson, Charles J., Mackay, Adam, Fratu, Octavian et al.

    2026

14. Parametric Sign Inversion and Topological Flipping in Driven Complex Systems: A Mathematical Analogy Across Scales

    2026 · Zenodo (CERN European Organization for Nuclear Research) · Attaianese, Claudia

    2026

15. Multi-Scale Constraint Systems: Admissibility Across Hierarchical Levels in Complex Systems

    2026 · PhilPapers (PhilPapers Foundation) · Paton, Andrew John

    2026

16. Linking δ¹³CDIC and microbial respiration to calcium carbonate dissolution in a complex groundwater system: evidence from a large-scale field study

    2026 · Preziosi, Elisabetta, Amalfitano, Stefano, Casentini, Barbara et al.

    2026