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[论文解读] Position: Certifiable State Integrity in Cyber-Physical Systems -- Why Modular Sovereignty Solves the Plasticity-Stability Paradox

Enzo Nicolás Spotorno, Antônio Augusto Medeiros Fröhlich|arXiv (Cornell University)|Jan 29, 2026

Adversarial Robustness in Machine Learning被引用 0

一句话总结

本文认为在 CPS 的可认证状态完整性需要一个模块化主权方法（HYDRA），通过冻结的 regime-specific 专家库和对不确定性的融合来解决可塑性-稳定性悖论，并实现跨生命周期转换的可验证安全性。

ABSTRACT

The machine learning community has achieved remarkable success with universal foundation models for time-series and physical dynamics, largely overcoming earlier approximation barriers in smooth or slowly varying regimes through scale and specialized architectures. However, deploying these monolithic models in safety-critical Cyber-Physical Systems (CPS), governed by non-stationary lifecycle dynamics and strict reliability requirements, reveals persistent challenges. Recent evidence shows that fine-tuning time-series foundation models induces catastrophic forgetting, degrading performance on prior regimes. Standard models continue to exhibit residual spectral bias, smoothing high-frequency discontinuities characteristic of incipient faults, while their opacity hinders formal verification and traceability demanded by safety standards (e.g., ISO 26262, IEC 61508). This position paper argues that the plasticity-stability paradox cannot be fully resolved by global parameter updates (whether via offline fine-tuning or online adaptation). Instead, we advocate a Modular Sovereignty paradigm: a library of compact, frozen regime-specific specialists combined via uncertainty-aware blending, which we term "HYDRA" (Hierarchical uncertaintY-aware Dynamics for Rapidly-Adapting systems). This paradigm ensures regime-conditional validity, rigorous disentanglement of aleatoric and epistemic uncertainties, and modular auditability, offering a certifiable path for robust state integrity across the CPS lifecycle.

研究动机与目标

Identify theoretical and practical barriers to deploying universal foundation models in safety-critical CPS.
Propose Modular Sovereignty (HYDRA) as a paradigm to decouple library constitution from runtime arbitration and resolve forgetting.
Outline architectural principles, advantages, and open challenges toward lifecycle-certifiable physical learning.
Enable regime-conditional validity, disentangled uncertainties, and modular auditability for safety-standard certification.

提出的方法

Define State Integrity as continuous, physically interpretable linkage between physical and digital representations across lifecycle.
Introduce HYDRA: a library of frozen, regime-specific specialists (S_k) combined by an uncertainty-aware Governor (B) and guarded by an Integrity Monitor (I).
Formalize output as a convex combination: ŷ_t = sum_k π_k^{(t)} S_k(x_t) with π in the simplex, ensuring the state remains in the convex hull of valid local manifolds.
Phase I: Offline constitution of L with Type-I (Physics-Derived) and Type-II (Data-Derived) specialists and a Constitutional Greedy Accretion vetting process.
Phase II: Online calibration where the Governor infers low-dimensional mixing coefficients π_t via residuals and uncertainty metrics, enabling regime-conditional conformal prediction.
Tie-ins to LPV theory via polytopic generalization and RPI Zonotopes for safety sets; employ Dirichlet priors (α) to manage sparsity vs. continuity in regime switching.

Figure 1 : Simplex Integration. The Governor isolates the AI (QM) from the Safety Core (ASIL D). Specialists provide estimation; the Governor and fallback form the high-assurance safety channel. Figure crafted with the help of a GenAI Image Model.

实验结果

研究问题

RQ1How can we maintain regime-conditional validity and certifiability in non-stationary CPS without catastrophic forgetting?
RQ2Can a library of frozen regime-specific specialists combined by an uncertainty-aware governor provide auditable safety guarantees under ISO/IEC safety standards?
RQ3How does residual-based arbitration enable reliable detection of regime shifts, faults, and aging in safety-critical dynamics?
RQ4What architectural and mathematical tools (e.g., LPV, polytopic theory, zonotopes) support modular certification and tractable verification?

主要发现

Monolithic foundation models exhibit plasticity-stability and certifiability challenges in non-stationary CPS, including forgetting and opaque verification.
HYDRA decouples library constitution from runtime arbitration, enabling fault-tolerant, certifiable adaptation via a small set of frozen specialists.
Uncertainty-aware blending (Governor) uses runtime residuals to detect regime shifts and manage switching with controllable ambiguity, leveraging LPV-like guarantees.
Convex combination of specialists preserves state within the convex hull of valid manifolds, supporting modular verification and safety envelopes (RPI Zonotopes).
The Integrity Triangle (Governance Health, Uncertainty, and Transparency) provides a structured runtime assurance framework with simple-safety fallbacks (Simplex Architecture).
Phase-wise library construction and vetting minimize forgetting, enable independent certification of components, and improve availability over monolithic wrappers.

Figure 2 : The Architecture of Sovereignty. Illustrated via the Vehicle Dynamics case study. The framework separates the offline Constitution (Library of Specialists) from the online Governance (in this example, implementing a Bayesian method for uncertainty-quantification, such as variational infer

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