Responding to Distribution Shift: When to Adapt, Freeze, or Rebuild World Models

When a world model detects distribution shift, what should the agent do? Current approaches offer a binary choice — continue or retrain — ignoring the spectrum of adaptive responses available. We present a unified framework combining the Homeostatic Hamiltonian Agent (HHA) with the Model Invalidity Test (MIT). HHA introduces a stress-energy functional that governs adaptation intensity through a dynamic gain parameter gamma, enabling three distinct response modes: freeze (preserve the current model), adapt (incremental update), or rebuild (full reconstruction). MIT provides the conjunctive decision rule that triggers these responses, testing both prediction accuracy and physics-model alignment. Across six benchmarks covering panic-freeze scenarios, noise specificity, structural recall, response taxonomy, ablation studies, and SOTA comparison, the HHA+MIT system demonstrates appropriate response selection with measurable separation between response modes. The framework provides a principled alternative to threshold-based switching by grounding adaptation decisions in physical quantities. This archive contains the full LaTeX source, compiled PDF (20 pages), and all benchmark scripts with reproducibility instructions.