The Horcrux: Mechanistically Interpretable Task Decomposition for Detecting and Mitigating Reward Hacking in Embodied AI Systems
This addresses the problem of reward hacking in embodied AI systems, offering a novel approach for more effective detection and mitigation, though it appears incremental as it builds on existing decomposition and interpretability methods.
The paper tackles reward hacking in embodied AI agents by introducing Mechanistically Interpretable Task Decomposition (MITD), a hierarchical transformer architecture that reduces reward hacking frequency by 34% across four failure modes in experiments on 1,000 HH-RLHF samples.
Embodied AI agents exploit reward signal flaws through reward hacking, achieving high proxy scores while failing true objectives. We introduce Mechanistically Interpretable Task Decomposition (MITD), a hierarchical transformer architecture with Planner, Coordinator, and Executor modules that detects and mitigates reward hacking. MITD decomposes tasks into interpretable subtasks while generating diagnostic visualizations including Attention Waterfall Diagrams and Neural Pathway Flow Charts. Experiments on 1,000 HH-RLHF samples reveal that decomposition depths of 12 to 25 steps reduce reward hacking frequency by 34 percent across four failure modes. We present new paradigms showing that mechanistically grounded decomposition offers a more effective way to detect reward hacking than post-hoc behavioral monitoring.