MapFormer: Self-Supervised Learning of Cognitive Maps with Input-Dependent Positional Embeddings
Abstract
A cognitive map is an internal model which encodes the abstract relationships among entities in the world, giving humans and animals the flexibility to adapt to new situations, with a strong out-of-distribution (OOD) generalization that current AI systems still do not possess. To bridge this gap, we introduce MapFormers, new Transformer-based architectures, which can learn cognitive maps from observational data and perform path-integration without supervision. Cognitive maps are learned in the model by disentangling structural relationships in the inputs from their specific content, a property that can be achieved by updating position encodings with input-dependent matrices, built as exponentials of learned combinations of Lie-algebra generators. We developed two variants of MapFormers that unify absolute and relative positional encoding to model episodic (EM) and working memory (WM), respectively. We tested MapFormers on several formal tasks targeting distinct cognitive capacities, including gating, 2D navigation and nested hierarchies (Dyck Languages). Our results demonstrate that MapFormers significantly outperform current AI architectures, achieving near-perfect OOD generalization where standard models fail. Furthermore, we show that MapFormers are scalable; evaluations on naturalistic data yield perplexity improvements over baselines, suggesting that these principles extend to large-scale, real-world domains. These results are obtained through efficient parallel computation on commutative maps, though our models can also learn non-commutative cognitive maps via sequential path-integration. Overall, these results suggest that input-dependent matrices provide a critical structural bias, by disentangling abstract relations from content in order to drive robust OOD generalization.
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