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Main Author: Kermiche, Noureddine
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.16585
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author Kermiche, Noureddine
author_facet Kermiche, Noureddine
contents We present the Global Neural World Model (GNWM), a self-stabilizing framework that achieves topological quantization through balanced continuous entropy constraints. Operating as a continuous, action-conditioned Joint-Embedding Predictive Architecture (JEPA), the GNWM maps environments onto a discrete 2D grid, enforcing translational equivariance without pixel-level reconstruction. Our results show this architecture prevents manifold drift during autoregressive rollouts by using grid ``snapping'' as a native error-correction mechanism. Furthermore, by training via maximum entropy exploration (random walks), the model learns generalized transition dynamics rather than memorizing specific expert trajectories. We validate the GNWM across passive observation, active agent control, and abstract sequence regimes, demonstrating its capacity to act not just as a spatial physics simulator, but as a causal discovery model capable of organizing continuous, predictable concepts into structured topological maps.
format Preprint
id arxiv_https___arxiv_org_abs_2604_16585
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The Global Neural World Model: Spatially Grounded Discrete Topologies for Action-Conditioned Planning
Kermiche, Noureddine
Machine Learning
Artificial Intelligence
We present the Global Neural World Model (GNWM), a self-stabilizing framework that achieves topological quantization through balanced continuous entropy constraints. Operating as a continuous, action-conditioned Joint-Embedding Predictive Architecture (JEPA), the GNWM maps environments onto a discrete 2D grid, enforcing translational equivariance without pixel-level reconstruction. Our results show this architecture prevents manifold drift during autoregressive rollouts by using grid ``snapping'' as a native error-correction mechanism. Furthermore, by training via maximum entropy exploration (random walks), the model learns generalized transition dynamics rather than memorizing specific expert trajectories. We validate the GNWM across passive observation, active agent control, and abstract sequence regimes, demonstrating its capacity to act not just as a spatial physics simulator, but as a causal discovery model capable of organizing continuous, predictable concepts into structured topological maps.
title The Global Neural World Model: Spatially Grounded Discrete Topologies for Action-Conditioned Planning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2604.16585