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Laplacian Representations for Decision-Time Planning

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arxiv 2602.05031 v2 pith:UJ7PIITD submitted 2026-02-04 cs.LG

Laplacian Representations for Decision-Time Planning

classification cs.LG
keywords planningdecision-timedistanceslaplacianlong-horizonrepresentationrepresentationsalgorithm
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Planning with a learned model remains a key challenge in model-based reinforcement learning (RL). In decision-time planning, state representations are critical as they must support local cost computation while preserving long-horizon structure. In this paper, we show that the Laplacian representation provides an effective latent space for planning by capturing state-space distances at multiple time scales. This representation preserves meaningful distances and naturally decomposes long-horizon problems into subgoals, also mitigating the compounding errors that arise over long prediction horizons. Building on these properties, we introduce ALPS, a hierarchical planning algorithm, and demonstrate that it outperforms commonly used baselines on a selection of offline goal-conditioned RL tasks from OGBench, a benchmark previously dominated by model-free methods.

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    cs.LG 2026-03 unverdicted novelty 4.0

    Temporal abstraction functions as a low-pass filter on transition dynamics to lower the effective rank of successor representations while bounding value function error in forward-backward learning.