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Main Authors: Collis, Poppy, Singh, Ryan, Kinghorn, Paul F, Buckley, Christopher L
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.10970
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author Collis, Poppy
Singh, Ryan
Kinghorn, Paul F
Buckley, Christopher L
author_facet Collis, Poppy
Singh, Ryan
Kinghorn, Paul F
Buckley, Christopher L
contents An open problem in artificial intelligence is how systems can flexibly learn discrete abstractions that are useful for solving inherently continuous problems. Previous work has demonstrated that a class of hybrid state-space model known as recurrent switching linear dynamical systems (rSLDS) discover meaningful behavioural units via the piecewise linear decomposition of complex continuous dynamics (Linderman et al., 2016). Furthermore, they model how the underlying continuous states drive these discrete mode switches. We propose that the rich representations formed by an rSLDS can provide useful abstractions for planning and control. We present a novel hierarchical model-based algorithm inspired by Active Inference in which a discrete MDP sits above a low-level linear-quadratic controller. The recurrent transition dynamics learned by the rSLDS allow us to (1) specify temporally-abstracted sub-goals in a method reminiscent of the options framework, (2) lift the exploration into discrete space allowing us to exploit information-theoretic exploration bonuses and (3) `cache' the approximate solutions to low-level problems in the discrete planner. We successfully apply our model to the sparse Continuous Mountain Car task, demonstrating fast system identification via enhanced exploration and non-trivial planning through the delineation of abstract sub-goals.
format Preprint
id arxiv_https___arxiv_org_abs_2408_10970
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hybrid Recurrent Models Support Emergent Descriptions for Hierarchical Planning and Control
Collis, Poppy
Singh, Ryan
Kinghorn, Paul F
Buckley, Christopher L
Artificial Intelligence
Systems and Control
An open problem in artificial intelligence is how systems can flexibly learn discrete abstractions that are useful for solving inherently continuous problems. Previous work has demonstrated that a class of hybrid state-space model known as recurrent switching linear dynamical systems (rSLDS) discover meaningful behavioural units via the piecewise linear decomposition of complex continuous dynamics (Linderman et al., 2016). Furthermore, they model how the underlying continuous states drive these discrete mode switches. We propose that the rich representations formed by an rSLDS can provide useful abstractions for planning and control. We present a novel hierarchical model-based algorithm inspired by Active Inference in which a discrete MDP sits above a low-level linear-quadratic controller. The recurrent transition dynamics learned by the rSLDS allow us to (1) specify temporally-abstracted sub-goals in a method reminiscent of the options framework, (2) lift the exploration into discrete space allowing us to exploit information-theoretic exploration bonuses and (3) `cache' the approximate solutions to low-level problems in the discrete planner. We successfully apply our model to the sparse Continuous Mountain Car task, demonstrating fast system identification via enhanced exploration and non-trivial planning through the delineation of abstract sub-goals.
title Hybrid Recurrent Models Support Emergent Descriptions for Hierarchical Planning and Control
topic Artificial Intelligence
Systems and Control
url https://arxiv.org/abs/2408.10970