FORM: Learning Expressive and Transferable First-Order Logic Reward Machines
December 31, 2024 Β· Declared Dead Β· π Adaptive Agents and Multi-Agent Systems
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Authors
Leo Ardon, Daniel Furelos-Blanco, Roko Parac, Alessandra Russo
arXiv ID
2501.00364
Category
cs.AI: Artificial Intelligence
Cross-listed
cs.FL,
cs.LO,
cs.SC
Citations
2
Venue
Adaptive Agents and Multi-Agent Systems
Last Checked
4 months ago
Abstract
Reward machines (RMs) are an effective approach for addressing non-Markovian rewards in reinforcement learning (RL) through finite-state machines. Traditional RMs, which label edges with propositional logic formulae, inherit the limited expressivity of propositional logic. This limitation hinders the learnability and transferability of RMs since complex tasks will require numerous states and edges. To overcome these challenges, we propose First-Order Reward Machines ($\texttt{FORM}$s), which use first-order logic to label edges, resulting in more compact and transferable RMs. We introduce a novel method for $\textbf{learning}$ $\texttt{FORM}$s and a multi-agent formulation for $\textbf{exploiting}$ them and facilitate their transferability, where multiple agents collaboratively learn policies for a shared $\texttt{FORM}$. Our experimental results demonstrate the scalability of $\texttt{FORM}$s with respect to traditional RMs. Specifically, we show that $\texttt{FORM}$s can be effectively learnt for tasks where traditional RM learning approaches fail. We also show significant improvements in learning speed and task transferability thanks to the multi-agent learning framework and the abstraction provided by the first-order language.
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