Sub-Goal Trees -- a Framework for Goal-Based Reinforcement Learning
This work addresses multi-goal queries in reinforcement learning, particularly for robotics applications like motion planning, though it appears incremental as it builds on existing dynamic programming and policy gradient methods.
The paper tackles the problem of multi-goal reinforcement learning by proposing a new framework based on the all pairs shortest path problem, which introduces sub-goal trees for constructing trajectories recursively, and demonstrates significant improvements in navigating a 7-DoF robot arm between obstacles.
Many AI problems, in robotics and other domains, are goal-based, essentially seeking trajectories leading to various goal states. Reinforcement learning (RL), building on Bellman's optimality equation, naturally optimizes for a single goal, yet can be made multi-goal by augmenting the state with the goal. Instead, we propose a new RL framework, derived from a dynamic programming equation for the all pairs shortest path (APSP) problem, which naturally solves multi-goal queries. We show that this approach has computational benefits for both standard and approximate dynamic programming. Interestingly, our formulation prescribes a novel protocol for computing a trajectory: instead of predicting the next state given its predecessor, as in standard RL, a goal-conditioned trajectory is constructed by first predicting an intermediate state between start and goal, partitioning the trajectory into two. Then, recursively, predicting intermediate points on each sub-segment, until a complete trajectory is obtained. We call this trajectory structure a sub-goal tree. Building on it, we additionally extend the policy gradient methodology to recursively predict sub-goals, resulting in novel goal-based algorithms. Finally, we apply our method to neural motion planning, where we demonstrate significant improvements compared to standard RL on navigating a 7-DoF robot arm between obstacles.