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Bibliographic Details
Main Authors: Pendyala, Abhijeet, Glasmachers, Tobias
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.17194
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author Pendyala, Abhijeet
Glasmachers, Tobias
author_facet Pendyala, Abhijeet
Glasmachers, Tobias
contents In this work, we augment reinforcement learning with an inference-time collision model to ensure safe and efficient container management in a waste-sorting facility with limited processing capacity. Each container has two optimal emptying volumes that trade off higher throughput against overflow risk. Conventional reinforcement learning (RL) approaches struggle under delayed rewards, sparse critical events, and high-dimensional uncertainty -- failing to consistently balance higher-volume empties with the risk of safety-limit violations. To address these challenges, we propose a hybrid method comprising: (1) a curriculum-learning pipeline that incrementally trains a PPO agent to handle delayed rewards and class imbalance, and (2) an offline pairwise collision model used at inference time to proactively avert collisions with minimal online cost. Experimental results show that our targeted inference-time collision checks significantly improve collision avoidance, reduce safety-limit violations, maintain high throughput, and scale effectively across varying container-to-PU ratios. These findings offer actionable guidelines for designing safe and efficient container-management systems in real-world facilities.
format Preprint
id arxiv_https___arxiv_org_abs_2503_17194
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Curriculum RL meets Monte Carlo Planning: Optimization of a Real World Container Management Problem
Pendyala, Abhijeet
Glasmachers, Tobias
Machine Learning
In this work, we augment reinforcement learning with an inference-time collision model to ensure safe and efficient container management in a waste-sorting facility with limited processing capacity. Each container has two optimal emptying volumes that trade off higher throughput against overflow risk. Conventional reinforcement learning (RL) approaches struggle under delayed rewards, sparse critical events, and high-dimensional uncertainty -- failing to consistently balance higher-volume empties with the risk of safety-limit violations. To address these challenges, we propose a hybrid method comprising: (1) a curriculum-learning pipeline that incrementally trains a PPO agent to handle delayed rewards and class imbalance, and (2) an offline pairwise collision model used at inference time to proactively avert collisions with minimal online cost. Experimental results show that our targeted inference-time collision checks significantly improve collision avoidance, reduce safety-limit violations, maintain high throughput, and scale effectively across varying container-to-PU ratios. These findings offer actionable guidelines for designing safe and efficient container-management systems in real-world facilities.
title Curriculum RL meets Monte Carlo Planning: Optimization of a Real World Container Management Problem
topic Machine Learning
url https://arxiv.org/abs/2503.17194