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Main Authors: Mohamed, Mohamed A., Nekhomiazh, Kateryna, Vyas, Vedant, Jose, Marcos M., Patterson, Andrew, Machado, Marlos C.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.18347
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author Mohamed, Mohamed A.
Nekhomiazh, Kateryna
Vyas, Vedant
Jose, Marcos M.
Patterson, Andrew
Machado, Marlos C.
author_facet Mohamed, Mohamed A.
Nekhomiazh, Kateryna
Vyas, Vedant
Jose, Marcos M.
Patterson, Andrew
Machado, Marlos C.
contents Continual reinforcement learning (RL) concerns agents that are expected to learn continually, rather than converge to a policy that is then fixed for evaluation. This setting is well-suited to environments that the agent perceives as changing over time, rendering any static policy ineffective. In continual RL, researchers often simulate such changes either by modifying episodic environments to incorporate task shifts during interaction or by designing simulators that explicitly model continual dynamics. However, transforming episodic problems into continual ones primarily captures scenarios involving abrupt changes in the data stream and still relies on episodic structure. Meanwhile, the few simulators explicitly designed for empirical continual RL research are often limited in scope or complexity. In this paper, we introduce AgarCL, a research platform for continual RL that enables agents to progress toward increasingly sophisticated behaviour. AgarCL is based on the game Agar.io, a non-episodic, high-dimensional problem with stochastic, ever-evolving dynamics, continuous actions, and partial observability. We provide benchmark results for DQN, PPO, and SAC on the primary continual RL challenge, as well as across a suite of smaller tasks within AgarCL. These smaller tasks isolate aspects of the full environment and allow us to characterize the distinct challenges posed by different components of the game. We further evaluate three continual learning methods-Shrink and Perturb, ReDo, and Continual Backpropagation-and observe little improvement over standard RL algorithms, suggesting that the challenges posed by AgarCL extend beyond the stability-plasticity dilemma.
format Preprint
id arxiv_https___arxiv_org_abs_2505_18347
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Cell Must Go On: Agar.io for Continual Reinforcement Learning
Mohamed, Mohamed A.
Nekhomiazh, Kateryna
Vyas, Vedant
Jose, Marcos M.
Patterson, Andrew
Machado, Marlos C.
Machine Learning
Artificial Intelligence
Continual reinforcement learning (RL) concerns agents that are expected to learn continually, rather than converge to a policy that is then fixed for evaluation. This setting is well-suited to environments that the agent perceives as changing over time, rendering any static policy ineffective. In continual RL, researchers often simulate such changes either by modifying episodic environments to incorporate task shifts during interaction or by designing simulators that explicitly model continual dynamics. However, transforming episodic problems into continual ones primarily captures scenarios involving abrupt changes in the data stream and still relies on episodic structure. Meanwhile, the few simulators explicitly designed for empirical continual RL research are often limited in scope or complexity. In this paper, we introduce AgarCL, a research platform for continual RL that enables agents to progress toward increasingly sophisticated behaviour. AgarCL is based on the game Agar.io, a non-episodic, high-dimensional problem with stochastic, ever-evolving dynamics, continuous actions, and partial observability. We provide benchmark results for DQN, PPO, and SAC on the primary continual RL challenge, as well as across a suite of smaller tasks within AgarCL. These smaller tasks isolate aspects of the full environment and allow us to characterize the distinct challenges posed by different components of the game. We further evaluate three continual learning methods-Shrink and Perturb, ReDo, and Continual Backpropagation-and observe little improvement over standard RL algorithms, suggesting that the challenges posed by AgarCL extend beyond the stability-plasticity dilemma.
title The Cell Must Go On: Agar.io for Continual Reinforcement Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2505.18347