Dynamic resource allocation during reinforcement learning accounts for ramping and phasic dopamine activity.

Neural Netw

Department of Bio and Brain Engineering, Korea Advanced Institute of Science and Technology (KAIST), Daejeon, 34141, South Korea; Program of Brain and Cognitive Engineering, Daejeon, 34141, South Korea; KAIST Institute for Health, Science, and Technology, Daejeon, 34141, South Korea; KAIST Institute for Artificial Intelligence, Daejeon, 34141, South Korea; KAIST Center for Neuroscience-inspired AI, Daejeon, 34141, South Korea. Electronic address:

Published: June 2020

AI Article Synopsis

  • - Understanding how animals learn from their environment involves balancing focus on important stimuli while being adaptable to changes; midbrain dopamine neurons play a key role in prioritizing these stimuli through their activity patterns.
  • - The study investigates how dopamine activity can transition between phasic responses to cues and rewards, and ramping activity as a reward is approached, which reflects resource allocation for learning.
  • - By modifying a standard learning model and simulating these dopamine transitions, the research shows that dopamine shifts between activity patterns based on the focus of the agent's resources, influencing task adaptation in response to environmental changes.

Article Abstract

For an animal to learn about its environment with limited motor and cognitive resources, it should focus its resources on potentially important stimuli. However, too narrow focus is disadvantageous for adaptation to environmental changes. Midbrain dopamine neurons are excited by potentially important stimuli, such as reward-predicting or novel stimuli, and allocate resources to these stimuli by modulating how an animal approaches, exploits, explores, and attends. The current study examined the theoretical possibility that dopamine activity reflects the dynamic allocation of resources for learning. Dopamine activity may transition between two patterns: (1) phasic responses to cues and rewards, and (2) ramping activity arising as the agent approaches the reward. Phasic excitation has been explained by prediction errors generated by experimentally inserted cues. However, when and why dopamine activity transitions between the two patterns remain unknown. By parsimoniously modifying a standard temporal difference (TD) learning model to accommodate a mixed presentation of both experimental and environmental stimuli, we simulated dopamine transitions and compared them with experimental data from four different studies. The results suggested that dopamine transitions from ramping to phasic patterns as the agent focuses its resources on a small number of reward-predicting stimuli, thus leading to task dimensionality reduction. The opposite occurs when the agent re-distributes its resources to adapt to environmental changes, resulting in task dimensionality expansion. This research elucidates the role of dopamine in a broader context, providing a potential explanation for the diverse repertoire of dopamine activity that cannot be explained solely by prediction error.

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http://dx.doi.org/10.1016/j.neunet.2020.03.005DOI Listing

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