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Generalization, discrimination, and extinction are key concepts in operant conditioning that influence how behaviors are learned and maintained.
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Positive reinforcement is a powerful method for teaching new behaviors to both animals and humans. B.F. Skinner demonstrated this with his experiments using rats in a Skinner box. When a rat pressed a lever, it received a food pellet. This immediate reward encouraged the rat to repeat the behavior. This method, where a reward follows every instance of the behavior, is known as continuous reinforcement. It is highly effective for establishing new behaviors quickly.
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Reward-predictive representations generalize across tasks in reinforcement learning.

Lucas Lehnert1,2, Michael L Littman1, Michael J Frank3,2

  • 1Computer Science Department, Brown University, Providence, RI 02912, USA.

Plos Computational Biology
|October 15, 2020
PubMed
Summary
This summary is machine-generated.

Artificial agents using reinforcement learning (RL) struggle with task generalization. New reward-predictive representations enable agents to generalize learning across different tasks, mimicking human-like deep transfer.

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Area of Science:

  • Computer Science
  • Artificial Intelligence
  • Machine Learning

Background:

  • Reinforcement learning (RL) with deep neural networks excels in specific tasks but lacks generalization.
  • Current transfer learning methods in RL are limited, failing to achieve human-like deep transfer.
  • Deep transfer requires discovering abstractions for analogical reuse of representations across distinct tasks.

Purpose of the Study:

  • To develop a novel abstraction method for reinforcement learning that enables generalization across diverse tasks.
  • To investigate if reward-predictive representations can facilitate deep transfer in artificial agents.
  • To explore the potential for state representation abstractions that support equivalence relations.

Main Methods:

  • Developed abstractions that minimize prediction errors for reward outcomes.
  • Constructed reward-predictive representations that compress task state spaces.
  • Combined states based on equivalence in transition and reward functions.

Main Results:

  • Reward-predictive abstractions generalized across tasks with varying transition and reward functions.
  • These representations are not tied to specific task dynamics, enabling broad applicability.
  • The approach contrasts with myopic reward-maximization strategies in RL.

Conclusions:

  • Abstractions minimizing reward prediction error facilitate generalization in reinforcement learning.
  • This approach offers a pathway towards achieving deep transfer in artificial agents.
  • Findings suggest investigating neural and cognitive systems for similar abstraction mechanisms.