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NECO
2007
2007
Reinforcement Learning, Spike-Time-Dependent Plasticity, and the BCM Rule
Learning agents, whether natural or artificial, must update their internal parameters in order to improve their behavior over time. In reinforcement learning, this plasticity is influenced by an environmental signal, termed a reward, which directs the changes in appropriate directions. We apply a recently introduced policy learning algorithm from Machine Learning to networks of spiking neurons, and derive a spike time dependent plasticity rule which ensures convergence to a local optimum of the expected average reward. The approach is applicable to a broad class of neuronal models, including the Hodgkin-Huxley model. We demonstrate the effectiveness of the derived rule in several toy problems. Finally, through statistical analysis we show that the synaptic plasticity rule established is closely related to the widely used BCM rule, for which good biological evidence exists. 1 Policy Learning and Neuronal Dynamics Reinforcement Learning (RL) is a general term used for a class of lear...
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| Added | 27 Dec 2010 |
| Updated | 27 Dec 2010 |
| Type | Journal |
| Year | 2007 |
| Where | NECO |
| Authors | Dorit Baras, Ron Meir |
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