Distilling Deep RL Models Into Interpretable Neuro-Fuzzy Systems

Add code
Sep 07, 2022
Arne Gevaert, Jonathan Peck, Yvan Saeys
Figure 1 for Distilling Deep RL Models Into Interpretable Neuro-Fuzzy Systems
Figure 2 for Distilling Deep RL Models Into Interpretable Neuro-Fuzzy Systems
Figure 3 for Distilling Deep RL Models Into Interpretable Neuro-Fuzzy Systems
Figure 4 for Distilling Deep RL Models Into Interpretable Neuro-Fuzzy Systems

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon

Deep Reinforcement Learning uses a deep neural network to encode a policy, which achieves very good performance in a wide range of applications but is widely regarded as a black box model. A more interpretable alternative to deep networks is given by neuro-fuzzy controllers. Unfortunately, neuro-fuzzy controllers often need a large number of rules to solve relatively simple tasks, making them difficult to interpret. In this work, we present an algorithm to distill the policy from a deep Q-network into a compact neuro-fuzzy controller. This allows us to train compact neuro-fuzzy controllers through distillation to solve tasks that they are unable to solve directly, combining the flexibility of deep reinforcement learning and the interpretability of compact rule bases. We demonstrate the algorithm on three well-known environments from OpenAI Gym, where we nearly match the performance of a DQN agent using only 2 to 6 fuzzy rules.

View paper onarxiv icon

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon