As the answer of Vishma Dias described learning rate [decay], I would like to elaborate the epsilon-greedy method that I think the question implicitly mentioned a **decayed-epsilon-greedy** method for exploration and exploitation.

One way to balance between exploration and exploitation during training RL policy is by using the **epsilon-greedy** method. For example, =0.3 means with a probability=0.3 the output action is randomly selected from the action space, and with probability=0.7 the output action is greedily selected based on argmax(Q).

An improved of the epsilon-greedy method is called a **decayed-epsilon-greedy** method.
In this method, for example, we train a policy with totally N epochs/episodes (which depends on the problem specific), the algorithm initially sets = (e.g., =0.6), then gradually decreases to end at = (e.g., =0.1) over training epoches/episodes.
Specifically, at the initial training process, we let the model more freedom to explore with a high probability (e.g.,=0.6), and then gradually decrease the with a rate *r* over training epochs/episodes with the following formula:

With this more flexible choice to end at the very small exploration probability , after the training process will focus more on exploitation (i.e., greedy) while it still can explore with a very small probability when the policy is approximately converged.

You can see the advantage of the decayed-epsilon-greedy method in this post.