Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I know the basics of feedforward neural networks, and how to train them using the backpropagation algorithm, but I'm looking for an algorithm than I can use for training an ANN online with reinforcement learning.

For example, the cart pole swing up problem is one I'd like to solve with an ANN. In that case, I don't know what should be done to control the pendulum, I only know how close I am to the ideal position. I need to have the ANN learn based on reward and punishment. Thus, supervised learning isn't an option.

Another situation is something like the snake game, where feedback is delayed, and limited to goals and anti-goals, rather than reward.

I can think of some algorithms for the first situation, like hill-climbing or genetic algorithms, but I'm guessing they would both be slow. They might also be applicable in the second scenario, but incredibly slow, and not conducive to online learning.

My question is simple: Is there a simple algorithm for training an artificial neural network with reinforcement learning? I'm mainly interested in real-time reward situations, but if an algorithm for goal-based situations is available, even better.

share|improve this question
add comment

2 Answers 2

up vote 7 down vote accepted

There are some research papers on the topic:

And some code:

Those are just some of the top google search results on the topic. The first couple of papers look like they're pretty good, although I haven't read them personally. I think you'll find even more information on neural networks with reinforcement learning if you do a quick search on Google Scholar.

share|improve this answer
    
The third link mentioned something about Q-learning. Is that applicable to the cart-pole problem? –  Kendall Frey May 23 '12 at 16:40
    
It seems to be applicable since it allows you to compare the expected utility of the available actions without having a model of the environment. So if you're doing an actual cart-pole problem with hardware, then it's going to be helpful. For more details on Q-learning see: applied-mathematics.net/qlearning/qlearning.html –  Lirik May 23 '12 at 16:47
    
Doesn't Q-learning involve a finite set of actions? The ideal cart-pole problem will have a continuous set of actions. Is that a problem? –  Kendall Frey May 23 '12 at 16:50
    
At the end of the day, there are many variants of NN and approaches for training which can be used to solve a problem, so you really have to spend a lot of time evaluating what's best for your problem domain. I would estimate that to be around 80% of the work! –  Lirik May 23 '12 at 17:00
    
I'm not all that familiar with the cart-pole problem, but I saw a discussion on google groups and it indicated that discrete actions lead to better results. It seems that there are RL + Continuous Action Space solutions involving Sequential Monte Carlo methods (referenced in the same discussion), but that seems like a slightly different approach. –  Lirik May 23 '12 at 18:34
add comment

If the output that lead to a reward r is backpropagated into the network r times, you will reinforce the network proportionally to the reward. This is not directly applicable to negative rewards, but I can think of two solutions that will produce different effects:

1) If you have a set of rewards in a range rmin-rmax, rescale them to 0-(rmax-rmin) so that they are all non-negative. The bigger the reward, the stronger the reinforcement that is created.

2) For a negative reward -r, backpropagate a random output r times, as long as it's different from the one that lead to the negative reward. This will not only reinforce desirable outputs, but also diffuses or avoids bad outputs.

share|improve this answer
    
Interesting. I wonder how this applies to delayed reward. I'm guessing it would work to specify anything that isn't a goal as a small negative reward. –  Kendall Frey May 23 '12 at 16:35
    
@Kendall Frey: For a neural network that can handle delays better that normal neural networks, see Long short term memory (Youtube video), or see hierarchical temporal memory (Youtube video). –  HelloGoodbye Feb 15 at 18:58
1  
Why should you rescale the rewards like that? Do they need rescaling at all? By doing that, a reward rmin becomes 0 after rescaling, so what was supposed to be a reward will turn out to have no reinforcement effect on the network. –  HelloGoodbye Feb 15 at 21:10
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.