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As far as my understanding is, it's possible to replace a look-up-table for Q-values (state-action-pair-evaluation) by a neural network for estimating these state-action pairs. I programmed a small library, which is able to propagate and backpropagate through a self-built neural network for learning wanted target-values for a certain in-out-put.

So I also found this site while googling, and googling through the whole web (as it felt for me): http://www.cs.indiana.edu/~gasser/Salsa/nn.html where the Q-learning combined with a neural network is shortly explained.

For each action, there's an extra output neuron, and the activation-value of one of these output-"units" tells me, the estimated Q-value. (One question: Is the activation value the same as the "output" of the neuron or something different?)

I used the standard sigmoid-function as activation-function, so the range of the function-values x is

0<x<1

So I thought, my target value should always be from 0.0 to 1.0 -> Question: Is that point of my understanding correct? Or did I missunderstand something about that?

If yes, there comes following problem: The equation for calculating the target-reward / new Q-value is: q(s,a) = q(s,a) + learningrate * (reward + discountfactor * q'(s,a) - q(s,a))

So how do I perform this equation to get the right target for the neural network, if targets should be from 0.0 to 1.0?! How do I calculate good reward-values? Is moving toward the aim more worth it, than going away from it? (more +reward when nearing the aim than -reward for bigger distance to aim?)

I think there are some missunderstandings of mine. I hope, you can help me to answer that questions. Thank you very much!

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1 Answer 1

Using a neural-network to store q-value is a good extension of table lookup. This makes it possible to use q-learning when the state space is continuous.

  input layer     ......  

                |/  \ |  \|
  output layer  a1   a2   a3
                0.1  0.2  0.9

Suppose you have 3 actions available. Above shows the outputs from the neural network using current state and learned weights. So you know a3 is the best action to go with.

Now the questions you have:

One question: Is the activation value the same as the "output" of the neuron or something different?

Yes, I think so. In the referred link, the author said:

Some of the units may also be designated output units; their activations represent the network's response.


So I thought, my target value should always be from 0.0 to 1.0 -> Question: Is that point of my understanding correct? Or did I missunderstand something about that?

If you choose sigmoid as your activation function, for sure you output will be from 0.0 to 1.0. There are different choices of activation functions, e.g., here. Sigmoid is one of the most popular choices though. I think the output value being from 0.0 to 1.0 is not a problem here. if at current time, you have only two available actions, Q(s,a1) = 0.1, Q(s,a2) = 0.9, you know that action a2 is much better than a1 with respective to q-value.


So how do I perform this equation to get the right target for the neural network, if targets should be from 0.0 to 1.0?! How do I calculate good reward-values?

I am not sure for this, but you can try to clamp the new target q-value to be between 0.0 and 1.0, i.e.,

q(s,a) = min(max(0.0, q(s,a) + learningrate * (reward + discountfactor * q'(s,a) - q(s,a))), 1.0)

Try to do some experiments for finding a proper reward value.


Is moving toward the aim more worth it, than going away from it? (more +reward when nearing the aim than -reward for bigger distance to aim?)

Normally you should give more reward when it's close to the aim if you use the classical update equation, so that the new q-value gets increased.

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wow thank you for that detailed answer! I just got another question about that: Is it quite useful to clamp the new target, or is there a chance of "wrong" behaviour of my agent? –  TheWhiteLlama Nov 19 '12 at 20:49
    
I am not sure. Unless you post some results here. Are you doing the epsilon-exploration for the agent? check the post here also. stackoverflow.com/questions/13148934/… –  greeness Nov 19 '12 at 21:29
    
Jup, the first thing I wanted to do is an "arrow", which should have the mission to find a red point (food or something). But even this easy-seeming task is not very easy for me :( –  TheWhiteLlama Nov 19 '12 at 22:21
1  
How about first implementing a table-lookup version of q-learning for your red-point mission (suppose you have discrete state space, check the link to the source code in my previous comment). Then try the neural network q-value storage for the same problem. –  greeness Nov 19 '12 at 22:26
1  
Yeah, linear activation at the output layer is good for regression problems. So it's a good choice to try for your case. –  greeness Nov 21 '12 at 19:46

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