# Reinforcement learning: Differences between QLearning and SarsaTD?

I apologize if the question doesn't fit any programming language specifications. If it is of real importance, I'm using C++.

I'm comparing learning algorithms, and although I know that Sarsa is On-Policy, while Qlearning is Off-Policy, when looking at their formulas I really do not see any difference. According to "Reinforcement Learning" by R.Sutton and A.G.Barto:

For a policy with value `Q` of state `S`, action `A`, timestep `t`:

``````SarsaTD: Q(St,At) = Q(St,At) + a [ R(t+1) + discount * Q(St+1,At+1) - Q(St,At) ]

Qlearning: Q(St,At) = Q(St,At) + a [ R(t+1) + discount * max Q(St+1,At) - Q(St,At) ]
``````

Is the real difference the fact that Sarsa only looks up the next Policy Value, while Qlearning looks up the next maximum Policy value ?

Thank you.

EDIT:

Ok so indeed the difference is the lookup on Q' ( Q(St+1,At+1). I do not however understand how the updating takes place: In Qlearning, for state S, i choose action A, because this action leads to max Q'. In Sarsa, how do I choose for state S, an action A ? (based on what criteria ?)

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Yes, this is the only difference. On-policy SARSA learns action values relative to the policy it follows, while off-policy Q-Learning does it relative to the greedy policy. Under some common conditions, they both converge to the real value function, but at different rates. Q-Learning tends to converge a little slower, but has the capabilitiy to continue learning while changing policies. Also, Q-Learning is not guaranteed to converge when combined with linear approximation.

In real-life terms, a SARSA person deciding which party to go to would choose the one he expects to be the most fun, while a Q-Learning person would choose the one that could be the most fun, if he made all the right moves.

In practical terms, under the ε-greedy policy, Q-Learning computes the difference between Q(s,a) and the maximum action value, while SARSA computes the difference between Q(s,a) and the weighted sum of the average action value and the maximum:

Q-Learning: Q(st+1,at+1) = maxaQ(st+1,a)

SARSA: Q(st+1,at+1) = ε·meanaQ(st+1,a) + (1-ε)·maxaQ(st+1,a)

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Ok, so how does Sarsa then choose a Policy ? I see that Qlearning will always go after the policy that promises it's action to take you to the next best Policy. What are the criteria for selecting the next Policy in Sarsa (basically what I want to know is how to evaluate for a Policy Q(S,A) how to choose the best action ). Isn't it the same, i.e. choosing for State S, the action A, which will has the highest (i.e. max) Q'(S,A) ? –  Alex Jul 28 '11 at 11:40
The policy is the rule for selecting the next action. It is something you need to choose when implementing the algorithm. The simplest policy is the greedy one — where the agent always chooses the best action. With this policy, SARSA and Q-Learning are the same. A better choice for learning is the ε-greedy policy, where some of the actions are chosen at random. –  Don Reba Jul 28 '11 at 11:59
Ok, that is why I asked the question in the first place, in this case they both are the same. Thank you very much ! I am using e-Greedy. So Qlearning only differs in the case of Off-Policy, where actions are chosen randomly yet updating with Q-learning maximizes Policy values ? –  Alex Jul 28 '11 at 12:04
Under the ε-greedy policy, the expected value under SARSA is the weighted sum of the average action value and the best action value: Q(s_t+1,a_t+1)=ε·mean(Q(s,a))+(1-ε)·max(Q(s,a)). The textbook gives it in chapter 5.4 On-Policy Monte Carlo Control. –  Don Reba Jul 28 '11 at 12:40
Thank you very much ! –  Alex Jul 28 '11 at 12:57

There's an index mistake in your formula for Q-Learning. Page 148 of Sutton and Barto's.

Q(st,at) <-- Q(st,at) + alpha * [r(t+1) + gamma * max Q(st+1,a) - Q(st,at) ]

The typo is in the argument of the max:

the indexes are st+1 and a, while in your question they are st+1 and at+1 (these are correct for SARSA).

Hope this helps a bit.

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In Q-Learning

This is your: Q-Learning: Q(St,At) = Q(St,At) + a [ R(t+1) + discount * max Q(St+1,At) - Q(St,At) ]

should be changed to Q-Learning: Q(St,At) = Q(St,At) + a [ R(t+1) + discount * max Q(St+1,a) - Q(St,At) ]

As you said, you have to find the maximum Q-value for the update eq. by changing the a, Then you will have a new Q(St,At). CAREFULLY, the a that give you the maximum Q-value is not the next action. At this stage, you only know the next state (St+1), and before going to next round, you want to update the St by the St+1 (St <-- St+1).

For each loop;

• choose At from the St using the Q-value

• take At and observe Rt+1 and St+1

• Update Q-value using the eq.

• St <-- St+1

Until St is terminal

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You should really format your answer. However, you're absolutely right. The formulas in Sutton & Barto denote as Q(St+1,At+1) while in practical terms its what you said. Wikipedia also had the wrong formula until very recently. –  Alex Mar 11 '14 at 21:24