# SARSA algorithm for average reward problems

My question is about using the SARSA algorithm in reinforcement learning for an undiscounted, continuing (non-episodic) problem (can it be used for such a problem?)

I have been studying the textbook by Sutton and Barto, and they show how to modify the Q-learning algorithm so that it can be used for undiscounted problems. They refer to the new algorithm (for undiscounted problems) as R-learning, in Chapter 6.7. Basically, in R-learning, the update rule for Q(s,a) on each iteration is:

Q(s,a) = Q(s,a) + alpha * [r - rho + max_a{Q(s',a)} - Q(s,a)]

Here, rho is updated on each iteration only if a greedy action is chosen at state s. The update rule for rho is:

rho = rho + beta * [r - rho + max_a{Q(s',a)} - max_a{Q(s,a)}]

(Here, alpha and beta are learning parameters.) Now, my question is to do with SARSA, rather than Q-learning. I want to modify the SARSA algorithm so that it is suitable for average reward (undiscounted) problems, in the same way that the Q-learning was modified to be used for average reward problems (I don't know if this is possible?). However, in the literature I cannot find an explanation of exactly how SARSA should be modified for an average reward problem.

Here is my guess for how SARSA should be used in an undiscounted problem. I would guess that the update rule should be:

Q(s,a) = Q(s,a) + alpha * [r - rho + Q(s',a') - Q(s,a)],

where a' is the action actually chosen at state s. This seems fairly obvious. But how should rho be updated? My guess is that since SARSA is an on-policy algorithm, rho should always be updated on each iteration - regardless of whether or not a greedy action is chosen at s - and the update rule should simply be:

rho = rho + beta * [r - rho + Q(s',a') - Q(s,a)].

Could somebody tell me if this is correct? Or should rho still be updated based on the optimal actions at the states s and s'?