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I am working on the power management of a device using Q-learning algorithm. The device has two power modes, i.e., idle and sleep. When the device is asleep, the requests for processing are buffered in a queue. The Q-learning algorithm looks for minimizing a cost function which is a weighted sum of the immediate power consumption and the latency caused by an action.

c(s,a)=lambda*p_avg+(1-lambda)*avg_latency

In each state, the learning algorithm takes an action (executing time-out values) and evaluates the effect of the taken action in next state (using above formula). The actions are taken by executing certain time-out values from a pool of pre-defined time-out values. The parameter lambda in above equation is a power-performance parameter (0_<lambda<1). It defines whether the algorithm should look for power saving (lambda-->1) or should look for minimizing latency (lambda-->0). The latency for each request is calculated as queuing-time + execution-time.
The problem is that the learning algorithm always favors small time-out values in sleep state. It is because the average latency for small time-out values is always lower, and hence their cost is also small. When I change the value of lambda from lower to higher, I don't see any effect in the final output policy. The policy always selects small time-out values as best actions in each state. Instead of average power and average latency for each state, I have tried using overall average power consumption and overall average latency for calculating cost for a state-action pair, but it doesn't help. I also tried using total energy consumption and total latency experinced by all the request for calculating cost in each state-action pair, but it doesn't help either. My question is: what could be a better cost function for this scenario? I update the Q-value as follows:

Q(s,a)=Q(s,a)+alpha*[c(s,a)+gamma*min_a Q(s',a')-Q(s,a)]

Where alpha is a learning rate (decreased slowly) and gamma=0.9 is a discount factor.

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Just as a note for convention: avoid the use of the term "lambda" in your reward function. Q(lambda) is another algorithm - which, not coincidentally, might be more appropriate for this problem (assuming you are using 1-step Q-learning. –  Throwback1986 Aug 8 '12 at 17:52
    
Yes, it's a 1-step learning. lambda in the cost function is just a power-performance tradeoff parameter. If I omit this parameter in the cost function, how do I define a criteria for either power saving or latency minimization? –  user846400 Aug 9 '12 at 8:23
    
I'm not suggesting that you omit the parameter. I'm suggesting you choose another variable to denote your "power performance parameter". –  Throwback1986 Aug 9 '12 at 14:54
    
My confusion is that if I use 1-step Q-learning (as above), shall I use the entire power consumption and entire latency for all the requests to calculate the cost in each state (s,a)? or shall I use the immediate power consumption and average latency caused by an action a in state s? –  user846400 Aug 9 '12 at 18:54

1 Answer 1

To answer the questions posed in the comments:

shall I use the entire power consumption and entire latency for all the requests to calculate the cost in each state (s,a)?

No. In Q-learning, reward is generally considered an instantaneous signal associated with a single state-action pair. Take a look at Sutton and Barto's page on rewards. As shown the instantaneous reward function (r_t+1) is subscripted by time step - indicating that it is indeed instantaneous. Note that R_t, that expected return, considers the history of rewards (from time t back to t_0). Thus, there is no need for you to explicitly keep track of accumulated latency and power consumption (and doing so is likely to be counter-productive.)

or shall I use the immediate power consumption and average latency caused by an action a in state s?

Yes. To underscore the statement above, see the definition of an MDP on page 4 here. The relevant bit:

The reward function specifies expected instantaneous reward as a function of the current state and action

As I indicated in a comment above, problems in which reward is being "lost" or "washed out" might be better solved with a Q(lambda) implementation because temporal credit assignment is performed more effectively. Take a look at Sutton and Barto's chapter on TD(lambda) methods here. You can also find some good examples and implementations here.

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Thanks Throwback1986. Sutton and Barto talk about maximizing the reward throughout their book. My confusion is that: do all the algorithms hold true for minimizing a cost in the same way, instead of maximizing a reward. In my case, I have to minimize the above mentioned cost function based on a power-performance constraint. –  user846400 Aug 13 '12 at 10:11
    
Minimizing negative reward is the same as maximizing positive reward. It's just a matter of sign convention. If you express your cost function as a negative reinforcement, your agent can by guided to select actions that minimize cost (thereby maximizing reward). –  Throwback1986 Aug 13 '12 at 14:20
    
Thanks Trowback1986. Your hints are very useful. There is one more question. If the next state and the current state by action are same, shall I assign cost to this state, or shall I wait till the state changes and assign the cost in terms of total energy consumption and latency? For example, if the algorithm executes a time-out period in sleep state and no requests come by the end of time-out period, the system finds itself in the same state. –  user846400 Aug 13 '12 at 14:26
    
Note the time subscript on the the reward function: this should tell you that a new reward (or cost) is to be computed at each time-step. Recall that reward is computed as r(s,a), i.e. a function of state and action. There is no inherent restriction that forces s_t-1 to be different from s_t. –  Throwback1986 Aug 13 '12 at 14:46
    
Thanks. In my case, could you suggest a better cost function to deal with the power consumption and per request latency with respect to a selected power-performance parameter? –  user846400 Aug 14 '12 at 11:28

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