This question was orignaly posted on cstheory but I believe the community of stackoverflow can also help. Any inspiration is warmly welcome.
To the point. Imagine a following scenario (Long time ago...):
You are a Jedi Master whose solemn purpose in life is to prepare your aprentice, let's call him Luke, for an ultimate challenge devised by ancient Jedi as a way of protecting their tomb from unauthorised Gungans stealing their stuff.
The challenge is devised to test each and every ability a true Jedi should posses, so your training should be as comprehensive as possible - you cannot leave any weak links or Luke will die!
Unfortunately you have to save a bunch of Ewoks stuck in an elevator on Coursant so you cannot finish the training yourself - you have to prepare a traning algorithm that will chose challenges Luke will face in the training room and let C3PO finish the job.
As this question is application-specific I will provide an extensive amount of properties, they are listed in decreasing importance/ease of extraction:
- There are 5-20 ablities you want Luke to practice
- You have a special algorithm that makes the practice session unique withing an ability
- Each seassion have a binnary peformance scale - Luke lives (0) or Luke dies (1) (during practice Luke will only get snapped by R2D2)
- If Luke fails a session he can play a special hologram explaining how he should have completed this specific practice session. You can assume that if he watches this hologram he will on average do better next time.
- We don't have much time! We have about 50 practice sessions in 3 stages (about 17 each) that is if everything goes smoothly (Luke solves all challenges at first trial).
- Each of Luke's failure's increases the amount of practice sessions you want him to do by a small amount 2-6.
- At any time during practice you want C3PO to be able to give Luke some feedback to reflect his progress in each ability. Scale: don't know yet, poor, some problems, decent, awesome
- If Luke fails at the end of an stage he will have to do more sessions in this stage than if he fails at the beginning.
You are very scrupulous and have made a lot of notes on how Luke was doing so far, namely
- A number of practice sessions of a particular ability
- Your special score of grading his performance in a particular ability (0 - you don't know, < 50 - poor, < 70 - ok, < 80 - good enough, < 90 - very well my young padawan, 100 - unlimited poweeeer!)
- Last time when given ability was practiced (we can assume that skill deteriorates over time)
- Time spent practicing
- Number of times you gave Luke a lecture after failing a practice session
- How long did each lecture take - Sometimes we don't have any of this information at all :(
Some abilities may affect the other - ex. if Luke get's better at 'force push' he will probably improve in 'force pull'
Each of Lukes failure's increases the amount of practice sessions you want him to do.
- You have a detailed history of how your previous students performed during their training.
Also the tomb defense will not wait until Luke has his lunch between the challenges so C3PO has to be able to throw new practice sessions at him in an online fashion - we are looking for a fast, computationally inexpenisive policy. However preprocessing (analyising data from 9.) can take some more time (as in 'We have some time to preprocess the data) . Also when analyising the data from 12. we have much more time - lets say C3P0 can do it overnight.
I see three ways of approaching this problem
- (simplification) As a special case of Non-Bayesian Binary Restless Multi-armed Bandit with Non-Identical Arms (uff) meaning:
- restless - reward probability evolves over time (is a Markov process)
- Non-Bayesian - underlying Markov transitions are not known
- Non-Identical - each arm is an a different (can't say independent due to property 10.) Markov process
How is it special:
- we can have a initial belief vector without the initial exploration phase due to property 9. and 12.
- we don't consider it in the conventional way - asymptotic reward is of no use for us (vide prop. 5.)
- the process (arm) should actually model learning - as Luke does more sessions in one ability the probability of him failing in it (our alorithm recieving a reward = 1) should be decreasing
we have to be able to translate the belief vector to human readable form to give Luke some feedback about his performance (7.)
- A more comprehensive approach based on a combination of Supervised Learning (preprocessing phase) and Reinforcment Learning .
I'm just starting to familiarize myself with these areas of research so I can't provide any insight here.I will update the question once I learn anything meaningful.
- (Super simplification) A greedy-randomized algorithm based on genetic approach (looks very similar to epsilon-greedy algorithm for RMBA)
- prepossessing can adjust initial fitness of specimen (abilities)
- in each step of the algorithm selects one ability for practice and afterwards its fitness is adjusted to new_fitness = f(previous_fitness, practice_session_reward) by some evaluation function
- possible selection policies: elitist (epsilon probability of choosing the best specimen otherwise we chose at random), roulette, tournaments
Uff, I could go on about implications I see in each of the aforementioned properties but I'm afraid this question will get to long (feel free to request them though) so I will cut to the chase.
How can YOU help Luke?
General ways to help
- By helping to assemble a list of similar problems/areas to explore.
- By providing references to solutions of similar problems.
- By suggesting algorithms or their parts (prepossessing, transition functions, selection routines), that would help to prepare a good training program.
- By throwing ideas how certain properties could be used to help C3PO to be more responsive and problem oriented
- By up-voting this question so more people can see it and help
Specific ways to help
a.d Approach 1. (RMBA) :
- By providing references to similar cases of RMBA (please do not list purely theoretical papers with algorithms that have only theoretical value of proving asymptotic regret but are not suited for implementation)
- By suggesting RMBA algorithms that could perform well in this application
- By helping me to find ways to incorporate problem specific properties to well known algorithms, especially:
- a way of recalculating the belief vector after each timestep that would take into acount that Luke is learning
- a way of translating the belief vector to human readable form)
a.d. Approach 2. (Reinforment Learing):
- By providing references or good (concise) introductory materials for someone to understand RL (fast!)
- By suggesting areas of RL that will come in handy
- By suggesting RL algorithms that will help to solve this problem
- Points analogous to approach 1.
a.d. Approach 3. (Genetic Algorithm):
- By suggesting good fitness adjustment f(previous_fitness, practice_session_reward) function
- By suggesting a good selection policy
- By showing me how to incorporate historical data to get initial fitness of the specimen (ability)
- By proposing how to translate fitness to human readable form (to give Luke his feedback)
- Points analogous to approach 1.
Just to emphasize the ultimate goal - we want Luke to overcome his weaknesses - hence we have to make the practice sessions a challenge - essentially our goal is to give Luke task he cannot complete (hence if he fails the algorithm gets a reward equal to 1), so he won't waste time on futile training of well known abilities. Correct me if this is not the best way to make sure Luke is properly trained.
Thank you in advance and may the force be with you.