**Here's my current method:**

Basically, what I'm currently doing is building a Naive Bayes Classifier (it might look complex in writing, but it's rather simple to implement). For each possible state of each feature (512 features * 2 states = 1024), I assign a Beta prior, which estimates the probability that this particular feature state will result in a user "click". When a user clicks an image, I update my priors.

Now the question is, how do I generate a new list of 9 sample vectors to display to the user? Well, I realized this is a Multi-Armed Bandit problem. For that, Thompson Sampling is an easy to use method. For each vector, and for each feature, I pick a state (either 0 or 1) with probability p, where p is proportional to the probability that the chosen state is the best (i.e., results in maximum likelihood for my Naive Bayes Classifier). To do this, I just sample from the Beta distribution for that feature at state 0, and also for that feature at state 1. I then set the feature depending on which sample is greatest.

This works to some degree.

**BIG Caveat:**

The main issue with what I'm doing is I am assuming independence in my features. More than that, and partly because the features are *not* independent, the distributions change as I iterate through this (partially invalidating previous data). Finally, the way I'm using Thompson sampling might not be best.

**Where now?**

My big question is, once I have a Naive Bayes classifier, how do I remove the assumption of independence? And with this updated model, can I still do something like Thompson sampling?

**Exploration vs Exploitation**

Thompson sampling helps to balance exploration vs exploitation. But since I have 9 images to choose from, surely some of those can be more exploitative. Here's one idea I had to keep my current model, but make it more exploitative. If we know the probability of a feature being set (based on Thompson sampling), we can make the algorithm more exploitative by weighting that probability exponentially. I.e.: Pnew = p^w / (p^w + (1-p)^w)... Since I'm displaying 9 images, I could perhaps choose w=[1..9]... We have to estimate p (the probablitiy of one beta random variable greater than another). For that, I can use moment matching to estimate normal distributions, and determine the probability from that. This is described Here - in CrossValidated StackExchange. To further enhance this, I might keep the selected image from the previous iteration (giving only 8 new images).