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# Algorithm for Finding Good, Reliable Players

I've the following players, each value corresponds to a result in percentage of right answers in a given game.

``````\$players = array
(
'A' => array(0, 0, 0, 0),
'B' => array(50, 50, 0, 0),
'C' => array(50, 50, 50, 50),
'D' => array(75, 90, 100, 25),
'E' => array(50, 50, 50, 50),
'F' => array(100, 100, 0, 0),
'G' => array(100, 100, 100, 100),
);
``````

I want to be able to pick up the best players but I also want to take into account how reliable a player is (less entropy = more reliable), so far I've come up with the following formula:

``````average - standard_deviation / 2
``````

However I'm not sure if this is a optimal formula and I would like to hear your thoughts on this. I've been thinking some more on this problem and I've come up with a slightly different formula, here it is the revised version:

``````average - standard_deviation / # of bets
``````

This result would then be weighted for the next upcoming vote, so for instance a new bet from player C would only count as half a bet.

I can't go into specifics here but this is a project related with the Wisdom of Crowds theory and the Delphi method and my goal is to predict as best as possible the next results weighting past bets from several players.

I appreciate all input, thanks.

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trying to pick the best fantasy football team? :) – Kip Oct 20 '09 at 21:52
@Kip: Not quite, but close. =) – Alix Axel Oct 22 '09 at 14:18
Re your (bolded) additional idea. Congratulations, you've almost reinvented the standard error of the mean! If you used average - 2*stdev/sqrt(numBets), you'd have the lower bound on the 95% confidence interval surrounding the mean. That value is a not entirely unreasonable way to select the best predictors. – Harlan Oct 22 '09 at 18:18
@Harlan: Thanks! I wish you had replied with an answer instead of a comment. Using the formula you provided I get some different results (B, D and F). B from 18.75 to 0, D from 62.29 to 43.67 and F also from 37.5 to 0. I think this new formula might be too "drastic" for what I'm trying to get but maybe you care to explain it a little better, I might have a new idea after reading what you have to say, who knows... – Alix Axel Oct 23 '09 at 13:03
Just to be sure I understand what you want, (30, 30, 30, 30) would be better than (32, 31, 33, 30), but of course (58, 72, 63, 89) would be better than both? – Tim Post Nov 2 '09 at 1:01

First off, I would not use Standard Deviation if your data arrays have only a few entries. Use more robust statistical measures like Median Absolute Deviation (MAD), likewise you might want to test using the Median instead of the Average.

This is due to the fact that, if your "knowledge" of players' bets is limited to only a few samples, your data is going to be dominated by outliers, i.e. the player being lucky/unlucky. Statistical means may be entirely inappropriate under those circumstances and you may want to use some form of heuristic approach.

I also assume from your links, that you do not in fact intend to pick the best player but rather based on the players next set of answers "A" want to predict the correct set of answers "C" by weighing "A" based on the players' previous track record.

Of course if there were a good solution to this problem, you could make a killing on the stock market ;-) (The fact that no-one does, should be an indication as to the existence of such a solution).

But getting back to ranking the players. Your main problem is that you (have to?) take the percentage of right answers as evenly distributed from 0--100%. If the test contains multiple questions this is certainly not the case. I would look at what a completely random player "R" scores on the test and build up a relative confidence number based on how much better/worse than "R" a given real player is.

Say, for each round of the game generate a million random players and look at the distribution of scores. Use the distribution as a weight for the players' real scores. Then combine the weighted scores using MAD and calculate the Median - MAD / some number, like you already suggested.

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Great answer, but in this case why would be better to use the MAD / Median than Standard Deviation / Average? – Alix Axel Nov 3 '09 at 21:03
If your data has a low n (i.e. data points), then the Standard Deviation (s) and average (mean) themselves are not very reliable. E.g., the standard deviation (s_m) of the mean is s/sqrt(n). If you have n=4 as in your example then the mean is itself only accurate to 50% of the data's s. In these situations MAD and Median are more robust. Also using s and mean requires you to assume a normal distribution for any give players' answers over time. This may or may not be the case depending on the setup of the game and your view on human decision making. – Timo Nov 4 '09 at 9:12

You can't get an optimal formula if you haven't quantified what is better. You need to figure out how do you want to weigh consistency against average. For example one option would be to estimate the score that the player will hit a given percentage of games. This requires some kind of model of the probability distribution of the players score. For instance, if we assume that the players scores follow the normal distribution, then your given formula calculates what score the player will surpass about 70% of the time.

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The thing is I've no idea what's better, I've started only with the average but I thought that introducing the deviation might also be a good idea... Please check my update for an idea of what I'm trying to do, maybe this would bring more insight into my question. – Alix Axel Oct 22 '09 at 14:23

Would a Bayesian Probablity Formula fit the bill?

I think it would. Here is a link to another site that is a little less mathematical about it: http://www.experiment-resources.com/bayesian-probability.html

Essentially you are predicting the probability that each player will score the highest in the next round. This is what bayesian probabilities eat for breakfast.

Bayesian probabilities are already in use in video games (warning: .doc file) to determine stuff just like this.

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I fixed the error, but remember likelihood != probabilty when talking about statistics. – nlucaroni Oct 21 '09 at 3:46
Seems way too much complicated for my math skills, maybe you wouldn't mind showing me an example in (pseudo) code? – Alix Axel Oct 22 '09 at 14:21

Hm. This would make a (100,100,100,60) player being rated worse than a (85,85,85,85) player. Why not also take the % of total points into account?

Like: percentage total points (e.g. 0..1) multiplied by your current calculation.

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Thank you for your answer, please check my update. – Alix Axel Oct 22 '09 at 14:19

Have you considered just using the median? It's considered a more robust statistic (less affected by outliers) than the mean. In your data, you get medians of: 0, 25, 50, 82.5, 50, 50, 100.

Does that seem to be what you intuitively want? I agree with others that there's no "right answer" here.

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I'm sorry for such a basic question, but how do I determine the median? – Alix Axel Oct 27 '09 at 2:58
(google is your friend!) For each player, sort the array, then, if there are an odd number of values, pick the middle one, otherwise pick the average of the middle two. Any statistical library will have a median function, too. – Harlan Oct 27 '09 at 12:12

I think you may be right that you want some sort of linear combination of the two factors, but I think we'd need to know more about what your doing to know what the actual constants would be...

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Thank you for your input, please check my update. If you need more info just say the word. – Alix Axel Oct 22 '09 at 14:20

Well, the "simple extension" is just the addition of a weight and a bounds:

average(player) - min(upper, weight * entrophy(player))

However, given the current data-set, I might not be concerned with "right answer percentage" so much as looking at the score difference per game, if that is an option.

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The formula in there is to sort voting, but if you consider the score to be similar to voting (0-whatever) you should be able to use it to calculate which players are more consistently scoring higher.

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