# Picking fair teams - and the math to prove it

Application: similar to picking playground teams.

I must divide a collection of n sequentially ranked elements into two teams of n/2. The teams must be as "even" as possible. Think of "even" in terms of playground teams, as described above. The rankings indicate relative "skill" or value levels. Element #1 is worth 1 "point", element #2 is worth 2, etc. No other constraints.

So if I had a collection [1,2,3,4], I would need two teams of two elements. The possibilities are

[1,2] & [3,4]

[1,3] & [2,4]

[1,4] & [2,3]

(Order is not important.)

Looks like the third option is the best in this case. But how can I best assess larger sets? Average/mean is one approach, but that would result in identical rankings for the following candidate pair which otherwise seem uneven:

[1,2,3,4,13,14,15,16] & [5,6,7,8,9,10,11,12]

I can use brute force to evaluate all candidate solutions for my problem domain.

Is there some mathematical/statistical approach I can use to verify the "evenness" of two teams?

Thanks!

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Should this be moved to math.stackexchange.com ? – jacknad Mar 13 '12 at 16:52
Are the rankings absolute values or relative values? For example, will there always be (1,2,3,...) or can there be (1,20,21,34,35), etc? An example case would be Kobe Bryant, and then a bunch of varsity high school basketball players. – steve8918 Mar 13 '12 at 16:54
I think you need to formalise what you mean by "evenness" a bit more; if two teams with the same mean ranking (and the same ranking sum) are "uneven", what does that mean? – Chowlett Mar 13 '12 at 17:02
Yes, the "evenness" is elusive. For simplicity's sake, I'm approaching this as I meant to articulate with my reference to points. Variation between elements can be considered constant. – spoxox Mar 13 '12 at 20:00

Your second, longer example, does not seem uneven (or unfair) to me. In fact, it accords with what you seem to think is the preferred answer for the first example.

Therein lies the non-programming-related nub of your problem. What you have are ordinal numbers and what you want are cardinal numbers. To turn the former into the latter you have to define your own mapping, there is no universal, off-the-shelf approach.

You might, for example, compare each element of the 2 sets in turn, eg `a1 vs b1, a2 vs b2, ...` and regard the sets as even enough if the number of cases where a is better than b is about the same as the number of cases where b is better than a.

But for your application, I don't think you will do better than use the playground algorithm, each team leader chooses the best unchosen player and turns to choose alternate. Why do you need anything more complicated ?

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It's not that I need something more complicated as much as I need to demonstrate the fairness of a given approach. If a quantifiable measure can demonstrate that teams are as evenly matched as possible, I'm very happy! – spoxox Mar 13 '12 at 20:01

The numbers represent rankings? Then no, there is no algorithm to get fair teams, because there's not enough information. It could be that even the match-up

``````[1] & [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16]
``````

is stacked against the large-team. This would be the case, for example, for chess-teams, if the difference between `[1]` and `[2]` was large.

Even the matchup you mentioned as being "unfair":

``````[1,2,3,4,13,14,15,16] & [5,6,7,8,9,10,11,12]
``````

Could be completely fair in a game like baseball. After all, players 13-16 still need to bat!

So, probably the most fair thing to do would be to just pick teams randomly. That would also avoid any form of "gaming" the system (like my friends and I did in gym class in high school :) )

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Fairness, like beauty, is in the eye of the beholder. But I'd agree with the leader of team B if the random team picker produced A = [1..8] and B = [9..16]. – High Performance Mark Mar 13 '12 at 17:22

I don't think there's enough information to determine an answer.

What does it really mean for someone to be #1 vs #2? Are they 50% better, or 10% better or 1% better? How much better is #1 vs #5? It's really the algorithm to assign a value that needs to be accurate, and the distribution algorithm needs to reflect this properly.

For example, like I said, if you have Kobe Bryant mixed in with a bunch of high school basketball kids, what would the relative values be? Because in basketball, Kobe Bryant could single-handedly beat all the high school kids. So would his rank be #1, and the rest of the kids be #1000+?

As well, you have to assume that the value determination takes into account the size of a team. Does the team only need 2 players? Or does it need 10? In latter case, then in your second example, the 2nd team seems okay because the top 4 players would be playing with 6 much worse players, which could affect the success.

If all you are doing is distributing values, and if the notion of "fairness" is built into the value system, then the mean values seem to be a fair way to distribute the players.

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Sorry, I meant to be clear on this earlier. Variation between elements can be considered constant. I suppose this allows for variation to be 0, and therefore all teams are equal - a useless outcome! Given the uniformity of variation (#1 is x% better than #2 and 2x% better than #3), does some algorithm lend itself to this level of specificity? – spoxox Mar 13 '12 at 20:06

You need an iterative ranking approach, with automated picking to produce evenly ranked teams on each iteration. This works even when the mix of participants changes to some extent over time. I created a tool to do just this for my 5-a-side group and then opened it up to allcomers if you google for "Fair Team Picker"

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