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Twitter recently announced that you can approximate the rank of any given twitter user with high accuracy by inputting their follower count in the following formula:

exp($a + $b * log(follower_count))

where $a=21 and $b=-1.1

This is obviously a lot more efficient than sorting the entire list of users by follower count for a given user.

If you have a similar data set from a different social site, how could you derive the values for $a and $b to fit that data set? Basically some list of frequencies the distribution of which is assumed to be power law.

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Note that's not what "log-normal" means... –  Oliver Charlesworth Jan 5 '11 at 23:09
    
linear on log/log scale is what I really meant –  ʞɔıu Jan 5 '11 at 23:29

2 Answers 2

up vote 6 down vote accepted

You have the following model:

y = exp(a + b.log(x))

which is equivalent to:

log(y) = a + b.log(x)

Therefore, if you take logs of your data set, you end up with a linear model, so you can then use linear regression to determine the best-fit values of a and b.

However, this all sounds pretty meaningless to me. Who's to say that a given networking site determines user rank using this sort of relationship?

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+1, they don't and Twitter never said that they do. This only approximates your rank by number of followers, not real 'rank' –  Kirk Broadhurst Jan 6 '11 at 0:03
    
@Kirk: Indeed, I initially misunderstood what the OP meant by "rank". I guess the rhetorical question becomes: who's to say that the distribution for a given networking site follows this sort of relationship? –  Oliver Charlesworth Jan 6 '11 at 0:08
    
Sorry I misunderstood what you meant! I guess this assumes that the distribution is logarithmically normal or follows the 'power law', which is probably a somewhat reasonable but completely unreliable assumption. –  Kirk Broadhurst Jan 6 '11 at 1:01
    
This is about my answer below. I know it's not the most elegant solution, but it's very practical. The main advantage is that Excel also let's you also use different algorithms to improve fit in your Excel solver add-in. By the way, if your data set is too large, you could reduce it by taking a random sample of your data. –  luiscolorado Jan 6 '11 at 13:49

You could use the Microsoft Excel add-in named "Solver". It is included with Excel, but not always installed by default. Look for "add-in" and "solver" at your Excel version and load it.

After installing the add-in, do the following:

  1. Create a new worksheet. In column A you would put the id of each individual (optional)

  2. Column B, the number of followers.

  3. If the data is not sorted, sort it using column B.

  4. On column C put ranking (you know, 1, 2, 3, etc.)

  5. Put value 21 at cell D1, and -1.1 at cell E1. Those are the Twitter values for $A and $B. Those are our base values. They will possibly change.

  6. At cell D2 put a formula like this: =exp($E$1+$F$1*log(B2))

  7. Copy down the formula at D2 at the end of the data.

  8. At cell E2 put a formula to compare the actual ranking with the result of the formula (i.e., variance). e.g., =sqrt(c2*c2+d2*d2). The closer are the actual and the predicted values, the value will tend to 0.

  9. Copy down cell E2 to the end of the data.

  10. At the bottom of data, at column E, sum the variances. e.g., Let's say your data has 10,000 values. At cell E10001 enter =sum(e2:e10000).

  11. Go to the menu Data, and look for the "Solver" menu location. The location may very depending on your version of Excel. Use the "Help" facility to search for Goal Seek.

  12. Follow the instructions (I have to go now) in Help to use the Solver add-in. Obviously, the changing cells are D1 and E1, and the goal is to make E10001 (the sum of the variances) as close to zero as possible.

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