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Given the following functional dependendies on a relation R(A B C D E F G)

AB → CF
BG → C
AEF → C
ABG → ED
CF → AE
A → CG
AD → FE
AC → B

I have worked out the candidate keys by using the method where you put the attribute in either a left, middle, right column depending if it is seen on the left hand side of a dependency, right hand side or both. Left means that the attribute is necessary, middle is unknown and right means not part of a key.

I got this:

L | M       | R
--|---------|----
- | ABCDEFG | - 

From here I worked out the closures for each individual attribute and the permutations: BC, BD, BE, BF, BG, CD, CF...

I found that only the closure of A and CF contain all attributes and therefore are candidate keys however the solution the problem also has BFG.

Can someone explain what I am doing wrong in calculating candidate keys? Thanks

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Did you try using a different algorithm to see whether you get the same results? –  Mike Sherrill 'Cat Recall' Apr 16 '12 at 22:04
    
Not sure about what other algorithms I could use. Do I have to take all possible combinations and take the closure of them i.e. combinations of 2,3,4,...? –  sam Apr 16 '12 at 22:09
    
Sometimes you have to do that. I'm not familiar with the algorithm you used, at least not with the way you presented it. BFG is, indeed, a candidate key. Are you missing how to derive the closure of BFG? –  Mike Sherrill 'Cat Recall' Apr 17 '12 at 0:27
    
Is this the algorithm you're using? (Starts on page 5) –  Mike Sherrill 'Cat Recall' Apr 17 '12 at 1:21
    
yes, thats the very one –  sam Apr 17 '12 at 9:30

1 Answer 1

up vote 2 down vote accepted

This algorithm tries to find shortcuts (pg 3), but in your case it doesn't find any. To determine whether any particular combination of attributes is a key, you try to figure out whether that combination determines every other attribute. In your case, you've done all the work; you're just missing something about BFG.

Logic                                    Attributes
--
BFG -> BFG, ∴ ...                       { B   FG}
BG -> C, ∴ BFG -> CF                    { BC  FG}
BFG -> CF and CF -> AE, ∴ BFG -> AE     {ABC EFG}
BFG -> AE,  ∴  BFG -> A
BFG -> A and ABG -> ED, ∴ BFG -> ED     {ABCDEFG}

So BFG is a candidate key.

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