# Method to find candidate key given FD:s?

I'm practicing taking as input a set of functional dependencies and output candidate key(s). Is there an algorithm and how come in such case there is no web-based implementation where I can input my FD:s and as output get a list of superkeys / candidate keys?

I practice on what I find here on SO and a suitable question is how to find the highest normal form for a given relation where the functional dependencies mentioned are

B->G

BI->CD

EH-> AG

G-> DE

Please check if I'm doing this right when I try to find that the candidate key is BFHI:

The FD B->G can be rewritten as ABCDEFHI->ABCDEFGHI and therefore ABCDEFHI is a superkey. The FD BI->CD can be rewritten as ABEFGHI->ABCDEFGHI and therefore ABEFGHI is a superkey. The FD EH->AG can be rewritten as BCDEEFHI->ABCDEFGHI and therefore BCDEEFHI is a superkey. The FD G->DE can be rewritten as ABCFGHI->ABCDEFGHI and therefore ABCFGHI is a superkey.

In our superkeys, BFHI is in every one. Therefore BFHI is the candidate key and it cannot be reduced further which can be seen from inspection(?)

Am I reasoning this the right way?

There is another question the augmenting algorithm can handle, if it works, Database extraneous attributes and decomposition

Here, the FD:s are

A->BCD

BC->DE

B->D

D->A

Here the FB A->BCD can be written as AEF->ABCDEF and therefore AEF is a superkey. The FD BC->DE can be rewritten as ABCF->ABCDEF and therefore ABCF is a superkey. The FD B->D can be rewritten as ABCEF->ABCDEF and therefore ABCEF is a superkey. The FD D->A can be rewritten as BCDEF->ABCDEF and therefore BCDEF is a superkey. For all superkeys, F is the only member(s) that is in every superkey and therefore F is the only candidate key.

Does this work?

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"how come in such case there is no web-based implementation" - Because you haven't built one yet! –  Emil Vikström Jun 4 '12 at 7:29
Yes there is Armstrong's axioms but that is not a method. It just states what can be done with FD:s. I'm looking for the method rather than definitions / axioms. I'm updating the question with another application of the augment algorithm to see if it's generally applicable. Many thanks for your comment. –  Niklas in Stockholm Jun 4 '12 at 7:30

``````No, but as F is not in any of the FD:s then it has to be a member of every candidate key.

Also, A->BCD, BC->DE, B->D, D->A give us
A+ (the cover of A) = ABCDE
B+ = ABCDE
C+ = C
D+ = ABCDE so the
E+ = E
F+ = F.

The combinations giving ABCDEF are
AF
BF
DF
and hence the candidate keys are {AF, BF, DF}
and every enhancement of any of those three are the superkeys
``````
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Now it looks easy. Thank you. –  Niklas in Stockholm Jun 4 '12 at 15:58