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I'm having trouble understanding how to identify keys in functional dependencies. I've been looking at examples, for example:

Given a relation ABCD, find all keys not including superkeys of the

A -> BC, C -> D, CD -> AB.

This gives keys C and A. The way I thought this problem was approached was that BC and D both depend on A and C, and AB depends on CD, meaning all three of them are keys, but since CD is a superkey (C is a subset that is also a key), CD is not considered a minimal superkey.

However, in another example,

E → A
D → A

The only key here is apparently BE. Why is this true, and can anyone clarify the steps to take in finding keys with these problems?


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2 Answers 2

up vote 5 down vote accepted

The second one's a bit simpler, so taking it first . . . you know that B must be in any key, because it's not on any right-hand side. (That is, even if you have the values of ACDE, you couldn't infer the value of B.) Similarly for E; so, any key must include BE. But BE is by itself a sufficient key, because E gives you A (hence BE → ABE) and AB gives you CD (hence BE → ABCDE).

In the first one, we can see that A is a key, because A gives you B and C, and C gives you D. Similarly, C is a key, because C gives you D, and C and D together give you A and B. Conversely, we see that A and/or C must be in any key, because every left-hand-side includes at least one of them.

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Wait, so does this mean that any attribute in the relation that's not found on the right side of the given FD's will be a key, no matter what, since you can't infer them from any FD? How can you know that for sure? –  user924199 Oct 16 '11 at 4:00
@user924199: No, it means that any attribute not found on the right-hand side of any FD must be part of every key. –  Mike Sherrill 'Cat Recall' Oct 16 '11 at 8:33
Sorry, can you explain why this is true? Also, as another example, if you're given AB -> C and C -> D, the only key in this case would be AB, right, since by the transitive property AB -> D and therefore C isn't a key? Assuming this is true, why can't the keys be A, B separately? –  user924199 Oct 16 '11 at 14:47
Sorry, no, you don't have that quite right. Let's make this a bit less abstract. Suppose you have a database table with the fields A, B, C, and D, where C = abs(A - B) and D = floor(C). For example, if A = 2.1 and B = -3.4, then C = 1.3, so D = 1. Then AB → C and C → D: if two records have the same A and B, then they have the same C, and if they have the same C, then they have the same D. Therefore: if they have the same A and B, then they are completely identical, so AB is a superkey. (continued) –  ruakh Oct 16 '11 at 23:41
(continued) But two records can have the same A, or the same B, or the same C, while differing in other fields; so neither A nor B nor C is a superkey. If you play around for a bit, you should be able to see why the only superkeys are AB, ABC, ABD, and ABCD. Of these, the only candidate key is AB, because the other superkeys all contain AB (and therefore, they contain more fields than they need to). Does that make sense? –  ruakh Oct 16 '11 at 23:41

A procedure that is a little more formal.

Take an FD, e.g. (example 2), AB -> CD.

Augment this using trivial FDs until you have ALL the attributes on the RHS.

You lack ABE on the RHS, so you must augment using the trivial FD ABE -> ABE to obtain ABE -> ABCDE.

That tells you that ABE is a superkey, because knowing the values in a certain row for ABE will be sufficient to determine the values for all attributes in that row.

Now inspect the OTHER FDs to see if any of them allow you to reduce the LHS (ABE) in this case. E -> A allows you to remove A from ABE, keeping thus only BE -> ABCDE. The rule for reduction is : if the LHS of another FD (E) is a proper subset of the superkey you are trying to reduce (ABE), then you can remove all the attributes from the superkey that are mentioned ONLY in the RHS of that other FD (you cannot remove E if you are looking at an "other" FD such as E -> EA !!!).

This procedure is not apt for mechanical implementation, because you might also have to take a look at "combinations" of other FDs. However, most use cases and even most fabricated class exercises typically are not complex enough to cause this procedure to fail (i.e. leaving you with a proper superkey instead of an irreducible one).

(PS to find ALL the keys, you will need to apply this to ALL given FDs)

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This answer, if it works, is much better since it is about the algorithm and not just the specific cases. –  Niklas Rtz Jun 4 '12 at 5:49

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