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F+ and F* is defined as follows:

  • F+: closure of F

    • F+ = {fd | F |= fd}
    • Set of all FDs deduced from inference rule (normally: Armstrong axioms)
  • F: cover of F

    • {fd | F |- fd} cover of F
    • Set of all FDs entailed by F (all FDs that are true)

So my question is: What is the difference between F+ and F*? Can you also give an example to demonstrate the difference.

closed as off-topic by Brad Larson May 2 '16 at 21:45

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An important property of the Armstrong’s axioms, (as well as of similar set of axioms), it that they are sound and complete (for a proof see for instance this).

This amount to say that F+ = F*. In other words, all the FD derived from those axioms are logically entailed by F, as well as all the FD dependencies logically entailed by F can be derived by repeatedly applying the axioms.

  • So your saying that they both essentially equivalent – Yahya Uddin Mar 29 '16 at 13:46
  • Exactly, they are equivalent. – Renzo Mar 29 '16 at 14:17
  • This is so odd. I'm glad I asked this question is "Computer Science" Stack Exchange and I got the complete opposite answer in that F+ and F* and completely different: cs.stackexchange.com/questions/55093/… . Note I only asked here as well because I was not sure how popular "Computer Science" Stack Exchange is. – Yahya Uddin Mar 29 '16 at 15:09
  • @YahyaUddin, in the other answer there is a confusion between the closure of a set of attributes (the answer) and the closure of a set of functional dependencies (your question). You can read any book on normalization theory and see that the definition of the closure of a set of attributes (X+) is completely different from the closure of a set of functional dependencies (F+). – Renzo Mar 29 '16 at 17:25

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