Armstrong's axioms

Armstrong's axioms are a set of references (or, more precisely, inference rules) used to infer all the functional dependencies on a relational database. They were developed by William W. Armstrong in his 1974 paper.^[1] The axioms are sound in generating only functional dependencies in the closure of a set of functional dependencies (denoted as $F^{+}$ ) when applied to that set (denoted as $F$ ). They are also complete in that repeated application of these rules will generate all functional dependencies in the closure $F^{+}$ .

More formally, let $\langle R(U),F\rangle$ denote a relational scheme over the set of attributes $U$ with a set of functional dependencies $F$ . We say that a functional dependency $f$ is logically implied by $F$ , and denote it with $F\models f$ if and only if for every instance $r$ of $R$ that satisfies the functional dependencies in $F$ , $r$ also satisfies $f$ . We denote by $F^{+}$ the set of all functional dependencies that are logically implied by $F$ .

Furthermore, with respect to a set of inference rules $A$ , we say that a functional dependency $f$ is derivable from the functional dependencies in $F$ by the set of inference rules $A$ , and we denote it by $F\vdash _{A}f$ if and only if $f$ is obtainable by means of repeatedly applying the inference rules in $A$ to functional dependencies in $F$ . We denote by $F_{A}^{*}$ the set of all functional dependencies that are derivable from $F$ by inference rules in $A$ .

Then, a set of inference rules $A$ is sound if and only if the following holds:

$F_{A}^{*}\subseteq F^{+}$

that is to say, we cannot derive by means of $A$ functional dependencies that are not logically implied by $F$ . The set of inference rules $A$ is said to be complete if the following holds:

$F^{+}\subseteq F_{A}^{*}$

more simply put, we are able to derive by $A$ all the functional dependencies that are logically implied by $F$ .

Axioms (primary rules)

Let $R(U)$ be a relation scheme over the set of attributes $U$ . Henceforth we will denote by letters $X$ , $Y$ , $Z$ any subset of $U$ and, for short, the union of two sets of attributes $X$ and $Y$ by $XY$ instead of the usual $X\cup Y$ ; this notation is rather standard in database theory when dealing with sets of attributes.

Axiom of reflexivity

If $X$ is a set of attributes and $Y$ is a subset of $X$ , then $X$ holds $Y$ . Hereby, $X$ holds $Y$ [ $X\to Y$ ] means that $X$ functionally determines $Y$ .

If

Y\subseteq X

then

X\to Y

.

Axiom of augmentation

If $X$ holds $Y$ and $Z$ is a set of attributes, then $XZ$ holds $YZ$ . It means that attribute in dependencies does not change the basic dependencies.

If

X\to Y

, then

XZ\to YZ

for any

Z

.

Axiom of transitivity

If $X$ holds $Y$ and $Y$ holds $Z$ , then $X$ holds $Z$ .

If

X\to Y

and

Y\to Z

, then

X\to Z

.

Additional rules (Secondary Rules)

These rules can be derived from the above axioms.

Decomposition

If $X\to YZ$ then $X\to Y$ and $X\to Z$ .

Proof

1. $X\to YZ$	(Given)
2. $YZ\to Y$	(Reflexivity)
3. $X\to Y$	(Transitivity of 1 & 2)

Composition

If $X\to Y$ and $A\to B$ then $XA\to YB$ .

Proof

1. $X\to Y$	(Given)
2. $A\to B$	(Given)
3. $XA\to YA$	(Augmentation of 1 & A)
4. $XA\to Y$	(Decomposition of 3)
5. $XA\to XB$	(Augmentation of 2 & X)
6. $XA\to B$	(Decomposition of 5)
7. $XA\to YB$	(Union 4 & 6)

Union

If $X\to Y$ and $X\to Z$ then $X\to YZ$ .

Proof

1. $X\to Y$	(Given)
2. $X\to Z$	(Given)
3. $X\to XZ$	(Augmentation of 2 & X)
4. $XZ\to YZ$	(Augmentation of 1 & Z)
5. $X\to YZ$	(Transitivity of 3 and 4)

Pseudo transitivity

If $X\to Y$ and $YZ\to W$ then $XZ\to W$ .

Proof

1. $X\to Y$	(Given)
2. $YZ\to W$	(Given)
3. $XZ\to YZ$	(Augmentation of 1 & Z)
4. $XZ\to W$	(Transitivity of 3 and 2)

Self determination

$I\to I$ for any $I$ . This follows directly from the axiom of reflexivity.

Extensivity

The following property is a special case of augmentation when $Z=X$ .

If

X\to Y

, then

X\to XY

.

Extensivity can replace augmentation as axiom in the sense that augmentation can be proved from extensivity together with the other axioms.

Proof

1. $XZ\to X$	(Reflexivity)
2. $X\to Y$	(Given)
3. $XZ\to Y$	(Transitivity of 1 & 2)
4. $XZ\to XYZ$	(Extensivity of 3)
5. $XYZ\to YZ$	(Reflexivity)
6. $XZ\to YZ$	(Transitivity of 4 & 5)

Armstrong relation

Given a set of functional dependencies $F$ , an Armstrong relation is a relation which satisfies all the functional dependencies in the closure $F^{+}$ and only those dependencies. Unfortunately, the minimum-size Armstrong relation for a given set of dependencies can have a size which is an exponential function of the number of attributes in the dependencies considered.^[2]

References

^ William Ward Armstrong: Dependency Structures of Data Base Relationships, page 580-583. IFIP Congress, 1974.
^ Beeri, C.; Dowd, M.; Fagin, R.; Statman, R. (1984). "On the Structure of Armstrong Relations for Functional Dependencies" (PDF). Journal of the ACM. 31: 30–46. CiteSeerX 10.1.1.68.9320. doi:10.1145/2422.322414. Archived from the original (PDF) on 2018-07-23.

External links

UMBC CMSC 461 Spring '99
CS345 Lecture Notes from Stanford University

[1] William Ward Armstrong: Dependency Structures of Data Base Relationships, page 580-583. IFIP Congress, 1974.

[2] Beeri, C.; Dowd, M.; Fagin, R.; Statman, R. (1984). "On the Structure of Armstrong Relations for Functional Dependencies" (PDF). Journal of the ACM. 31: 30–46. CiteSeerX 10.1.1.68.9320. doi:10.1145/2422.322414. Archived from the original (PDF) on 2018-07-23.

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