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It has been suggested that this article be merged into unique key. (Discuss) Proposed since August 2009.

A superkey is defined in the relational model of database organization as a set of attributes of a relation variable for which it holds that in all relations assigned to that variable, there are no two distinct tuples (rows) that have the same values for the attributes in this set. Equivalently a superkey can also be defined as a set of attributes of a relvar upon which all attributes of the relvar are functionally dependent.

Note that the set of all attributes is a trivial superkey.

Also note that if attribute set K is a superkey of relvar R, then at all times it is the case that the projection of R over K has the same cardinality as R itself.

Informally, a superkey is a set of attributes within a table whose values can be used to uniquely identify a tuple. A candidate key is a minimal set of attributes necessary to identify a tuple, this is also called a minimal superkey. For example, given an employee schema, consisting of the attributes employeeID, name, job, and departmentID, we could use the employeeID in combination with any or all other attributes of this table to uniquely identify a tuple in the table. Examples of superkeys in this schema would be {employeeID, Name}, {employeeID, Name, job}, and {employeeID, Name, job, departmentID} which is the trivial superkey.

In a real database we do not need values for all of those attributes to identify a tuple. We only need, per our example, the set {employeeID}. This is a minimal superkey – that is, a minimal set of attributes that can be used to identify a single tuple. So, employeeID is a candidate key.

Example

First, list out all the (non-empty) sets of attributes:

• {Monarch Name}  • {Monarch Number}  • {Royal House}

• {Monarch Name, Monarch Number}

• {Monarch Name, Royal House}

• {Monarch Number, Royal House}

• {Monarch Name, Monarch Number, Royal House}

Second, eliminate all the sets which do not meet superkey's requirement. For example, {Monarch Name, Royal House} cannot be a superkey because for the same attribute values (Edward, Plantagenet), there are two distinct tuples:

• (Edward, II, Plantagenet)
• (Edward, III, Plantagenet)

Finally, after elimination, the remaining sets of attributes are the only possible superkeys in this example:

• {Monarch Name, Monarch Number} (Candidate Key)
• {Monarch Name, Monarch Number, Royal House}

In real situations, however, superkeys are normally not determined by this method, which is very tedious and time-consuming, but by analyzing functional dependencies (FD).

See also

• Alternate key
• Compound key
• Foreign key
• Primary key

External links

• Relation Database terms of reference, Keys: An overview of the different types of keys in an RDBMS

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