**Relational database systems ***will* be the best thing since sliced bread...

... when we (hopefully) get them, that is. SQL databases suck so hard it's not funny.

What I find amusing (if sad) is *certified DBAs* who think an SQL database system is a relational one. Speaks volumes for the quality of said certification.

Confused? Read C. J. Date's books.

**edit**

Why is it called *Relational* and what does that word mean?

These days, a programmer (or a certified DBA, *wink*) with a strong (heck, *any*) mathematical background is an exception rather than the common case (I'm an instance of the common case as well). SQL with its *tables*, *columns* and *rows*, as well as the joke called Entity/Relationship Modelling just add insult to the injury. No wonder the misconception that *Relational* Database Systems are called that because of some *Relationships* (Foreign Keys?) between *Entities* (tables) is so pervasive.

In fact, *Relational* derives from the *mathematical* concept of relations, and as such is intimately related to set theory and functions (in the mathematical, not any programming, sense).

[http://en.wikipedia.org/wiki/Finitary_relation][2]:

In mathematics (more specifically, in set theory and logic), a **relation** is a property that assigns truth values to combinations (*k*-tuples) of *k* individuals. Typically, the property describes a possible connection between the components of a *k*-tuple. For a given set of *k*-tuples, a truth value is assigned to each *k*-tuple according to whether the property does or does not hold.

An example of a ternary relation (i.e., between three individuals) is: "*X* was-introduced-to *Y* by *Z*", where (X,Y,Z) is a 3-tuple of persons; for example, "Beatrice Wood was introduced to Henri-Pierre Roché by Marcel Duchamp" is true, while "Karl Marx was introduced to Friedrich Engels by Queen Victoria" is false.

Wikipedia makes it perfectly clear: in a SQL DBMS, such a ternary relation would be a "*table*", not a "*foreign key*" (I'm taking the liberty to rename the "columns" of the relation: X = who, Y = to, Z = by):

```
CREATE TABLE introduction (
who INDIVIDUAL NOT NULL
, to INDIVIDUAL NOT NULL
, by INDIVIDUAL NOT NULL
, PRIMARY KEY (who, to, by)
);
```

Also, it would contain (among others, possibly), this "*row*":

```
INSERT INTO introduction (
who
, to
, by
) VALUES (
'Beatrice Wood'
, 'Henri-Pierre Roché'
, 'Marcel Duchamp'
);
```

but not this one:

```
INSERT INTO introduction (
who
, to
, by
) VALUES (
'Karl Marx'
, 'Friedrich Engels'
, 'Queen Victoria'
);
```

Relational Database Dictionary:

**relation (mathematics)** Given sets *s1*, *s2*, ..., *sn*, not necessarily distinct, *r* is a relation on those sets if and only if it's a set of *n*-tuples each of which has its first element from *s1*, its second element from *s2*, and so on. (Equivalently, *r* is a subset of the Cartesian product *s1* x *s2* x ... x *sn*.)

Set *si* is the *i*th domain of *r* (*i* = 1, ..., *n*). *Note*: There are several important logical differences between relations in mathematics and their relational model counterparts. Here are some of them:

- Mathematical relations have a left-to-right ordering to their attributes.
- Actually, mathematical relations have, at best, only a very rudimentary concept of attributes anyway. Certainly their attributes aren't named, other than by their ordinal position.
- As a consequence, mathematical relations don't really have either a heading or a type in the relational model sense.
- Mathematical relations are usually either binary or, just occasionally, unary. By contrast, relations in the relational model are of degree
*n*, where *n* can be any nonnegative integer.
- Relational operators such as JOIN, EXTEND, and the rest were first defined in the context of the relational model specifically; the mathematical theory of relations includes few such operators.

And so on (the foregoing isn't meant to be an exhaustive list).