# Relation between types prod and sig in COQ

In COQ the type prod (with one constructor pair) corresponds to cartesian product and the type sig (with one constructor exist) to dependent sum but how is described the fact that the cartesian product is a particular case of dependent sum? I wonder there is a link between prod and sig, for instance some definitional equality but I don't find it explicitely in the reference manual.

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As a matter of fact, the type `prod` is more akin to `sigT` than `sig`:

``````Inductive prod (A B : Type) : Type :=
pair : A -> B -> A * B

Inductive sig (A : Type) (P : A -> Prop) : Type :=
exist : forall x : A, P x -> sig P

Inductive sigT (A : Type) (P : A -> Type) : Type :=
existT : forall x : A, P x -> sigT P
``````

From a meta-theoretic point of view, prod is just a special case of sigT where your `snd` component does not depend on your `fst` component. That is, you could define:

``````Definition prod' A B := @sigT A (fun _ => B).

Definition pair' {A B : Type} : A -> B -> prod' A B := @existT A (fun _ => B).

Definition onetwo := pair' 1 2.
``````

They can not be definitionally equal though, since they are different types. You could show a bijection:

``````Definition from {A B : Type} (x : @sigT A (fun _ => B)) : prod A B.
Proof. destruct x as [a b]. auto. Defined.

Definition to {A B : Type} (x : prod A B) : @sigT A (fun _ => B).
Proof. destruct x as [a b]. econstructor; eauto. Defined.

Theorem fromto : forall {A B : Type} (x : prod A B), from (to x) = x.
Proof. intros. unfold from, to. now destruct x. Qed.

Theorem tofrom : forall {A B : Type} (x : @sigT A (fun _ => B)), to (from x) = x.
Proof. intros. unfold from, to. now destruct x. Qed.
``````

But that's not very interesting... :)

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Ok, sorry for my late reply and thanks for your explanation. It's clear. –  Asymptotik Dec 28 '12 at 14:55
Consider the traditional summation of a series whose terms do not depend on the index: the summation of a series of `n` terms, all of which are `x`. Since `x` does not depend upon the index, usually denoted `i`, we simplify this to `n*x`. Otherwise, we would have `x_1 + x_2 + x_3 + ... + x_n`, where each `x_i` can be different. This is one way of describing what you have with Coq's `sigT`: a type that is an indexed family of `x`s, where the index is a generalization of the differing data constructors typically associated with variant types.