A simple approach might be something like,

```
Require Import Omega.
Inductive V : Set :=
mkV : forall (v:nat), 0 <= v /\ v <= 10 -> V.
Lemma member0 : V.
Proof. apply (mkV 0). omega. Qed.
Definition inc (v:V) : nat := match v with mkV n _ => n + 1 end.
Lemma inc_bounds : forall v, 0 <= inc v <= 11.
Proof. intros v; destruct v; simpl. omega. Qed.
```

Of course the type of `member0`

may not be as informative as you might like. In that case, you may want to index `V`

by the `nat`

corresponding to each element of the set.

```
Require Import Omega.
Inductive V : nat -> Set :=
mkV : forall (v:nat), 0 <= v /\ v <= 10 -> V v.
Lemma member0 : V 0.
Proof. apply (mkV 0). omega. Qed.
Definition inc {n} (v:V n) : nat := n + 1.
Lemma inc_bounds : forall {n:nat} (v:V n), 0 <= inc v <= 11.
Proof. intros n v. unfold inc. destruct v. omega. Qed.
```

I've not worked with `Reals`

before, but the above can be implemented on `R`

as well.

```
Require Import Reals.
Require Import Fourier.
Open Scope R_scope.
Inductive V : R -> Set :=
mkV : forall (v:R), 0 <= v /\ v <= 10 -> V v.
Lemma member0 : V 0.
Proof. apply (mkV 0). split. right; auto. left; fourier. Qed.
Definition inc {r} (v:V r) : R := r + 1.
Lemma inc_bounds : forall {r:R} (v:V r), 0 <= inc v <= 11.
Proof. intros r v; unfold inc.
destruct v as (r,pf). destruct pf. split; fourier.
Qed.
```