You can't express it directly.

It's misleading to think of objects in `Set`

as mathematical sets. `Set`

is the sort of datatypes, the same kinds of types that you find in programming languages (except that Coq's types are very powerful).

Coq doesn't have subtyping¹. If the two types `F`

and `Q`

are distinct, then they are disjoint, as far as the mathematical model is concerned.

The usual approach is to declare `F`

as a completely related set, and declare a canonical injection from `F`

to `Q`

. You'll want to specify any interesting property of that injection, beyond the obvious.

```
Parameter Q : Set.
Parameter F : Set.
Parameter inj_F_Q : F -> Q.
Axiom inj_F_Q_inj : forall x y : F, inj_F_Q x = inj_F_Q y -> x = y.
Coercion inj_F_Q : F >-> Q.
```

That last line declares a coercion from `F`

to `Q`

. That lets you put an object of type `F`

wherever the context requires the type `Q`

. The type inference engine will insert a call to `inj_F_Q`

. You will need to write the coercion explicitly occasionally, since the type inference engine, while very good, is not perfect (perfection would be mathematically impossible). There is a chapter on coercions in the Coq reference manual; you should at least skim through it.

Another approach is to define your subset with an extensional property, i.e. declare a predicate `P`

on the set (the type) `Q`

and define `F`

from `P`

.

```
Parameter Q : Set.
Parameter P : Q -> Prop.
Definition G := sig P.
Definition inj_G_Q : G -> Q := @proj1_sig Q P.
Coercion inj_G_Q : G >-> Q.
```

`sig`

is a specification, i.e. a weak sum type, i.e. a pair consisting of an object and a proof that said object has a certain property. `sig P`

is eta-equivalent to `{x | P x}`

(which is syntactic sugar `sig (fun x => P x)`

). You have to decide whether you prefer the short or the long form (you need to be consistent). The `Program`

vernacular is often useful when working with weak sums.

¹ _{
There is subtyping in the module language, but that's not relevant here. And coercions fake subtyping well enough for many uses, but they're not the real thing.
}